Abstract
Intra-tumoral heterogeneity is a hallmark of glioblastoma that challenges treatment efficacy. However, the mechanisms that set up tumor heterogeneity and tumor cell migration remain poorly understood. Herein, we present a comprehensive spatiotemporal study that aligns distinctive intra-tumoral histopathological structures, oncostreams, with dynamic properties and a specific, actionable, spatial transcriptomic signature. Oncostreams are dynamic multicellular fascicles of spindle-like and aligned cells with mesenchymal properties, detected using ex vivo explants and in vivo intravital imaging. Their density correlates with tumor aggressiveness in genetically engineered mouse glioma models, and high grade human gliomas. Oncostreams facilitate the intra-tumoral distribution of tumoral and non-tumoral cells, and potentially the collective invasion of the normal brain. These fascicles are defined by a specific molecular signature that regulates their organization and function. Oncostreams structure and function depend on overexpression of COL1A1. Col1a1 is a central gene in the dynamic organization of glioma mesenchymal transformation, and a powerful regulator of glioma malignant behavior. Inhibition of Col1a1 eliminates oncostreams, reprograms the malignant histopathological phenotype, reduces expression of the mesenchymal associated genes, induces changes in the tumor microenvironment and prolongs animal survival. Oncostreams represent a pathological marker of potential value for diagnosis, prognosis, and treatment.
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Introduction
High grade gliomas (HGG) are the most prevalent and malignant brain tumors. They grow rapidly, invade surrounding normal brain, and recur within 12 months. Median survival is 18–20 months, in spite of current standard of care1,2. Despite some notable successful outcomes from the large cancer sequencing program, which identified driver genes in a number of cancers, effective therapeutically actionable breakthroughs have not yet been identified in HGG3,4,5,6,7.
HGG are highly heterogeneous at the histological, cellular, and molecular level. Heterogeneity of HGG is illustrated in addition by characteristic pathological structures such as pseudopalisades, microvascular proliferation, and areas of hypoxia and necrosis2,8. The molecular characterization of glioma heterogeneity identified three main molecular signatures: proneural, mesenchymal, and classical4,9. However, later studies demonstrated that all three transcriptomic signatures are expressed within individual tumors5,10,11. Rather than outright glioma subtypes, the consensus proposes that individual tumors are enriched in particular molecular subtypes. Thus, studies have correlated histological features with genetic alterations and transcriptional expression patterns. For example, highly aggressive histological features such as hypoxic, necrotic and microvascular proliferative zones have been associated with the mesenchymal molecular signature and worse prognosis8. However, the molecular classification has only minor clinical impact. Thus, alternative classification schemes using a pathway-based classification are currently being considered12. How these new classifications will deal with tumor heterogeneity remains to be explored. Moreover, different microenvironmental, metabolic, and therapeutic factors drive transitions of the GBM transcriptomic signature, particularly transitions to mesenchymal states. It is important to note that glioblastoma plasticity explains the high degree of tumor heterogeneity and favor the selection of new clones at recurrence or therapy resistance13,14,15,16. It has been proposed that intra-tumoral heterogeneity is represented by four main cellular states, the progenitor, astrocyte, oligodendrocyte, and mesenchymal like-state, which are a consequence of tumor plasticity and are affected by the tumor microenvironment15.
Tumor mesenchymal transformation is a hallmark of gliomas13,17,18. A mesenchymal phenotype is defined by cells with spindle-like, fibroblast-like morphology associated with alterations in their dynamic cellular organization leading to an increase in cell migration and invasion19,20. The mesenchymal phenotype is controlled by particular transcription factors and downstream genes related to the extracellular matrix (ECM), cell adhesion, migration, and tumor angiogenesis18,21,22.
However, the cellular and molecular mechanisms that regulate mesenchymal transformation in gliomas, especially concerning the mesenchymal features of invasive cells, has remained elusive. Integrating morphological features, spatially resolved transcriptomics, and cellular dynamics resulting from mesenchymal transformation, growth, and invasion are thus of great relevance to the understanding of glioma progression13,20.
Cell migration is essential to continued cancer growth and invasion. Morphological and biochemical changes that occur during mesenchymal transformation allow glioma cells to move throughout the tumor microenvironment and invade the adjacent normal brain. Tumor cells also migrate along blood vessels, white matter tracks, and the subpial surface23. Within the tumor microenvironment, aligned extracellular matrix fibers help guide the movement of highly motile mesenchymal-like breast cancer cells24,25.
Collective motion is a form of collective behavior where individual units’ (cells) movement is regulated by local intercellular interactions (i.e., attraction/repulsion) resulting in large scale coordinated cellular migration26,27,28,29,30. Collective motion plays an essential role in embryogenesis and wound healing27,31,32,33. Emergent organized collective motion patterns could help explain so far poorly understood tumoral behaviors such as invasion, metastasis, and especially recurrence27,31.
Studies of tumor motility have concentrated on the behavior of glioma cells at the tumor invasive border27,34,35. Potential motility at the glioma core has not been studied in much detail so far. This study challenges the conventional belief that cells in the central core are non-motile and indicate that the glioma core displays collective migratory patterns. This would suggest that the capacity of gliomas to invade and grow, results from phenomena occurring at the tumor invasive border, and from the overall capacity of gliomas to organize collective motion throughout the tumor mass, from the tumor core to the tumor invasive border with normal brain.
Collagen1a1 (COL1A1) has been shown previously to be a major component of the extracellular matrix in different cancers, including glioma, and has been reported to promote tumor growth and invasion36,37. Alternatively, some data suggest that collagen fibers could be passive barriers to resist tumor cell infiltration, or provide biophysical and biochemical support for cell migration. Some studies reported that density of COL1A1 inversely correlates with glioma patients’ prognosis38. However, other studies showed that either increased or decreased deposition of collagen could be associated with increased tumor malignancy39,40,41. Therefore, it is important to further determine the role of COL1A1 in glioma growth and invasion.
Our study reveals that malignant gliomas, both high grade human gliomas and mouse glioma models, display regular distinctive anatomical multicellular fascicles of aligned and elongated, spindle-like cell. We suggest they are areas of mesenchymal transformation. For the sake of simplicity in their description throughout the manuscript, we have named these areas ‘oncostreams’. Using time-lapse laser scanning confocal imaging of high grade glioma explants ex vivo, and multiphoton microscopy in vivo we demonstrate that oncostreams are organized collective dynamic structures. They are present at the tumor core and at areas of the tumor border at the interphase with the normal brain. To study the molecular mechanisms underlying oncostream organization and function we use laser capture microdissection (LCM) followed by RNA-sequencing and bioinformatics analysis. We discovered that oncostreams are defined by a mesenchymal transformation signature enriched in extracellular matrix-related proteins, and which suggests that COL1A1 is a key determinant of oncostream organization. Inhibition of Col1a1 within glioma cells led to oncostream loss and reshaping of the highly aggressive phenotype of HGG. These data indicate that COL1A1 contributes to the tumor microenvironment scaffold, and serves to organize areas of collective motion in gliomas. In summary, we provide a comprehensive study of the histological, morphological, and dynamic properties of glioma tumors. In addition, we characterize the molecular mechanisms that define intra-tumoral mesenchymal transformation in gliomas and discuss their therapeutic implications. Oncostreams are anatomically and molecularly distinctive, regulate glioma growth, display collective motion, and are regulated by the extracellular matrix, especially by COL1A1. Inhibiting Col1a1 within glioma cells is a potential therapeutic strategy to mitigate glioma mesenchymal transformation, intra-tumoral heterogeneity, and thus, potentially reduce deadly glioma invasion and continued growth.
Results
Intra-tumoral multicellular fascicles of elongated and aligned cells in gliomas: oncostreams
HGG are characterized by anatomical, cellular, and molecular heterogeneity which determines, in part, tumor aggressiveness and reduces treatment efficacy5,7,11. Histopathological analysis of mouse and human gliomas revealed the presence of frequent distinct multicellular fascicles of elongated (spindle-like) and aligned cells (≈5–30 cells wide) distributed throughout the tumors. These structures resemble areas of mesenchymal transformation which we describe as oncostreams (Fig. 1A, B).
To study the presence and morphological characterization of oncostreams, we examined histological sections from various mouse glioma models as well as human glioma specimens (Fig. 1A, B). We determined the existence of oncostreams in genetically engineered mouse models (GEMM) of glioma including NPA (NRAS, shP53, shAtrx) and NPD (NRAS, shP53, Pdgfb) and other implantable models (GL26) (Fig. 1A and Supplementary Fig. 1A, B). Moreover, human glioma samples from primary resections and a xenograft glioma model, SJGBM2, established the presence of these multicellular structures in human tissue (Fig. 1B and Supplementary Fig. 1C). Morphological analysis determined that cells within histological areas corresponding to oncostreams have an aspect ratio of 2.63 ± 0.19 (elongated or spindle-like cells) compared to the surrounding tissue where cells have an aspect ratio of 1.37 ± 0.12 (round cells), both in mouse and human gliomas as shown in Fig. 1C and Supplementary Fig. 1D. We also determined that elongated cells within oncostreams are nematically aligned with each other, whereas outside of oncostreams, cell orientations are not aligned (Fig. 1D and Supplementary Fig. 1E).
To gain insight into the cellular features of oncostreams we asked if they are homogeneous or heterogeneous multicellular structures. We observed that in GEMM of gliomas, oncostreams are formed by GFP+ tumor cells, and are enriched in other tumor microenvironment cells such as ACTA2+ mesenchymal cells, IBA1+, and CD68+ tumor associated microglia/macrophages cells, Nestin+ cells and GFAP+ glial derived cells (Fig. 1E–G and Supplementary Fig. 2A–D). The quantification of mesenchymal cells (ACTA2+), and tumor associated microglia/macrophages (TAM) cells (CD68+ and IBA1+) showed a significant enrichment of these populations within oncostreams compared to the surrounding areas (Fig. 1E–G). Moreover, non-tumoral cells within oncostreams were positively aligned along the main axes of oncostreams, and with tumor cells in mouse gliomas (Fig. 1H). This suggests that oncostreams are mesenchymal-like structures which interact with TAM and mesenchymal cells.
To test if oncostreams form along existing brain structures, we evaluated their co-localization with white matter tracts. Although, occasional positive immune-reactivity (Neurofilament-L) was present within some areas of the tumors, oncostream fascicles were not preferentially organized along brain axonal pathways (Supplementary Fig. 1F). These data indicate that oncostreams are fascicles of spindle-like aligned cells within glioma tumors, which contain tumor and non-tumor cells.
Oncostream density positively correlates with tumor aggressiveness and poor prognosis in mouse and human gliomas
Oncostreams are histological features that contribute to intra-tumoral heterogeneity suggesting a potential role in glioma progression and malignancy. To understand whether the presence of oncostreams correlates with tumor aggressiveness and clinical outcomes, we generated genetically engineered tumors of different malignant behaviors using the Sleeping Beauty Transposon system. These models reproduce the malignant histopathological features of gliomas as demonstrated in previous studies42,43,44,45. We induced tumors harboring two different genotypes: (1) Activation of Rtk/Ras/Pi3k pathway, in combination with P53 and Atrx downregulation (NPA), and, (2) Rtk/Ras/Pi3k activation, P53 downregulation, Atrx downregulation, and mutant IDH1-R132 expression (NPAI) (Fig. 2A). IDH1-wild-type tumors (NPA) display a highly malignant phenotype and worse survival prognosis (Mediam survival (MS): 70 days), compared with tumors harboring the IDH1-R132 mutation, NPAI, (MS: 213 days) (Fig. 2B). This outcome reproduces human disease, as patients with IDH1-Mutant tumors also have prolonged median survival1,45,46. Tumor histopathological analysis showed a positive correlation between the density of oncostreams and tumor malignancy (Fig. 2C, D). NPA (IDH1-WT) tumors exhibited larger areas of oncostreams within a highly infiltrative and heterogeneous glioma characterized by abundant necrosis, microvascular proliferation, pseudopalisades and cellular heterogeneity as described before44,45. Conversely, NPAI (IDH1-Mut) tumors display a very low density of oncostreams and a homogenous histology mainly comprised of round cells, low amounts of necrosis, no microvascular proliferation, absence of pseudopalisades and less invasive borders (Fig. 2C and Supplementary Fig. 5).
