Abstract
While changes in nuclear structure and organization are frequently observed in cancer cells, relatively little is known about how nuclear architecture impacts cancer progression and pathology. To begin to address this question, we studied Nuclear Transport Factor 2 (NTF2) because its levels decrease during melanoma progression. We show that increasing NTF2 expression in WM983B metastatic melanoma cells reduces cell proliferation and motility while increasing apoptosis. We also demonstrate that increasing NTF2 expression in these cells significantly inhibits metastasis and prolongs survival of mice. NTF2 levels affect the expression and nuclear positioning of a number of genes associated with cell proliferation and migration, and increasing NTF2 expression leads to changes in nuclear size, nuclear lamin A levels, and chromatin organization. Thus, ectopic expression of NTF2 in WM983B metastatic melanoma abrogates phenotypes associated with advanced stage cancer both in vitro and in vivo, concomitantly altering nuclear and chromatin structure and generating a gene expression profile with characteristics of primary melanoma. We propose that NTF2 is a melanoma tumor suppressor and could be a novel therapeutic target to improve health outcomes of melanoma patients.
Similar content being viewed by others
Introduction
Cancer cells exhibit many characteristics that distinguish them from normal cells, including higher proliferation rates, immortalization, suppressed apoptosis, and metastasis1. In addition to these functional differences, cancer cells are also morphologically distinct, with irregularly shaped cells, increased nuclear-to-cytoplasmic ratios, prominent nucleoli, and larger nuclei. Pathologists have long used altered nuclear morphology to distinguish cancer cells from normal cells, and late stage tumors often exhibit more aberrant nuclear structures compared to earlier stages2,3,4,5. Nuclear size has diagnostic and prognostic value in melanoma6,7,8, one of the most prevalent cancers with cases of cutaneous melanoma growing at the fastest rate of all cancers among Caucasians9. However, how altered nuclear architecture contributes to progression and pathology of a broad range of cancers, including melanoma, is unknown. The six major steps of melanoma progression are: common acquired nevus without cytogenetic abnormalities, melanocytic nevus with aberrant differentiation, dysplastic nevus, radial growth phase (RGP) primary melanoma, vertical growth phase (VGP) primary melanoma, and metastatic melanoma10. In VGP melanoma some local dermal cell invasions are possible, while cell dissemination over longer distances is a defining characteristic of metastatic melanoma11.
We previously reported that RGP primary melanoma cells exhibit larger nuclei compared to normal melanocytes. Based on data from 4 patient-derived cell lines and 24 biopsies, we also found that as nuclear size increases during melanoma progression, the levels of Nuclear Transport Factor 2 (NTF2) decrease12. This led us to hypothesize that reductions in NTF2 expression might promote melanoma progression to more advanced stages of disease, motivating our current study to test if ectopic NTF2 expression in metastatic melanoma could abrogate certain cancer cell phenotypes.
How might NTF2 influence cell and nuclear function? NTF2 plays a critical role in nucleocytoplasmic transport by recycling RanGDP from the cytoplasm to the nucleus where GDP is exchanged for GTP by chromatin-bound RCC113,14,15,16. In addition, NTF2 is associated with the nuclear pore complex (NPC)13,14,17,18, where higher NTF2 amounts reduce the NPC diameter12,19,20. In turn, a smaller NPC pore size correlates with reduced nuclear import of large cargo molecules19. Conversely, import of large cargos increases when NTF2 is inhibited or depleted21. Large cargos relevant to nuclear size are nuclear lamins, intermediate filament proteins that line the inner nuclear membrane and regulate chromatin organization22,23. Though relatively small proteins, lamins are highly oligomeric and/or adopt extended conformations based on biophysical and structural studies, explaining why lamins appear to be imported as large cargos24,25,26. Increasing NTF2 levels in mammalian cell lines and Xenopus is sufficient to reduce lamin import and nuclear size12,21.
In this study, we investigated if increasing NTF2 expression can impact the pathogenesis of metastatic melanoma. To address this question, we utilized a pair of melanoma cell lines isolated from the same patient that are unique because they correspond to two different consecutive stages of disease: VGP primary melanoma (WM983A) and metastatic melanoma (WM983B). We largely focused our studies on these two cell lines because of their similar genetic backgrounds. We generated a stably transfected version of the metastatic melanoma cell line in which we could titrate the NTF2 expression level. Our data demonstrate that increasing the level of NTF2 expression reduces cell motility and cell proliferation while increasing apoptosis. In mice injected with these melanoma cells, increasing NTF2 levels reduces lung metastases and prolongs survival. Furthermore, RNA sequencing of cells expressing different levels of NTF2 revealed differentially expressed genes involved in cell migration and cell survival. We demonstrate NTF2-dependent changes in gene positioning, chromatin organization, nuclear size, and nuclear lamin A levels. Lastly, we show that VGP primary melanoma cells express higher NTF2 levels relative to metastatic melanoma and that increasing NTF2 expression in metastatic melanoma recapitulates some cellular phenotypes and gene expression patterns characteristic of VGP primary melanoma. These results highlight NTF2 as a potential novel therapeutic target to treat metastatic melanoma.