Further, to objectively identify and quantify tumor areas covered by oncostreams, we trained a fully convolutional neural network (fCNN) (Supplementary Figs. 3 and 4A). Our deep learning analysis found that oncostreams occupied 15.28 ± 6.10% of the area in NPA tumors compared with only 1.18 ± 0.81% in NPAI tumors (Fig. 2C, D and Supplementary Fig. 5A, B). Cellular alignment analysis validated the presence or absence of oncostreams (Fig. 2E).
To determine whether oncostreams are linked to glioma aggressiveness in human patients, we evaluated a large cohort of TCGA glioma diagnostic tissue slides from the Genomic Data Commons Portal of the National Cancer Institute. We visually examined 100 TCGA-glioblastoma multiforme (GBM) tissue sections (WHO Grade IV) and 120 TCGA-low grade glioma (LGG) tissues (WHO Grade II and III) using the portal’s slide image viewer (Supplementary Table 1). Oncostreams were present in 47% of TCGA-GBM grade IV tumors tissue, in 8.6% of TCGA-LGG grade III, and were absent from TCGA-LGG grade II (Fig. 3A–C and Supplementary Data 1), consistent with tumor aggressiveness (http://gliovis.bioinfo.cnio.es)47. We then determined the presence of oncostreams across known molecular subtypes of HGG (Grade IV)4. We found oncostream fascicles in 59.4% of Mesenchymal (MES), 53.6% of Classical (CL) subtypes, and only 26.7% of Proneural (PN) (Supplementary Fig. 6A). Finally, we evaluated oncostreams presence related to IDH status and 1p 19q co-deletion in LGG (Grade III). Oncostreams were present in 16.6% of IDH-WT subtype, 5% of IDHmut-non-codel, and absent from IDHmut-codel subtype (Supplementary Fig. 6B). These analyses suggest that oncostream presence is higher in Mesenchymal and Classical subtypes and correlates with IDH-WT status, and thus with a poor prognosis.
To validate the histological identification, we examined H&E images using our deep learning algorithm (Supplementary Fig. 4B). We observed a strong concordance (>80%) between machine learning and the manual histological identification of oncostreams (Supplementary Table 2). Oncostream presence and their segmentation by deep learning is illustrated in Fig. 3C and Supplementary Figs. 7 and 8. Additionally, alignment analysis of glioma cells confirmed the existence of fascicles of elongated, mesenchymal-like cells in human gliomas (Fig. 3D). Thus, our deep learning algorithm validates our histological identification of oncostreams and confirms that the density of oncostream fascicles positively correlates with glioma aggressiveness.
The analysis of cellular heterogeneity showed that non-tumoral cells such as IBA1+ macrophages/microglia and GFAP+ glial-derived cells were positively aligned within oncostreams tumoral cells (SOX2+) in human HGG (Fig. 3E). Conversely, we detected that low grade gliomas (LGG) exhibited homogenous round cells, GFAP+, and IBA1+ cells throughout the tumor with no defined orientation or alignment (Fig. 3F).
Oncostreams are defined by a distinctive spatial transcriptome signature
To determine whether oncostreams fascicles are characterized by a specific gene expression profile, we performed a spatially-resolved transcriptomic analysis using LCM coupled to RNA sequencing (RNA-Seq). Oncostreams were dissected according to their morphological characteristics defined above. Surrounding areas of homogenous rounded cells were selected as non-oncostreams areas (control) (Fig. 4A). RNA-Seq analysis detected a set of 43 differentially expressed (DE) genes; 16 genes were upregulated and 27 downregulated within oncostreams (Fig. 4B, C and Supplementary Data 2).
Functional enrichment analysis of DE genes, performed using the I-PathwayGuide platform (Advaita Corporation, MI, USA), showed that False Discovery Rate (FDR) corrected gene ontology (GOs) terms were associated with migration and extracellular matrix biological process. GOs such as “positive regulation of motility”, “positive regulation of cell migration”, “collagen catabolic processes” and “extracellular matrix organization” were the most over-represented biological processes (Fig. 4D and Supplementary Table 3). The upregulated DE genes within the relevant GOs include: Col1a1, Mmp9, Mmp10, Acta2, Adamts2, Cdh5, Cyr61, Plp1 and those downregulated were Enpp2, Akap12, Bdkrb1 (Fig. 4E and Supplementary Fig. 9). Significant DE genes shared by related GOs are shown in Supplementary Fig. 9. These data indicate that oncostreams can be identified by a specific gene expression set and suggest a distinct role for oncostreams as intra-tumoral mesenchymal-like migratory assemblies within glioma tumors.
COL1A1 contributes to oncostream organization in high grade gliomas
Histopathologically, oncostreams are spindle-like multicellular fascicles with a defined DE gene expression signature enriched in mesenchymal genes. The GO ontology analyses suggest a central role of collagen catabolic process and extracellular matrix organization in oncostreams function. To understand the molecular mechanisms that regulate oncostream organization and function, we identified critical genes using network analysis. Network interactions revealed that Col1a1 is a hub gene, one of the most highly connected nodes, representing a potential regulator of the network’s signaling pathways and biological functions (Fig. 5A and Supplementary Fig. 10A). We found that the most relevant Col1a1-related pathways include: Focal Adhesion, Extracellular Matrix Organization, and Integrin Signaling pathways (Supplementary Fig. 10B, C and Supplementary Tables 4 and 5).
To analyze the role of Col1a1 in oncostream organization, we analyzed COL1A1 expression by immunofluorescence analysis. The Col1a1 gene encodes for the alpha-1 chain of type I collagen fibers. We observed that collagen fibers were aligned within oncostreams and overexpressed in more aggressive NPA (IDH1-WT) gliomas compared with NPAI (IDH1-Mut) tumors. COL1A1 expression was significantly lower and only found surrounding blood vessels in NPAI (IDH1-Mut) tumors (Fig. 5B, C). Correspondingly, human GBM glioma tumors (IDH1-WT) with high oncostream densities showed prominent alignment of collagen fibers along these fascicles and higher COL1A1 expression compared to LGG (IDH1-Mut) (Fig. 5D, E).
Moreover, TCGA-glioma data indicate that COL1A1 has differentially higher expression in GBM histological Grade IV. LGG IDH-WT tumors display higher expression of COL1A1 than IDH1-Mutant. Within the GBM molecular subtype classification4,9, the Mesenchymal group shows higher expression of COL1A1 than the Proneural and Classical groups (Supplementary Fig. 11A); the COL1A1 gene is clearly associated with the mesenchymal subtype. Analysis of patient survival related to COL1A1 expression showed that mesenchymal GBM subtype displayed a significantly shorter survival (MS: 10.4 months) for COL1A1 high tumors, compared to COL1A1 low (MS: 17.9 months) tumors. Classical and Proneural subtypes did not show survival differences associated to COL1A1 expression (Supplementary Fig. 11B). Thus, oncostreams represent intra-tumoral mesenchymal-like structures organized along collagen fibers.
Col1a1 depletion leads to oncostream loss, tumor microenvironment (TME) remodeling and increases in median survival
To evaluate the functional role of COL1A1 in oncostream formation we generated a Col1a1-deficient genetically engineered mouse glioma model. We generated Col1a1 wild-type, and Col1a1 knock-down tumors with different genetic backgrounds (Supplementary Fig. 12A–C). Col1a1 downregulation increased median survival (MS) (Fig. 5F, G). The knockdown of Col1a1 in NPA tumors (NPAshCOL1A1) increased survival to MS: 123 days, compared to NPA control tumors (MS: 68 days) (Fig. 5F). Similarly, Col1a1 knockdown in NPD tumors harboring PDGFβ ligand upregulation (NPDshCOL1A1), also exhibited an increased median survival (MS: 98 days) compared to the NPD controls (MS: 74 days) (Fig. 5G).
To further analyze the effects of Col1a1 downregulation, we evaluated the histopathological features of glioma tumors, quantified oncostream density using deep learning analysis, and evaluated COL1A1 expression within glioma tissues (Fig. 5H, I). We observed that NPA tumors with Col1a1 downregulation showed a significant reduction of COL1A1 immunoreactivity within tumors; it was only maintained in small areas surrounding blood vessels (Fig. 5J, K). Col1a1 inhibition led to oncostream loss and reprogramming of the histopathological tumoral characteristics as evidenced by homogenous round cell morphology, resembling low grade tumors (Fig. 5J, K). Downregulation of Col1a1 in NPD tumors appeared less effective, with large areas of remaining COL1A1 (Fig. 5H,I). Nonetheless, Col1a1 was downregulated within tumor cells and oncostream dismantling was significant compared to NPD control. Some oncostream areas remained associated with blood vessels which displayed significant amounts of COL1A1 (Fig. 5J, K).
We analyzed the effect of Col1a1 depletion on the intrinsic properties of tumoral cells. In vitro studies showed that Col1a1-knockdown cells exhibited a significantly decreased cell proliferation and cell migration compared to controls (Supplementary Fig. 13A–D). Also, we observed that intracranial implantation of Col1a1-knockdown cells resulted in decreased tumor growth and progression when compared to controls (Supplementary Fig. 13E). In vivo, genetically engineered Col1a1 knockdown tumors displayed decreased cell proliferation (PCNA+ cells) (Fig. 6A,B), increased apoptosis via activation of Cleaved-Caspase 3, and downregulation of the anti-apoptotic protein Survivin (Supplementary Fig. 14A–C).
Furthermore, to determine whether Col1a1 downregulation within glioma cells modifies the glioma TME we analyzed changes in tumor-associated macrophages (TAM), endothelial cells, and mesenchymal cells. We found that Col1a1 knockdown tumors exhibited a decreased recruitment of CD68+ TAM (Fig. 6C, D), impaired CD31+ endothelial vascular proliferation (Fig. 6E, F), and diminished ACTA2+ perivascular mesenchymal cells (Fig. 6G, H). Moreover, inhibition of Col1a1 within glioma cells led to downregulation of fibronectin expression, a mesenchymal associated extracellular matrix protein (Supplementary Fig. 14E, F) that is associated with a more aggressive phenotype.
In these preclinical animal models, the expression of Col1a1 was knocked down from the earliest stages of tumor development. Further, to evaluate the effects of the pharmacological degradation of deposited collagen fibers in highly malignant tumors we analyzed explants of brain tumor sections treated with collagenase. We observed that collagenase treatment decreased reticular fibers (general collagen staining), reduced COL1A1 expression and disassemble fibers’ alignment along tumoral cells, and caused oncostreams depletion in a dose-dependent manner (Supplementary Fig. 15A–D). These data indicate that oncostream organization and functions are regulated by COL1A1. Col1a1 knockdown within glioma cells decreased oncostream formation, reprogramed glioma mesenchymal transformation, and remodeled the glioma TME, thus increasing animal survival. Col1a1 inhibition represents an approach for future translational development.
Oncostreams’ mesenchymal patterns reveal intra-tumoral collective motion in gliomas
GO analysis indicates that biological processes such as positive regulation of motility/migration are enriched within oncostream fascicles. Overexpression of extracellular matrix (ECM)-associated proteins suggest a potential role of COL1A1 fibers in regulating oncostreams’ motility. To study if oncostreams represent migratory structures within glioma tumors, we established a physiologically viable explant brain tumor slice model containing a high density of oncostreams (Fig. 7A). The movement of glioma cells expressing green fluorescent protein (GFP), within the thickness of each explant, was visualized using time-lapse confocal imagining and tracked using Fiji’s plug-in Track-Mate (Fig. 7A–C).
Migration analyses show complex glioma cell dynamics throughout the tumor core. The glioma tumor core displays groups of cells (within particular zones) with similar nematic orientation and displaying complex movement patterns (Fig. 7D and Supplementary Fig. 16A) and, which represent collective motion27,29,30,31. Angle velocity distribution indicated the existence of three patterns of collective motility shown schematically in Fig. 7D, F: in ‘Zone A’ cells don’t have a preferred direction, in ‘Zone B’ cells move in opposite directions (~135° and 315°), and in ‘Zone C’ all cells move with a predominant preferred direction (~45°) (Fig. 7D, F). We named these patterns swarm (Zone A), stream (Zone B), or flock (Zone C) (Fig. 7G). They were classified by likelihood analysis: the distribution of the angle velocity is constant in a swarm (all angle velocity are equally probable), bi-modal in a stream (cells are moving in equal but opposite directions), and uni-modal in a flock (cells move in one direction) (Fig. 7H). These patterns were observed in all tumor slices examined (Supplementary Figs. 18, 19, and 20). Average cell speeds differed among the three patterns (Fig. 7E and Supplementary Figs. 18, 19, and 20). In the tumor core, swarms moved faster and without orientation, followed by directionally moving flocks and streams (Supplementary Fig. 27). To determine which of these collective motion patterns match oncostream histological features, we analyzed H&E sections corresponding to imaged organotypic slices (Supplementary Fig. 16B). Cells within histological areas corresponding to streams and flocks have an aspect ratio of 2.2 and 2.7, respectively, (spindle-like cells), while those within areas corresponding to swarms have an aspect ratio of 1.2 (round cells) (Supplementary Fig. 16C, D). Moreover, elongated cells within streams and flocks are nematically aligned with each other, whereas round cells within swarms are not (Supplementary Fig. 16E). As predicted by our in silico model48, these results suggest that cell shape, or eccentricity, is driving feature in the organization of collective motion patterns (Supplementary Fig. 16F). Therefore, taking into account cell shape and alignment, we define oncostreams as the histological expression of collective motion patterns (streams and flocks). Notice that only the dynamic analysis of collective motion can differentiate between streams and flocks. At the histological level both appear as oncostreams.
In collective motion of flocks, interactions among individual cells are sufficient to propagate order throughout a large population of starlings49. To define if oncostream migration patterns recall organized collective motion behavior, we analyzed the organization of the cells by performing local pair-wise correlation analysis (relative position and pair directional correlation) by tumor zones (Supplementary Fig. 17A–C). These analyses indicate the spatial correlation of location and alignment between individual cells. We observed that within swarms cells are more separated, as neighbors are located at 20–40 μm. Streams and flocks have higher cell density, and the nearest neighbors are closer, at 20–30 μm (Supplementary Figs. 17E and 18, 19, 20). Pair-wise directional correlation with nearby neighbors showed that cell movement is positively correlated in all patterns at distances between 10 and 50 μm, with higher correlation left-to-right for streams (≈0.2), left-to-right/front-to-back for flocks (≈0.2–0.4), and a lower correlation for swarms (≈0.1) (Supplementary Figs. 17F and 18, 19, 20). We ascertained that tumor cells within oncostreams migrate in a directional manner (streams (↑↓) and flocks (↑↑)), while non-oncostream cre more separated, as neighborells move randomly without directional alignment as swarms. Thus, our analyses strongly indicate that within the tumor core of high grade glioma cells are dynamically heterogeneous and display organized collective migratory behavior associated with tumor histological and genetic features.
Oncostreams increase the intratumoral spread of tumoral and non-tumoral cells
Pair-wise correlation analysis showed that oncostream glioma cells are collectively organized. To test the underlying nature of collective oncostream motility, we analyzed adherent junction markers. Tumors with oncostreams were negative for E-cadherin, whereas N-cadherin was strongly expressed (Supplementary Fig. 21A), suggesting that these fascicles move in a manner akin to collective migration of mesenchymal cells of the neural crest33,50. Although, no difference in N-cadherin were found within oncostreams and the surrounding areas, N-cadherin was elevated in TCGA-GBM (Grade IV) tumors compared to TCGA-LGG (Grade III and II). High levels of N-cadherin correlate with lower survival in HGG patients and mesenchymal transformation (Supplementary Fig. 21B, C).
On the other hand, oncostream growth and motility is unlikely to be due to glioma proliferation. BrdU staining showed no differences between oncostream and non-oncostream regions, and in the oncostreams, the mitotic plane was always perpendicular to the main axis as expected (Supplementary Fig. 21D, E). These results are also supported by the RNA-Seq data of dissected oncostreams, where proliferation genes were not differentially expressed (Fig. 4A–C).
Collective motion could affect the distribution of other cells within the tumor. Since oncostreams are heterogeneous, we inquired about their pro-tumoral role by potentially spreading cells throughout the tumor. We designed co-implantation experiments using human glioma stem cells (MSP-12), and highly aggressive and oncostream-forming glioma cells (GL26) co-implanted into immunosuppressed mice. Implantation of MSP-12 cells alone generated slow-growing tumors (median survival of 6–8 months). At 21 days post-implantation, MSP-12 cells remained restricted to the injection area with an average distance of 28.9 ± 7.73 µm from the actual injection site. Surprisingly, when MSP-12 cells were co-implanted with GL26-citrine cells, MSP-12 cells spread throughout the tumor, moving along oncostreams to much longer distances (83.7 ± 23.74 µm) from the injection site (Fig. 7I–K). Cellular cytoplasmic processes from MSP-12 cells implanted alone displayed a random distribution. However, in co-implanted tumors, such processes from MSP-12 cells are completely aligned with glioma GL26 cells within oncostreams (Fig. 7K, L and Supplementary Fig. 21F). These results strongly suggest that oncostreams function as intra-tumoral highways facilitating the rapid distribution of slow-moving glioma cells and/or non-tumor cells throughout the tumor mass. These findings could help explain the dispersal and intratumoral mixing of diverse clonal populations as demonstrated in previous studies, supporting an important potential role of oncostreams in determining spatial cellular heterogeneity.
Dynamic interactions at the tumor invasive border: Oncostreams foster glioma aggressiveness through collective migration
Furthermore, we asked whether oncostreams contribute to glioma malignant behavior. The analysis of histological sections showed that multicellular fascicles of elongated and aligned cells are found invading from the tumor border into the normal brain parenchyma (Supplementary Fig. 22A). The formation of streams around blood vessels was also observed (Supplementary Fig. 22A). These patterns of invasion are also detected using our deep learning methods (Supplementary Fig. 22B).
We then used our glioma explant model to analyze the glioma dynamics by time-lapse confocal imaging at the tumor invasive border (Figs. 8A and Supplementary Fig. 23). We implanted glioma NPA GFP+ cells into tdTomato (mT/mG) mice so the border between tumor cells and normal brain could be delineated easily. We observed that glioma cells that extended from the tumor border to the normal brain parenchyma adopted different dynamic patterns. At the invasive tumor border cells were seen moving as isolated cells, or as collective migratory fascicles that resembled oncostream structures found in the tumor core (Fig. 8B–G and Supplementary Figs. 23–26).
To objectively distinguish between different dynamic patterns, we determined the angle velocity distribution, and the likelihood that distributions corresponded to either a stream, a flock, or a swarm. We found streams along the perivascular niche, and invading brain parenchyma without following any pre-existing brain structures, as well as cells invading as flocks, and swarms (Fig. 8E, F and Supplementary Figs. 23D, G, H and 24–26A, C, D). The correlation of position and pairwise correlation supports the existence of invading collective motion structures in NPA tumors with high expression of COL1A1 (Supplementary Fig. 22D, E and Supplementary Figs. 23J, K and 24–26F, G). We also determined the participation of collagen fibers in oncostreams migration Immunofluorescence analysis on explant slices showed that collagen fibers are aligned along multicellular fascicles of glioma cells invading the normal brain. These data show how collagen fibers serve as scaffolds for collective tumoral cell invasion (Supplementary Fig. 27).
Our data indicate the existence of a complex framework of collective motion patterns at the glioma border, that is consistent with previous descriptions34. Although the patterns observed at the NPA tumor border are similar to those of the tumor core, cell speed differed between the areas. Cells in the tumor core displayed significantly lower average speeds (stream: 4.26; flock: 5.95, swarm: 6.27 µm/h) compared to cells at the tumor invasive border (stream: 7.95; flock: 7.55, swarm: 8.01 µm/h) (Supplementary Fig. 28A, B).
Then, we asked whether the knockdown of Col1a1 in NPA gliomas affects changes in the patterns of migration. Analysis of tumor cells (GFP+) at the tumor borders of GEMM of gliomas comparing NPA and NPA-shCOL1A1 showed a difference in the cellular patterns found at the tumor invasive border. The analysis of tumor borders revealed an increase in the sinuosity of NPA tumors, a finding compatible with NPA tumors exhibiting a higher proportion of collective migration into the normal brain when compared to NPA-shCOL1A1 tumors (Fig. 8G–I and Supplementary Fig. 29).
Moreover, the time lapse-confocal imaging and migration analysis of NPA-shCOL1A1 explants showed that in these tumors, cells invade the normal brain parenchyma as isolated cells (Supplementary Figs. 30–33). Velocity angle, velocity vector and the likelihood analysis indicated that the overall distribution corresponded predominantly to swarm random patterns (Supplementary Figs. 30–33D, E, F). Further analysis of Relative Position Correlation and Pairwise correlation supports the presence of low density of cells compatible with single cell invasion patterns in NPAshCOL1A1 tumors with low expression of collagen (Supplementary Figs. 30–33G, H).
We conclude that oncostreams (streams and flocks) are organized collective migratory structures enriched in COL1A1 that participate in the dynamic organization of the tumor microenvironment within the tumor core and at the tumor invasive border of high-grade gliomas, impacting the malignant behavior of gliomas. Depletion of collagen1A1 eliminates oncostreams and their associated functions.
Intravital imaging of glioma reveals the existence of oncostreams’ collective motion patterns in vivo
To determine whether our previously described collective migration patterns of glioma cells ex vivo occur also in vivo we performed high resolution time lapse intravital imaging using two photon microscopy. To do so NPA glioma cells were intracranially implanted in the brains of tdTomato (mT/mG) mice at a depth of 0.8 mm (Fig. 9A). To visualize cell migration, we established a cranial window above the injection site (Fig. 9B). After 7–15 days of tumor growth, we acquired z-stack images to obtain a 3D orthogonal view of the tumor growing within the cortex. This allowed us to establish intravital imaging below the brain surface. Next, we selected a position at a depth of >100 µm and proceeded to acquire time lapse images of the tumor growing in the normal parenchyma at an interval of 5 min, for 8–12 h (Fig. 9C, D and Supplementary Figs. 35A, 36A, B, and 37A, B).
In some cases, to determine the exact anatomical location of the tumor, following intravital imaging, we perfused-fixed the brain and performed fluorescence immuno-histochemistry analysis on paraffin-embedded coronal sections which were imaged by confocal microscopy (Supplementary Fig. 35B, C). The location of the area imaged by intravital microscopy (>100 µm) is shown. In this figure, we can identify the location of the tumor (GFP+ cells) containing parenchymal blood vessels (TdTomato+), and astrocytic processes (GFAP+) (Supplementary Fig. 35B, C). Thus, together with Supplementary Fig. 35A, we demonstrate imaging below the brain surface and within the normal parenchyma of the brain.
To analyze the movement of GFP+ glioma cells we used Fiji’s plug-in Track-Mate. In Fig. 9 the imaged area of the tumor core was divided into subregions to determine the existence of migration patterns (Fig. 9E, F). The analysis of cell migration in vivo showed that the glioma cells exhibit organized, nematically aligned cells moving collectively at a depth of 120 µm. Angle velocity distribution analysis determined the existence of stream collective motion patterns in the three delimited subregions (for example in Fig. 9H), illustrating that aligned cells are moving in opposite directions.
To corroborate the existence of stream patterns we applied our likelihood analysis. For streams, the distribution of the angle velocity and velocity vectors displayed a bi-modal distribution (cells were moving in equal but opposite directions) (Fig. 9I), similar to that observed in the explant models. Mean speed varied from 5.50 to 9.95 µm/h (Fig. 9G). A different tumor imaged at a depth of 145 µm also showed the presence of streams (Supplementary Fig. 36).
We then analyzed the tumor invasive border in contact with normal brain (Supplementary Fig. 35). At an imaging depth of 140 µm, cells at the tumor border displayed stream collective dynamics (Supplementary Fig. 35D, Zone A and B). These motion patterns were determined using the angle velocity distribution analysis, and likelihood distribution analysis (Supplementary Fig. 35G, H). Further analysis of Relative Position and Pairwise correlation supports the presence of high density of cells compatible with collective migration patterns (Supplementary Figs. 34B, C, 35I, J, and 36I, J).
To determine whether the knockdown of Col1a1 in NPA gliomas alters the migration patterns observed for NPA gliomas we analyzed a NPAshCOL1A1 tumor by two-photon microscopy at a depth of 110 µm (Supplementary Fig. 37A, B).
The intravital migration analysis of NPAshCOL1A1 gliomas showed that glioma cells migrate without a preferred direction, as swarms (Supplementary Fig. 37C–G). The alignment analysis, Relative Position, and Pairwise correlation confirm the presence of not-aligned low-density cells compatible with single cell invasion patterns in gliomas with Col1a1 downregulation (Supplementary Fig. 37E, J, K).
The collective motion patterns found in vivo resemble the collective motion patterns described using the ex vivo explant model. Our results show that glioma cells expressing collagen are organized in collective dynamic patterns at the tumor core and the tumor invasive border, in tumor explants, and in in vivo intravital models of gliomas analyzed by two photon microscopy.
Discussion
Mesenchymal transformation is a hallmark of tumor heterogeneity that is associated with a more aggressive phenotype and therapeutic resistance13,18,21. Mesenchymal transformation involves fibroblast-like morphological changes associated with active migration and gain of expression of mesenchymal genes as previously described21,22.
Herein we present a comprehensive study that defines the morphological, cellular, dynamic, and molecular properties of multicellular mesenchymal-like structures within gliomas. These structures are fascicles of aligned spindle-like cells found throughout the tumors and represent areas of mesenchymal transformation. We interpret these structures to be the histological expression of areas of collective motion of glioma cells, and we refer to them as oncostreams.
Oncostreams are areas of mesenchymal transformation and are identified histologically as fascicles of aligned and elongated cells. When examined dynamically, we found that tumor cells move by collective motion within the tumor core and at the invading border. The capacity to identify areas of collective motion in histological sections has allowed us to characterize the molecular organization of such dynamic structures. We thus describe the overall molecular mechanisms that govern the organization and function of these structures and demonstrate the causal role of individual mediators. Surprisingly, we discovered that COL1A1 is central to the structural and dynamic characteristics of oncostreams. Indeed, the loss of Col1a1 expression from tumor cells disrupts the structural and functional characteristics of oncostreams, resulting in a complete loss of mesenchymal areas within gliomas and a reduction in glioma malignant behavior (Fig. 10).
The analysis of the gene ontologies over-represented within oncostreams indicates that oncostreams denote areas enriched for “positive regulation of cell migration”, and in mesenchymal-related genes. Interestingly, Col1a1 appeared as a central hub of oncostream organization and mesenchymal transformation. We postulate that oncostreams are the histopathological expression of patterns of collective motion (i.e., streams and flocks) in high grade glioma tumors. Different strategies of cell migration encountered in our gliomas are reminiscent of migratory characteristics observed during embryonic development31,32,50. In developmental biology, collective motion is represented by cells moving together in clusters, sheets, streams, or other multicellular arrangements28,31,32.
Our studies of oncostream dynamics at the tumor core are compatible with the results of Ralitza et al.51. This group studied ex vivo explant slices of spontaneous intestinal carcinoma, and showed that cells within the tumor core were highly dynamic and display directionally correlated cell motion51, similar to our results described herein. Recent in silico based mathematical modeling of glioma cell dynamics by our group, showed that only elongated cells, but not spherical cells, are able to form organized aligned cellular structures in a cell-density dependent manner48. Our modeling studies strongly support our in vivo and ex vivo data described in this manuscript.
Moreover, it has been described that increased matrix cross-linking, enzymatic remodeling, and parallel orientation of matrix collagen fibers stiffens tissue, modifies cell morphology, and promotes cell migration and invasion36,39,40,52,53. Our results support the proposal that oncostreams serve as highways to spread tumor, and non-tumor cells, throughout the tumor. Indeed, oncostream fascicles contain higher amounts of macrophages/microglia and mesenchymal cells. Dispersal of tumor and non-tumoral cells throughout the tumors could help explain the mixing of different clonal populations seen in molecular studies of high grade gliomas10.
This study contributes to explaining how a particular feature of intratumoral heterogeneity, namely mesenchymal transformation, affects HGG progression. Our data indicate that the density of oncostreams plays a potential role in overall glioma malignant behavior in mouse and human gliomas.
Spatially resolved transcriptional analysis using LCM provided insights into the molecular mechanisms that regulate oncostream functions. Oncostreams were defined by a specific transcriptomic signature that matched our immunohistochemical studies. Col1a1 overexpression within oncostreams was complemented with the overexpression of extracellular matrix proteins such as Mmp9, Mmp10, Adamts2, which are known to remodel and participate in the reorganization of collagen fibers. Oncostream fascicles were correspondingly enriched in Col1a1 when assessed by immunohistochemistry.
Within the extracellular matrix, collagen fibers would be able to constitute a scaffold for the organization of the tumor microenvironment and thus potentially act to promote tumor infiltration and invasion. While collagen was previously thought to be a passive barrier that could reduce tumor invasion, it has now been shown that collagen fibers can serve as mechanical and biochemical tracks that facilitate cellular migration and tumor progression36,37,39,54. Previously, multi-cancer computational analysis found that within a mesenchymal transformation signature in different cancers including gliomas, COL1A1 was one of the top differentially expressed genes18,22,55. COL1A1 is overexpressed in high grade malignant gliomas and its expression levels are inversely correlated with patient survival56 as indicated in https://www.cancer.gov/tcga. In our mouse glioma models and in human gliomas, tumors with higher density of oncostreams also express higher levels of COL1A1. COL1A1 is a consistently differentially expressed gene in the glioma mesenchymal signature identified in malignant gliomas and in glioma stem cells as described in previous studies4,9,57. Overall, our data are in agreement with a recent study by Puchalski et al., which assigned genetic and transcriptional information to the most common morphological hallmarks of a glioma, emphasizing the importance of integrative histo-molecular studies8.
Surprisingly, our data indicate significant plasticity of the mesenchymal phenotype in gliomas, similar to other studies13,15. Genetic inhibition of Col1a1 within glioma cells depleted of Col1a1 from tumors, eliminated oncostream structures, reduced the glioma malignant phenotype, and prolonged animal survival. Our findings are comparable with results from various studies that investigated the in vitro and in vivo consequences of collagen depletion, inhibition of collagen cross-linking, or collagen synthesis inhibition on normalizing tumor ECM. In these studies, inhibition of collagen led to changes in the ECM which improved drug penetration, efficacy, as well as tumor access of therapeutic nano-particles or gene-based therapies58,59,60,61,62. In addition, Col1a1 inhibition within glioma cells induced cell intrinsic and extrinsic changes in the TME. Col1a1 inhibition not only inhibits tumor cell proliferation and migration but also decreased the infiltration of microglia/macrophages, endothelial cells proliferation, and perivascular mesenchymal-like cells. As previously shown by other studies, glioblastomas exhibit complex interactions between tumoral and non-tumoral cells, (including macrophages, immune cells, and endothelial cells), which influence tumor growth, transformation, invasion, and response to treatment9,13,63. However, a major remodeling of the tumor mesenchymal phenotype in response to inhibition of Col1a1 has not been described earlier.
Moreover, we found that multicellular oncostream fascicles are detected in both ex vivo and in vivo glioma models, and that oncostreams may potentially act to facilitate tumor cell invasion, thereby increasing glioma aggressiveness. Our findings strongly support the importance of collective motility of glioma cells in the progression of tumor growth and possibly the invasion of normal brain parenchyma, and is supported by earlier studies of normal and pathological conditions27,34,35,64,65,66,67,68. Several lines of evidence suggest that oncostream fascicles within the tumor core are interspersed with normal brain cells, i.e. GFAP+ astrocyte processes, and positive neurofilament staining; in addition, tumors growing in TdTomato mice show green tumor cells intermingled with normal brain (shown by its red fluorescence). However, we acknowledge the limitations of intravital imaging in evaluating the interactions between tumor cells and individual normal brain cells and the significance of our data for the migratory behavior of human gliomas. Further studies using transgenic mice expressing fluorescent proteins in normal brain cells would be valuable to understand oncostream interactions with individual normal brain cells in the tumor core, and at the tumor borders. Although oncostreams are present throughout the tumor core, and tumor invasive borders, the detailed interactions of oncostreams with normal brain awaits further experiments and technical developments; we recognize that the current experiments do not address diffuse brain infiltration in human gliomas. Additional strategies, using fresh human explant models will be necessary to expand our study and characterize oncostream migration and interaction with the normal brain parenchyma.
In summary, our observations suggest that oncostreams are morphologically and molecularly distinct structures that represent areas of collective motion that contribute to tumor growth and aggressiveness. These malignant dynamic structures overexpress Col1a1. Col1a1 knockdown eliminates oncostreams, reduces the mesenchymal phenotype, modifies the TME, and slows tumor progression. Our findings provide alternative views towards understanding tumor mesenchymal transformation and its therapeutic treatment. We propose that depletion of Col1a1 within glioma cells is a promising approach to reprogram mesenchymal transformation in glioma tumors, and could be harnessed as a therapeutic approach, and reduce the glioma malignant phenotype.
Methods
Glioma cell lines and culture conditions
Mouse glioma cells (NPA, NPD, NPAshCOL1A1, NPDshCOL1A1, and GL26) and human glioma cells (MSP-12, SJGBM2) were maintained at 37 °C with 5% CO2 and their respective media42,43,44,45. Mouse NPA, NPD, NPAshCOL1A1, NPDshCOL1A1 neurospheres were derived from our genetically engineered tumors using the Sleeping Beauty (SB) transposase system as42,43,44,45. Mouse GL26 glioma cells were generated by Sugiura K and obtained from the frozen stock maintained by the National Cancer Institute (Bethesda, MD)23. MSP-12 human glioma cell lines were provided by Christine Brown, City of Hope, and SJGBM2 human glioma cells were provided by Children’s Oncology Group (COG) Repository, Health Science Center, Texas Tech University.
Intracranial implantable syngeneic mouse gliomas
All in vivo experiments were conducted according to the guidelines approved by the Institutional Animal Care and Use Committee (IACUC) at the University of Michigan protocols PRO00009599, PRO00009578, and PRO00009551. All animals were housed in an AAALAC accredited animal facility at the University of Michigan. Animals were monitored daily. All tumor bearing animals were euthanized at the time they develop clinical signs of tumor burden (impaired mobility, ruffled fur, hunched posture, protoporphyrin staining around eyes and nose, hunched posture, loss of coordination). Maximal tumor burden did not exceed IACUC guidelines.
Glioma tumors were generated by stereotactic intracranial implantation into the mouse striatum of 3.0 × 104 mouse glioma cells (either, NPA, NPD, or GL26) in 6–8 week old females C57BL/6 mice (Taconic Biosciences) or human glioma cells (SJGBM2) in immune-deficient 6–8 week old males NSG mice, following our methodology43,44,45,69. To test whether oncostream tumor cells help move other cells throughout the tumor we generated a co-implantation glioma model by intracranial implantation of highly malignant GL26-citrine cells with low aggressive human MSP12 glioma cells at a ratio of 1:30 (1000 GL26-citrine cells and 30,000 MSP12 cells) in immune-deficient NSG mice. As controls, NSG mice were implanted with 30,000 MSP12 cells alone or 1000 GL26-citrine cells alone as controls.
Genetically engineered mouse glioma models (GEMM)
We used genetically engineered mouse glioma models for survival analysis and histopathological analysis. Murine glioma tumors harboring different genetic drivers were generated using the Sleeping Beauty (SB) transposon system42,43,44,45. Genetic modifications were induced in postnatal day 1 (P01) male and female wild-type C57BL/6 mice (Jackson Laboratory), according to IACUC regulations.
To design and clone the shRNA targeting the Col1a1 gene (pT2-shCol1a1-GFP4), we tested 3 22-base pair sequences for the mouse Col1a1 gene selected from candidate sequences within the RNAi codex database (http://cancan.cshl.edu/cgi-bin/Codex/Codex.cgi) and InvivoGene (http://www.invivogen.com/sirnawizard). shCol1a1-A: CCCTGGTGATACTGGTGTTAAA, shCol1a1-B: GCAACAGTCGCTTCACCTACA, shCol1a1-C: GCAAGACAGTCATCGAATACA and shRNA Scramble: GAATCTAATCGTATCGTGGCTG. To confirm Col1a1 knockdown, NIH/3T3 mouse cells were transfected with the designed shRNA plasmids for 72 h and subsequently analyzed by Western Blot43. COL1A1 protein levels were normalized to β-ACTIN levels and compared to the Scramble control. Uncropped membrane scans are supplied in the Source data file.
Genetic models generated include the following gene expression/inhibitions: (i) shP53, NRAS-G12V and shAtrx (NPA), (ii) shP53, NRAS-G12V, shAtrx and IDH1-R132H (NPAI), (iii) shP53, NRAS-G12V and Pdgfβ (NPD), (iv) shP53, NRAS-G12V, shAtrx, shCol1a1 (NPAshCOL1A1), (v) shP53, NRAS-G12V, Pdgfβ, shCol1a1 (NPDshCOL1A1). Plasmid sequences were verified by Sanger sequencing. Plasmid sequences described below were used to generate tumors: (i) pT2C-LucPGK-SB100X, transposon & luciferase expression; (ii) pT2-NRAS-G12V, RTK/RAS/PI3K activation; (iii) pT2-shP53-GFP4, P53 knock-down; (iv) pT2-shAtrx-GFP4, ATRX knock-down; (v) pKT-IDH1(R132H)-IRES-Katushka, mIDH1 expression; (vi) pT2-shP53-Pdgfβ-GFP4, P53 knock-down in combination with PDGFβ ligand overexpression. The pT2CAG-NRAS-G12V and pT2-shP53-GFP4 plasmids were the generous gift of Dr. John Ohlfest (University of Minnesota). Mice were injected with the plasmids. Plasmid uptake in pups and tumor growth was monitored by IVIS® Spectrum imaging. Adult mice displaying symptoms of morbidity were transcardially perfused43.
Analysis of human glioma tissues
Oncostream presence was analyzed in unidentified H&E sections of paraformaldehyde-fixed paraffin-embedded human glioma samples obtained from primary surgery from the University of Michigan Medical School Hospital. All patients gave informed consent for collection of tissue collection under Institutional Review Board–approved protocols (HUM00057130 and HUM00024610) at the University of Michigan.
To determine the presence of oncostreams in a large cohort of human glioma tissues we used the biospecimens from “The Cancer Genome Atlas Research Network” (TCGA) from the Genomic Data Commons Data Portal, National Cancer Institute, NIH (https://portal.gdc.cancer.gov). We analyzed primary Glioblastoma multiforme (TCGA-GBM) and Low-Grade Glioma (TCGA-LGG) databases. We selected cases that have available the Slide Image and diagnostic Slides. The diagnostic slides are available for TCGA-GBM: 389 patients and TCGA-LGG: 491 patients. The presence of oncostreams was scored on 100 TCGA-GBM Grade IV tissue samples and 120 TCGA-LGG samples.
Oncostream presence was analyzed on tumors classified by histology grade (grade II, III, and IV) as shown in Supplementary Table 1. GBM were also analyzed by molecular subtypes: Classical (CL), Mesenchymal (MES), and Proneural (PN). LGG were classified in relation to grade and subtypes which consider IDH status and 1p/19q co-deletion (IDHmut-codel, IDHmut-non-codel and IDHwt) (Supplementary Data 1). H&E histology samples were analyzed at high magnification using the Slide Image Viewer from the data portal. Histological material containing brain tumors and oncostreams of both rodent and human gliomas were evaluated by C.G.K. (board certified pathologist), A.C. and PRL. Concordance regarding the presence or absence of oncostreams, between the three evaluators, was >90%. Due to the need for good quality morphological preservation, only PFPE sections were used. Clinical data including age, sex, pathology, survival, treatment information, and data including information of MGMT DNA methylation status, IDH1 mutation status, G-CIMP DNA methylation status, were obtained from http://firebrowse.org, http://gliovis.bioinfo.cnio.es and https://portal.gdc.cancer.gov data portals (Supplementary Data 1).
Cell aspect ratio and alignment analysis in H&E tumor sections
Images were obtained using bright-field microscopy of H&E stained paraffin sections (Olympus BX53 Upright Microscope). Tumors were imaged using 40× and 20× objectives. Images were processed using the program ImageJ. Image processing included color deconvolution to isolate nuclei, transforming images to 8-bit, and adjusting the threshold to remove background. Elliptical overlay masks were then imposed over the nuclei to match their shape. The shapes of these masks were then analyzed for the shape descriptors aspect ratio and circularity. For cell alignment analysis images were processed using ImageJ. Briefly, image processing included creating a ROI around the stream area and the non-stream area. These ROIs were then saved as separate images. Both images underwent color deconvolution to isolate nuclear stain, 8-bit conversion, and threshold adjustment to remove background. Images were then analyzed for the Feret’s angle of the nucleus. The Feret’s angle is the angle (0°–180°) that is taken from the x-axis to a line parallel with the longest distance across the particle being considered. Histograms were generated with these data in MATLAB using the Matplotlib plugin.
Deep learning analysis for oncostreams detection on H&E staining of glioma tissue
A fully convolutional neural network (fCNN) was trained in order to identify and segment oncostreams in histologic images70. We implemented a U-Net architecture to provide semantic segmentation of glioma specimens using deep learning71,72,73. Our oncostream dataset consisted of images from mouse tissues and open-source images from The Cancer Genome Atlas (TCGA). A total of 109 hematoxylin and eosin (H&E) stained histologic mouse images and 64 from TCGA were reviewed and oncostreams were manually segmented by the study authors (A.C, A.E.A, and P.R.L.). Images from both datasets were then augmented by randomly sampling regions within each image to generate unique patches (~300 patches/image). The location and scale of each patch was randomly chosen to allow for oncostream segmentation to be scale invariant. First, using the mice dataset only, six iterations of training/validation set splits (80%/20%) were generated by randomly sampling unique, non-overlapping regions from each of labeled histologic images and used for model selection/hyper-parameter tuning and model testing, respectively. Our fCNN was trained for binary classification of foreground (oncostream) and background (non-oncostream) using a binary cross-entropy loss function. Both pixel-level classification accuracy and intersection over union (IOU) were used as metrics to evaluate model performance. IOU values over the testing set there were manually annotated. Our model generalized well to both mouse and human data. In addition to having a mean IOU value of 80.3%, our model did not make any false positive errors in TCGA grade II gliomas (Supplementary Table 7). The model was trained using the Adam optimizer with an initial learn rate ɑ = 0.0001, β1 = 0.9, β2 = 0.999, and ε = 10E−771. We used a scheduled learning rate decrease such that the rate was halved every 10 epochs and the model was trained for a total of 75 epochs for each iteration. The best performing model on the mouse dataset was then used as a pre-trained fCNN to initialize training on the TCGA data. We used both mouse and TCGA images for fCNN training with 20% of the TCGA data held out for model validation. Our fCNN was implemented using the model-level Python-based API, Keras (version 2.2.0), with a TensorFlow74 (version 1.8.0) backend running on two NVIDIA GeForce 1080 Ti graphical processing units. This model is generalizable to both mouse and human images.
Immunohistochemistry on paraffin embedded brain tumors (IHC-DAB)
Following perfusion with Tyrode saline solution, mouse brains were fixed in 4% paraformaldehyde (PFA), and post-fixed for an additional 48 h at 4 °C. Brains were then processed and embedded in paraffin at the University of Michigan Microscopy & Image Analysis Core Facility using a Leica ASP 300 paraffin tissue processor/Tissue-Tek paraffin tissue embedding station (Leica, Buffalo Grove IL). Tissue was sectioned using a rotary microtome (Leica) set to 5 μm in the z-direction. Endogenous Peroxidase quenching was carried out using a 0.3% H2O2 incubation for 5 min at room temperature. Heat-induced antigen retrieval was performed using 10 mM citric acid, 0.05% Tween 20, pH 6.0. Tissue permeabilization and blocking were completed using PBS 0.2% Tween-20 with 5% goat serum for one hour at room temperature. Tissue was incubated with primary antibodies at 4 °C overnight at concentrations detailed in Supplementary Table 6. Tissue sections were then incubated with secondary biotinylated antibodies (Polyclonal Goat Anti-Rabbit Immunoglobulins/Biotin, Agilent (E043201-6) at a 1:1000 dilution in PBS with 0.2% Tween-20 overnight at 4 °C. ABC Avidin-Biotin-Complex Binding reagent (Vectastain Elite ABC kit) and Betazoid DAB Chromogen detection kit (BioCare BDB2004) was used according to the manufacturer’s instructions.
Immunofluorescence on paraffin-embedded sections from brain tumors
Paraformaldehyde fixed and paraffin-embedded tissues were sectioned and then de-paraffinized and re-hydrated. Heat-induced antigen retrieval was performed using 10 mM Citric Acid, 0.05% Tween 20, pH 6.0. Permeabilization was performed using 0.5% TritonX-100 in PBS for 30 min at room temperature while shaking. Tissue sections were blocked in 10% horse serum and 3% BSA in PBS. This method was performed following previous protocol43. Primary antibodies were incubated at 4 °C overnight in a humid chamber in 3% BSA in PBS at concertation detailed in Supplementary Table 8. Tissues were then incubated for 90 min at room temperature with Alexa Fluor™ 488, Alexa Fluor™ 555, Alexa Fluor Plus™ 647, or Alexa Fluor 594™ conjugated secondary antibodies (Invitrogen, Thermofisher Scientific) at a dilution of 1:1000 in PBS. Secondary antibodies names and used concentrations are detailed in Supplementary Table 6. COL1A1 detection was performed using HRP-conjugated streptavidin was incubated for 60 min at room temperature. Alexa Fluor™ 488 Tyramide was incubated for 10 min. Nuclei were stained with DAPI (1:1000) in PBS for 5 min.
Immunohistochemistry on vibratome brain tumor sections
For immunohistochemistry on vibratome brain tumor sections were left in 4% paraformaldehyde fixation for 48 h and then transferred to PBS 0.1% sodium azide for an additional 24 h at 4 °C. A Leica VT100S vibratome was used to obtain 50 µm coronal brain sections. The immunohistochemistry protocol was performed as described below and as previously performed75,76. Vibratome sections were permeabilized in TBS-Triton-X 0.1% for 60 min. Antigen retrieval was performed in 10 mM sodium citrate. Non-specific antibody binding was blocked with 10% goat serum in TBS-Triton-X 0.1% for 1 h at room temperature. Brain sections were then incubated with primary antibody diluted in TBS-Triton-X 0.1%, 1% goat serum, and 0.1% sodium azide for 24 h at RT, in the dark. Sections were then washed 6 times in TBS-Triton-X 0.1% and then incubated with the secondary antibody diluted in 1% goat serum in TBS-Triton-X 0.1% for 24 h at RT, in the dark. Finally, sections were washed 6 times and incubated with 5 µg/ml of 4′,6-diamidino-2-phenylindole (DAPI) (Life technologies, D21490) in PBS for 5 min. Sections were washed again 3 times and mounted on microscope slides with prolong gold anti-fade reagent (Invitrogen, P36930).
Immunohistochemistry and immunofluorescence imaging
Images were obtained using bright-field microscopy from independent biological replicates (Olympus BX53 Upright Microscope). Ten different fields of each section were selected at random for study to include heterogeneous tumor areas. For immunofluorescence on paraffin embedded sections from brain tumors images were acquired with a laser scanning confocal microscope (LSM 880, Axio Observer, Zeiss, Germany). Imaged were analyzed using Zen (Blue edition) version 2.5. Integrated density was determined for the analysis of COL1A1 expression using Image J.
Laser capture microdissection (LCM) of brain tumors
Malignant glioma tumors were induced by intracranial implantation of dissociated NPA neurospheres in C57BL/6 mice as described above. LCM approach was used to analyze differential mRNA expression of intra-tumoral glioma heterogeneity. This methodology conserves tissue histology integrity and RNA quality77. Briefly, animals were perfused with Tyrode solution (0.8% NaCl, 0.0264% CaCl2, 0.005% NaH2PO4, 0.1% glucose, 0.1% NaHCO3, and 0.02% KCl) for 5 min followed by 30% Sucrose dissolved in Tyrode solution for 15 min. Tissue was maintained overnight at 4 °C in 30% sucrose solution prepared in RNAse free water. Brain tumors were cryopreserved in OCT and stored at −80 °C. Tissue was cryosectioned at 10 µm thickness, placed onto 2 µm polyethylene naphthalate (PEN) and stored at −80 °C. Tumor sections were fixed in ethanol and stained with 4% Cresyl violet and 0.5% eosin dyes dissolved in ethanol. Oncostream areas from three independent mouse glioma samples were dissected from surrounding glioma tissue using a LMD7000 Leica LCM. Tissue was collected in DNase/RNase free 0.5 ml PCR flat head tubes containing 30 µL of RLT lysis buffer and stored at −80 °C until RNA purification.
RNA isolation, quality control and cDNA library preparation
RNA was isolated for laser microdissected tissues using the RNeasy Plus Micro Kit following the manufacturer’s recommendations (Qiagen). A total tissue area of 2.5 × 106 to 7 × 106 µm2 was dissected for each group to increase the efficiency of the mRNA extraction and cDNA library preparation.
0.25 to 10 ng of total RNA was used for cDNA library preparation using a kit suitable for RNA isolation at pico-molar concentrations (MARTer Stranded Total RNA-Seq Kit v2 - Pico Input Mammalian) following manufacturer recommended protocol (Clontech/Takara Bio #635005). Sample volume was adjusted to 350 µL with lysis buffer with 1% β-mercaptoethanol. DNA was removed using gDNA eliminator spin columns. RNA was eluted in 12 µL of RNase-free water warmed at 37 °C.
Before library preparation, RNA was assessed for quality using the TapeStation System (Agilent, Santa Clara, CA) using the manufacturer’s recommended protocols. We obtained a RIN between 6 and 7 after laser microdissection of glioma tissue. A RIN of 6 was determined to be suitable for cDNA library preparation.
Final libraries were checked for quality and quantity by bioanalyzer on a Eukaryote total RNA Pico chip using the manufacturer’s recommended instructions. The samples were pooled, sequenced on the Illumina HiSeq 4000, as paired-end 50 nt reads with 10% PhiX spike-in, according to the manufacturer’s recommended protocols.
RNA-Sequencing and bioinformatics analysis
Quality of the raw reads data for each sample using FastQC (version v0.11.3) to identify features of the data that may indicate quality problems (e.g. low quality scores, over-represented sequences, inappropriate GC content).
Tuxedo Suite software package was used for alignment, differential expression analysis, and post-analysis diagnostics by the University of Michigan Bioinformatics Core. Reads were aligned to the reference genome including both mRNAs and Ensemble lncRNAs (UCSC mm10) using TopHat (version 2.0.13) and Bowtie2 (version 2.2.1). Default parameter settings were used for alignment, with the exception of: “b2-very-sensitive” telling the software to spend extra time searching for valid alignments. FastQC was used for a second round of quality control (post-alignment), to ensure that only high quality data would be input to expression quantitation and differential expression analysis. Cufflinks/CuffDiff (version 2.1.1) technique was implemented for differential expression analysis, using UCSC mm10.fa as the reference genome sequence. For expression quantitation, normalization, and differential expression analysis, “—multi-read-correct” was used to adjust expression calculations for reads that map in more than one locus, as well as “compatible-hits-norm” and “upper-quartile–norm” for normalization of expression values. Diagnostic plots were generated using the CummeRbund R package.
Genes and transcripts have been identified as differentially expressed based on three criteria: test status = “OK”, FDR ≤ 0.05, and fold change ≥ ± 1.5. Genes and isoforms were annotated with NCBI Entrez GeneIDs and text descriptions. Volcano plots demonstrating total genes and DE genes were produced with the R base package. The Data (significantly impacted GOs biological processes) were analyzed using Advaita Bio’s iPathwayGuide78.
Differentially expressed genes of all tumors were used for gene ontology (GO) analyses and significantly impacted Pathway analyses using Advaita Bio’s iPathwayGuide78. Network analysis of the DE genes were achieved using Cytoscape and Reactome App. Network was clustered by Reactome Functional Interaction (FI). Analysis of the expression of COL1A1, E-Cadherin, and N-Cadherin in normal tissue and in human gliomas were performed using the dataset of TCGA-GBM and TCGA-LGG from Gliovis (http://gliovis.bioinfo.cnio.es)47.
Tumor explant glioma model and time-lapse confocal imaging
For the analysis of glioma dynamics, we generated tumors by intracranial implantation of 3 × 104 NPA neurospheres which were used to carry out a 3D explant slice culture glioma model. C57BL6 6–8 weeks old females mice (Taconic Biosciences) were used for the dynamic analyses of the tumor core and B6.129(Cg)-Gt(ROSA)26Sortm4(ACTB-tdTomato,-EGFP)Luo/J- transgenic 6–8 weeks old females mice (Jackson laboratory, STOCK 007676) were used for the analysis of the tumor invasive border. The red color corresponds to a cell membrane-localized tdTomato (mT) fluorescence expression which is widespread in all cells and tissues. Mice were euthanized at 19 days’ post-implantation for NPA tumors and 31 days’ post-implantation for NPAshCOL1A1 tumors. Brains were removed, dissected, and embedded in a 4% agarose solution and kept on ice for 5 min. Then, brains were submerged in ice-cold and oxygenated media (DMEM High-Glucose without phenol red, GibcoTM, USA) and sectioned in a Leica VT100S vibratome (Leica, Buffalo Grove, IL) set to 300 μm in the z-direction. All steps were performed under sterile conditions in a BSL2 laminar flow hood. Brain tumor sections were transferred to laminin-coated Millicel Cell Culture Insert (PICM0RG50, Millipore Sigma, USA) (Supplementary Fig. 23A). Tumor slices were maintained in DMEM F-12 media supplemented with 25% FBS, Penicillin-Streptomycin 10.000 U/mlL at 37 °C with a 5% CO2 atmosphere. After 4–18 h media were replaced with DMEM-F12 media supplemented with B27 2%, N2 1%, Normocin 0.2%, Penicillin-Streptomycin 10.000 U/ml and growth factors EGF and FGF 40 ng/ml. For time-lapse imaging, slices were placed in an incubator chamber of a single photon microscope. We utilized an inverted Zeiss LSM880 laser scanning confocal microscope with AiryScan (Carl Zeiss, Jena, Germany), equipped with an incubation chamber kept at 37 °C with a 5% CO2. To validate the depth of imaging, in some experiments (see Supplementary Fig. 23A–C), before time lapse imaging, we obtained high resolution z-stacks with approximate dimensions of z = 143.81, x = 850.19, y = 850.19. Time-lapse images were then obtained every ten minutes for 100-300 cycles, selecting the imaging plane to fall at the middle of the z-stack to avoid imaging at the bottom of the explant. Following movie acquisition, sections were fixed in 4% paraformaldehyde (PFA) for 2 days. Fixed sections were embedded in 2% agarose for H&E and immunohistochemistry analysis. Sections were processed and embedded in paraffin at the University of Michigan Microscopy & Image Analysis Core Facility using a Leica ASP 300 paraffin tissue processor/Tissue-Tek paraffin tissue embedding station (Leica, Buffalo Grove IL). Tumor explants were used for collagenase treatment. Sections were then treated for 48 h with collagenase (C2399, MilliporeSigma, USA) at a concentration of 5, 10, or 15 units/ml or vehicle control. Following treatment, sections were fixed in 4% paraformaldehyde (PFA) for 2 days.
Collagenase treatment of tumor explant brain slices model
Glioblastoma tumors were generated by intracranial implantation of 3.0 × 104 NPA neurosphere cells into the striatum of C57BL/6 mouse brains. At 19 days following implantation, mice were euthanized per ULAM guidelines. Brains underwent explant sectioning as described above and maintained on Millicel Cell Culture. Sections were then treated for 48 h with collagenase (C2399, Millipore Sigma, USA) at a concentration of 5, 10, or 15 units/ml or vehicle control. Following treatment, sections were fixed in 4% paraformaldehyde (PFA) for 2 days. Fixed sections were embedded in 2% agarose. Sections were then processed and embedded in paraffin at the University of Michigan Microscopy & Image Analysis Core Facility using a Leica ASP 300 paraffin tissue processor/Tissue-Tek paraffin tissue embedding station (Leica, Buffalo Grove IL).
Cranial window implantation and two photon intravital live imaging in vivo
Craniotomy and cranial window implantations were performed as described here and in Supplementary Data and following previous protocols described by us and others23,79,80. The protocol was conducted according to the guidelines approved by the Institutional Animal Care and Use Committee (IACUC) at the University of Michigan. Briefly, mice were anesthetized and placed in a stereotactic frame. A craniotomy of 3 × 3 mm size was made over the right hemisphere between bregma and lambda. 5 × 104 GFP+ NPA glioma cells were intracranially implanted at a depth of 0.8 mm ventral, near the center of the craniotomy overlying the brain cortex of males and females, 6–8 weeks old B6.129(Cg)-Gt(ROSA)26Sortm4(ACTB-tdTomato-EGFP)Luo/J mice (Jackson Laboratory, STOCK 007676). These mice were utilized to identify (in red) normal brain tissue, and thus establish tumor borders. The cranial window was covered with two round microscope cover glasses, and a metal head bar was positioned on the skull posterior to the cranial window. One week post NPA tumor cells’ injection and cranial window implantation, and two-weeks post NPAshCOL1A1 implantation, intravital live imaging was performed using a two-photon microscope (Bruker Technology) with a 20× water immersion objective (Olympus, NA 1.0) for 8–12 h. To avoid imaging at the brain surface, first we acquired high-resolution 3D z-stacks spanning 0–330 µm depth from the surface of the brain. Z-stacks were then imported to Imaris viewer version 9.8 (Bitplane, Imaris, Oxford Instruments, MA, USA) to obtain 3D images. We then used Orthoslicer3D to reveal the depth of the imaging position in relation to the surface of the brain for time-lapse data acquisition. More methodological details are available in Supplementary Methods.
Mathematical analysis of tumor cell movement
To determine the movement of cells in different areas of the tumor we performed localized statistical analysis in different zones of the tumor. We selected localized areas based on the organization of cells in clusters, group of cells moving together with similar distribution. Raw data of 4 movies from the tumor core and 4 movies from the tumor border were analyzed for 293 cycles (core) and 186 cycles (border) for a frame rate of Δt = 10 min between image acquisition. To track cell motion, we used the software Fiji with the plugin TrackMate81. Analysis was performed as indicated in detail in Supplementary Methods.
Classification of glioma migration patterns
To classify the collective cellular motion behavior of the three types of patterns called flock, stream, and swarm illustrated in Supplementary Fig. 16F we used as criteria the orientation of each cell described by its unique angle velocity denoted θi. More precisely, we transformed the Angle Velocity Distribution graph into a histogram where we examined the distribution of all the values θi. A schematic representation of these distributions is depicted in Fig. 7G. Considering a data-set θn n = 1…N of orientations where N is the total number of cells, θn ϵ [0, 2π] is the direction of the cell n. We tested three types of distributions ρ to describe the dataset and gave a likelihood in each case as described in Supplementary Methods. The Akaike Weight (AW) indicates which pattern has the highest likelihood in each experimental situation82.
Statistical Analysis
All in vivo experiments were performed using independent biological replicates, as indicated in the text and figures for each experiment. Data are shown as the mean ± SEM. Any difference was considered statistically significant when p < 0.05. In experiments that included one variable, the one-way ANOVA test was used. In experiments with two independent variables, the two-way ANOVA test was employed. A posterior Tukey’s multiple comparisons test was used for mean comparisons. Student’s two-sided t-test was used to compare unpaired data from two samples. Survival data were entered into Kaplan–Meier survival curves plots, and statistical analysis was performed using the Mantel log-rank test. Median survival is expressed as MS. Significance was determined if p < 0.05. All analyses were conducted using GraphPad Prism (version 8.0.0) or SAS (2021 SAS Institute, Cary, NC). Each statistical test used is indicated within the figure legends.
Reporting summary
Further information on research design is available in the Nature Research Reporting Summary linked to this article.
Data availability
All data associated with this study are in the paper and/or the Supplementary Information. RNA-Seq dataset generated in this study have been deposited at the NCBI’s Gene Expression Omnibus (GEO) with identifier GSE188970. Additionally, the following public databases were used: TCGA glioma diagnostic tissue slides from the Genomic Data Commons Portal of the National Cancer Institute [https://portal.gdc.cancer.gov]. Clinical data [http://firebrowse.org]; [http://gliovis.bioinfo.cnio.es]; and [https://portal.gdc.cancer.gov]. TCGA dataset related to Col1A1, E-Cadherin, and N-Cadherin expression and its correlation with patient survival [http://gliovis.bioinfo.cnio.es]. To select shRNA targeting Col1a1 gene, we used the RNAi codex database [http://cancan.cshl.edu/cgi-bin/Codex/Codex.cgi] and InvivoGen’s siRNA Wizard [http://www.invivogen.com/sirnawizard]. All the movies/imaging data generated in this study have been provided in the supplementary information. The remaining data are available within the article, supplementary information, or source data file. Cells, plasmids, and other reagents developed in this study could be made available upon request to pedrol@umich.edu. Source data are provided with this paper.
Code availability
The analysis of oncostreams in mouse and human glioma tissue was performed using U-Net architecture to provide semantic segmentation of specimens using deep learning. Public GitHub repository for the project code can be found at https://github.com/MLNeurosurg/DeepStreams. Analysis of glioma cells dynamics was performed using the Julia Programing Language. Link for this project Script and their dependencies can be found at public GitHub repository https://github.com/smotsch/analysis_glioma.
References
Parsons, D. W. et al. An integrated genomic analysis of human glioblastoma multiforme. Science 321, 1807–1812 (2008).
Louis, D. N. et al. The 2007 WHO classification of tumours of the central nervous system. Acta Neuropathol. 114, 97–109 (2007).
Ceccarelli, M. et al. Molecular profiling reveals biologically discrete subsets and pathways of progression in diffuse glioma. Cell 164, 550–563 (2016).
Verhaak, R. G. et al. Integrated genomic analysis identifies clinically relevant subtypes of glioblastoma characterized by abnormalities in PDGFRA, IDH1, EGFR, and NF1. Cancer Cell 17, 98–110 (2010).
Sottoriva, A. et al. Intratumor heterogeneity in human glioblastoma reflects cancer evolutionary dynamics. Proc. Natl Acad. Sci. USA 110, 4009–4014 (2013).
Brennan, C. W. et al. The somatic genomic landscape of glioblastoma. Cell 155, 462–477 (2013).
Nicholson, J. G. & Fine, H. A. Diffuse glioma heterogeneity and its therapeutic implications. Cancer Discov. 11, 575–590 (2021).
Puchalski, R. B. et al. An anatomic transcriptional atlas of human glioblastoma. Science 360, 660–663 (2018).
Wang, Q. et al. Tumor evolution of glioma-intrinsic gene expression subtypes associates with immunological changes in the microenvironment. Cancer Cell 32, 42–56.e46 (2017).
Patel, A. P. et al. Single-cell RNA-seq highlights intratumoral heterogeneity in primary glioblastoma. Science 344, 1396–1401 (2014).
Bergmann, N. et al. The intratumoral heterogeneity reflects the intertumoral subtypes of glioblastoma multiforme: A regional immunohistochemistry analysis. Front. Oncol. 10, 494 (2020).
Garofano, L. et al. Pathway-based classification of glioblastoma uncovers a mitochondrial subtype with therapeutic vulnerabilities. Nat. Cancer 2, 141–156 (2021).
Kim, Y. et al. Perspective of mesenchymal transformation in glioblastoma. Acta Neuropathol. Commun. 9, 50 (2021).
Hara, T. et al. Interactions between cancer cells and immune cells drive transitions to mesenchymal-like states in glioblastoma. Cancer Cell 39, 779–792.e711 (2021).
Neftel, C. et al. An integrative model of cellular states, plasticity, and genetics for glioblastoma. Cell 178, 835–849.e821 (2019).
Majc, B. et al. Epithelial-to-mesenchymal transition as the driver of changing carcinoma and glioblastoma microenvironment. Biochim. Biophys. Acta Mol. Cell Res. 1867, 118782 (2020).
Azam, Z., To, S. T. & Tannous, B. A. Mesenchymal transformation: The rosetta stone of glioblastoma pathogenesis and therapy resistance. Adv. Sci. 7, 2002015 (2020).
Behnan, J., Finocchiaro, G. & Hanna, G. The landscape of the mesenchymal signature in brain tumours. Brain 142, 847–866 (2019).
Yang, J. et al. Guidelines and definitions for research on epithelial-mesenchymal transition. Nat. Rev. Mol. Cell Biol. 21, 341–352 (2020).
Williams, E. D., Gao, D., Redfern, A. & Thompson, E. W. Controversies around epithelial-mesenchymal plasticity in cancer metastasis. Nat. Rev. Cancer 19, 716–732 (2019).
Carro, M. S. et al. The transcriptional network for mesenchymal transformation of brain tumours. Nature 463, 318–325 (2010).
Cheng, W. Y., Kandel, J. J., Yamashiro, D. J., Canoll, P. & Anastassiou, D. A multi-cancer mesenchymal transition gene expression signature is associated with prolonged time to recurrence in glioblastoma. PLoS One 7, e34705 (2012).
Baker, G. J. et al. Mechanisms of glioma formation: iterative perivascular glioma growth and invasion leads to tumor progression, VEGF-independent vascularization, and resistance to antiangiogenic therapy. Neoplasia 16, 543–561 (2014).
Ray, A., Morford, R. K., Ghaderi, N., Odde, D. J. & Provenzano, P. P. Dynamics of 3D carcinoma cell invasion into aligned collagen. Integr. Biol. 10, 100–112 (2018).
Pickup, M. W., Mouw, J. K. & Weaver, V. M. The extracellular matrix modulates the hallmarks of cancer. EMBO Rep. 15, 1243–1253 (2014).
Deisboeck, T. S. & Couzin, I. D. Collective behavior in cancer cell populations. Bioessays 31, 190–197 (2009).
Friedl, P., Locker, J., Sahai, E. & Segall, J. E. Classifying collective cancer cell invasion. Nat. Cell Biol. 14, 777–783 (2012).
Friedl, P. & Mayor, R. Tuning collective cell migration by cell–cell junction regulation. Cold Spring Harb. Perspect. Biol. https://doi.org/10.1101/cshperspect.a029199 (2017).
Méhes, E. & Vicsek, T. Collective motion of cells: From experiments to models. Integr. Biol. 6, 831–854 (2014).
Rørth, P. Fellow travellers: Emergent properties of collective cell migration. EMBO Rep. 13, 984–991 (2012).
Friedl, P. & Gilmour, D. Collective cell migration in morphogenesis, regeneration, and cancer. Nat. Rev. Mol. Cell Biol. 10, 445–457 (2009).
Scarpa, E. & Mayor, R. Collective cell migration in development. J. Cell Biol. 212, 143–155 (2016).
Theveneau, E. & Mayor, R. Neural crest delamination and migration: From epithelium-to-mesenchyme transition to collective cell migration. Dev. Biol. 366, 34–54 (2012).
Alieva, M. et al. Intravital imaging of glioma border morphology reveals distinctive cellular dynamics and contribution to tumor cell invasion. Sci. Rep. 9, 2054 (2019).
Haeger, A., Krause, M., Wolf, K. & Friedl, P. Cell jamming: Collective invasion of mesenchymal tumor cells imposed by tissue confinement. Biochim. Biophys. Acta 1840, 2386–2395 (2014).
Brett, E. A., Sauter, M. A., Machens, H. G. & Duscher, D. Tumor-associated collagen signatures: Pushing tumor boundaries. Cancer Metab. 8, 14 (2020).
Mammoto, T. et al. Role of collagen matrix in tumor angiogenesis and glioblastoma multiforme progression. Am. J. Pathol. 183, 1293–1305 (2013).
Huijbers, I. J. et al. A role for fibrillar collagen deposition and the collagen internalization receptor endo180 in glioma invasion. PLoS One 5, e9808 (2010).
Fang, M., Yuan, J., Peng, C. & Li, Y. Collagen as a double-edged sword in tumor progression. Tumour Biol. 35, 2871–2882 (2014).
Payne, L. S. & Huang, P. H. The pathobiology of collagens in glioma. Mol. Cancer Res. 11, 1129–1140 (2013).
Pointer, K. B. et al. Association of collagen architecture with glioblastoma patient survival. J. Neurosurg. 126, 1812–1821 (2017).
Calinescu, A. A. et al. Transposon mediated integration of plasmid DNA into the subventricular zone of neonatal mice to generate novel models of glioblastoma. J. Vis. Exp.: JoVE https://doi.org/10.3791/52443 (2015).
Comba, A. et al. Fyn tyrosine kinase, a downstream target of receptor tyrosine kinases, modulates antiglioma immune responses. Neuro-Oncol. 22, 806–818 (2020).
Koschmann, C. et al. ATRX loss promotes tumor growth and impairs nonhomologous end joining DNA repair in glioma. Sci. Transl. Med. 8, 328ra328 (2016).
Núñez, F. J. et al. IDH1-R132H acts as a tumor suppressor in glioma via epigenetic upregulation of the DNA damage response. J. Sci. Transl. Med. 11, eaaq1427 (2019).
Brat, D. J. et al. Comprehensive, integrative genomic analysis of diffuse lower-grade gliomas. N. Engl. J. Med. 372, 2481–2498 (2015).
Bowman, R. L., Wang, Q., Carro, A., Verhaak, R. G. & Squatrito, M. GlioVis data portal for visualization and analysis of brain tumor expression datasets. Neuro-Oncol. 19, 139–141 (2017).
Jamous, S., Comba, A., Lowenstein, P. R. & Motsch, S. Self-organization in brain tumors: How cell morphology and cell density influence glioma pattern formation. PLoS Comput. Biol. 16, e1007611 (2020).
Bialek, W. et al. Statistical mechanics for natural flocks of birds. Proc. Natl Acad. Sci. USA 109, 4786–4791 (2012).
Szabó, A. & Mayor, R. Mechanisms of neural crest migration. Annu. Rev. Genet. 52, 43–63 (2018).
Staneva, R. et al. Cancer cells in the tumor core exhibit spatially coordinated migration patterns. J. Cell Sci. https://doi.org/10.1242/jcs.220277 (2019).
Egeblad, M., Rasch, M. G. & Weaver, V. M. Dynamic interplay between the collagen scaffold and tumor evolution. Curr. Opin. Cell Biol. 22, 697–706 (2010).
Provenzano, P. P. et al. Collagen reorganization at the tumor-stromal interface facilitates local invasion. BMC Med. 4, 38 (2006).
Shintani, Y., Hollingsworth, M. A., Wheelock, M. J. & Johnson, K. R. Collagen I promotes metastasis in pancreatic cancer by activating c-Jun NH(2)-terminal kinase 1 and up-regulating N-cadherin expression. Cancer Res. 66, 11745–11753 (2006).
Kim, H., Watkinson, J., Varadan, V. & Anastassiou, D. Multi-cancer computational analysis reveals invasion-associated variant of desmoplastic reaction involving INHBA, THBS2, and COL11A1. BMC Med. Genomics 3, 51 (2010).
GLASS Consortium. Glioma through the looking GLASS: molecular evolution of diffuse gliomas and the Glioma Longitudinal Analysis Consortium. Neuro Oncol 20, 873–884 (2018).
Behnan, J. et al. Differential propagation of stroma and cancer stem cells dictates tumorigenesis and multipotency. Oncogene 36, 570–584 (2017).
Dolor, A. & Szoka, F. C. Jr. Digesting a path forward: The utility of collagenase tumor treatment for improved drug delivery. Mol. Pharm. 15, 2069–2083 (2018).
Diop-Frimpong, B., Chauhan, V. P., Krane, S., Boucher, Y. & Jain, R. K. Losartan inhibits collagen I synthesis and improves the distribution and efficacy of nanotherapeutics in tumors. Proc. Natl Acad. Sci. USA 108, 2909–2914 (2011).
Kumar, S., Henning-Knechtel, A., Magzoub, M. & Hamilton, A. D. Peptidomimetic-based multidomain targeting offers critical evaluation of Aβ structure and toxic function. J. Am. Chem. Soc. 140, 6562–6574 (2018).
Kato, M., Hattori, Y., Kubo, M. & Maitani, Y. Collagenase-1 injection improved tumor distribution and gene expression of cationic lipoplex. Int. J. Pharm. 423, 428–434 (2012).
Lee, S. et al. Extracellular matrix remodeling in vivo for enhancing tumor-targeting efficiency of nanoparticle drug carriers using the pulsed high intensity focused ultrasound. J. Control Release 263, 68–78 (2017).
Hambardzumyan, D., Gutmann, D. H. & Kettenmann, H. The role of microglia and macrophages in glioma maintenance and progression. Nat. Neurosci. 19, 20–27 (2016).
Gritsenko, P. G. & Friedl, P. Adaptive adhesion systems mediate glioma cell invasion in complex environments. J. Cell Sci. https://doi.org/10.1242/jcs.216382 (2018).
Gritsenko, P. G. et al. p120-catenin-dependent collective brain infiltration by glioma cell networks. Nat. Cell Biol. 22, 97–107 (2020).
Peglion, F., Llense, F. & Etienne-Manneville, S. Adherens junction treadmilling during collective migration. Nat. Cell Biol. 16, 639–651 (2014).
Lim, D. A. & Alvarez-Buylla, A. The adult ventricular-subventricular zone (V-SVZ) and olfactory bulb (OB) neurogenesis. Cold Spring Harb. Perspect. Biol. https://doi.org/10.1101/cshperspect.a018820 (2016).
Waclaw, B. et al. A spatial model predicts that dispersal and cell turnover limit intratumour heterogeneity. Nature 525, 261–264 (2015).
Kamran, N. et al. Current state and future prospects of immunotherapy for glioma. Immunotherapy 10, 317–339 (2018).
Shelhamer, E., Long, J. & Darrell, T. Fully convolutional networks for semantic segmentation. IEEE Trans. Pattern Anal. Mach. Intell. 39, 640–651 (2017).
Sharma, M., Pachori, R. & Acharya, U. R. Adam: a method for stochastic optimization. Pattern Recognit. Lett. 94, 172–179 (2017).
Hollon, T. C. et al. Near real-time intraoperative brain tumor diagnosis using stimulated Raman histology and deep neural networks. Nat. Med. 26, 52–58 (2020).
Ronneberger, O., Fischer, P. & Brox, T. U-Net: Convolutional Networks for Biomedical Image Segmentation. Medical Image Computing and Computer-Assisted Intervention (MICCAI), Springer, LNCS, Vol. 9351 234–241, 2015.
Abadi, M. et al. TensorFlow: a system for Large-Scale machine learning. In 12th USENIX symposium on operating systems design and implementation (OSDI 16) 265–283 (2016).
Wilson, T. J., Zamler, D. B., Doherty, R., Castro, M. G. & Lowenstein, P. R. Reversibility of glioma stem cells’ phenotypes explains their complex in vitro and in vivo behavior: Discovery of a novel neurosphere-specific enzyme, cGMP-dependent protein kinase 1, using the genomic landscape of human glioma stem cells as a discovery tool. Oncotarget 7, 63020–63041 (2016).
Yadav, V. N. et al. CXCR4 increases in vivo glioma perivascular invasion, and reduces radiation induced apoptosis: A genetic knockdown study. Oncotarget 7, 83701–83719 (2016).
Comba, A. et al. Laser Capture Microdissection of Glioma Subregions for Spatial and Molecular Characterization of Intratumoral Heterogeneity, Oncostreams, and Invasion. J Vis Exp. https://doi.org/10.3791/60939 (2020).
Draghici, S. et al. A systems biology approach for pathway level analysis. Genome Res. 17, 1537–1545 (2007).
Huber, D. et al. Multiple dynamic representations in the motor cortex during sensorimotor learning. Nature 484, 473–478 (2012).
Chen, Z., Ross, J. L. & Hambardzumyan, D. Intravital 2-photon imaging reveals distinct morphology and infiltrative properties of glioblastoma-associated macrophages. Proc. Natl Acad. Sci. USA 116, 14254–14259 (2019).
Tinevez, J. Y. et al. TrackMate: An open and extensible platform for single-particle tracking. Methods 115, 80–90 (2017).
Burnham, K. P. & Anderson, D. R. Model Selection and Multimodel Inference: A Practical Information-Theoretic Approach 2 edn (Springer, 2002).
Acknowledgements
We thank all members of our laboratory, and E.D.Lowenstein, for advice and comments on this work. This work was supported by National Institutes of Health, National Institute of Neurological Disorders and Stroke (NIH/NINDS) grants: R37-NS094804, R01-NS105556, R21-NS107894, R21-NS091555; R01-NS074387 to M.G.C.; National Institute of Neurological Disorders and Stroke (NIH/NINDS) grants: R01-NS076991, R01-NS096756, R01-NS082311, R01-NS122234, R01-NS127378 to P.R.L.; National Institute of Biomedical Imaging and Bioengineering (NIH/NIBI): R01-EB022563; National Cancer Institute (NIH/NCI) U01CA224160; Rogel Cancer Center at The University of Michigan G023089 to M.G.C. Ian’s Friends Foundation grant G024230, Leah’s Happy Hearts Foundation grant G013908, Pediatric Brain Tumor Foundation grant G023387 and ChadTough Foundation grant G023419 to P.R.L. RNA Biomedicine grant: F046166 to M.G.C. National Cancer Institute (NIH/NCI) grants: R01 CA125577 and R01 CA107469 to CGK. Health and Human Services, National Institutes of Health, UL1 TR002240 to Michigan Institute for Clinical and Health Research (MICHR), Postdoctoral Translational Scholars Program (PTSP), Project F049768 to A.C.
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Conception and design: A.C., M.G.C., and P.R.L. Development of methodology: A.C., M.S.F., P.J.D., A.E.A., T.H., W.N.A.-H., M.L.V., D.B.Z., S.M., and P.R.L. Acquisition of data, analysis, and interpretation: A.C., M.S.F., P.J.D., A.E.A., T.H., M.L.V., D.B.Z., C.A. II, M.G.C., S.M., and P.R.L. Human histopathology analysis and identification of oncostreams: A.C., C.K., A.E.A., and P.R.L. Laser microdissection protocol: A.C., P.R.L., P.E.K., A.K. Development and establishment of intravital imaging using multiphoton microscopy: A.C., M.S.F., P.R.L., G.L.Q., and P.F.A. Development and experimental assistance with human glioma cell lines: C.E.B. Manuscript writing: A.C., S.M., P.R.L. Administrative, technical, or material support (i.e., reporting or organizing data, constructing databases): A.C. and P.R.L. Study supervision: M.G.C. and P.R.L. All authors reviewed the final version of the manuscript.
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Comba, A., Faisal, S.M., Dunn, P.J. et al. Spatiotemporal analysis of glioma heterogeneity reveals COL1A1 as an actionable target to disrupt tumor progression. Nat Commun 13, 3606 (2022). https://doi.org/10.1038/s41467-022-31340-1
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DOI: https://doi.org/10.1038/s41467-022-31340-1
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