Results
Increased NTF2 expression reduces cell proliferation and increases apoptosis
We previously published that expression of the nuclear transport protein NTF2 inversely correlates with nuclear size during melanoma progression12. A critical unanswered question is if changes in nuclear architecture and nucleocytoplasmic transport have any relevance to cancer progression and disease severity. Therefore, we developed stably transfected metastatic melanoma WM983B cells that allow for titratable expression of NTF2 dependent on doxycycline dosage. From a range of doxycycline concentrations tested, we selected for further study the concentration that maximally reduced nuclear size without showing any cytotoxic effects. With 20 ng/ml doxycycline added to the growth media, on average 7.8-fold higher NTF2 protein expression was observed compared to the parental cell line (Fig. 1A), well within the physiological range of NTF2 protein expression variation reported in numerous cultured cell lines27. Interestingly, stably transfected cells not treated with doxycycline expressed ~ fourfold higher and more variable NTF2 protein levels compared to the parental cell line, an indication of promoter leakiness that has been reported by others28. For the sake of simplicity, we will refer to the parental cell line WM983B as “NTF2 low”, stably transfected WM983B without doxycycline as “NTF2 high dox-”, and stably transfected WM983B with 20 ng/ml doxycycline as “NTF2 high dox +” (Fig. 1A). To confirm promoter leakiness, we transiently transfected NTF2 high dox- cells with a commercially available pTet-tTS plasmid to suppress the leakiness, which reduced the NTF2 level to that of the parental cell line (Fig. S1A). In our subsequent studies with these cells, we noted the greatest experimental variability with the NTF2 high dox- cells, likely due to differences in the proportion of cells exhibiting leaky NTF2 expression. It is worth noting that we also performed complementary NTF2 knockdown experiments in both normal melanocytes (AG21857) and metastatic melanoma (WM983B). However, NTF2 knockdown led to cell inviability that could not be rescued by expressing NTF2 point mutants defective for either Ran or NPC binding, similar to what we previously reported in HeLa cells12.
We examined how increased NTF2 expression in metastatic melanoma affected various cancer cell characteristics. We first measured cell proliferation rates. Cells were plated at a constant density and then counted 24, 48, and 72 h later. There were 44% fewer NTF2 high dox + cells at 72 h compared to NTF2 low cells (Fig. 1B). Cell proliferation was not affected by mCherry overexpression, indicating that ectopic expression of a generic protein does not reduce proliferation of the metastatic melanoma cells (Fig. S2A). We next quantified the fraction of apoptotic cells by staining for activated caspase-3/7. Compared to NTF2 low cells, the apoptosis frequency was fivefold higher in NTF2 high dox + cells (Fig. 1C). While there was a modest increase in the apoptosis frequency from 1% to 5.5%, there was no evidence that NTF2 overexpression caused general cell toxicity. To test if NTF2 has a similar effect in a different type of cancer, we increased NTF2 expression in LNCaP cells that were derived from a human prostate cancer metastasis. Consistent with the melanoma results, ectopic NTF2 expression reduced cell proliferation in cultured metastatic prostate cancer cells (Fig. S1B-D). These data show that increasing NTF2 levels leads to decreased cell proliferation and increased apoptosis.
Increased NTF2 levels reduce melanoma cell motility
Acquisition of metastatic potential by melanoma cells is the critical change that leads to patient death29. To initially test if NTF2 expression impacts metastasis, we performed in vitro would healing cell migration assays. We created small scratches in confluent monolayers of NTF2 low, NTF2 high dox-, and NTF2 high dox + melanoma cells and observed cell behavior by time-lapse microscopy. The NTF2 low cell line was highly motile, completely filling the scratch after only 3 h (Fig. 2A). During that same 3-h time period, the NTF2 high dox- and NTF2 high dox + cells only covered 43% and 11% of the scratch area, respectively. We repeated these experiments with a larger scratch area and increased the observation time (Fig. 2B and Videos 1–2). The same trend was observed with the NTF2 low, NTF2 high dox-, and NTF2 high dox + cells filling 70%, 38%, and 21% of the scratch area, respectively, after 10 h (Fig. 2C). These data reveal an inverse correlation between NTF2 expression levels and cell migration potential, and this effect is specific to NTF2 as ectopic mCherry expression did not affect the rate at which metastatic melanoma cells filled the scratch (Fig. S2B). In these experiments we did not inhibit cell division because even low concentrations of drugs that affect microtubules can impact cell migration30. Because filling of the scratch in our wound healing assays might be affected by cell proliferation, we also examined migration of non-dividing individual cells on the edge of the scratch (Fig. 2D). The NTF2 low cell trajectories were the longest with the NTF2 high dox- and NTF2 high dox + cells exhibiting progressively reduced cell movements (Fig. 2E). Expression of mCherry did not affect the distance traveled by metastatic melanoma cells (Fig. S2C), again indicating that general protein overexpression does not impact cell migration. These data show that titrated increases in NTF2 levels concomitantly decrease cell motility.
Increased NTF2 levels reduce melanoma metastasis in vivo
We next examined if NTF2 expression levels affect melanoma metastatic potential in vivo. For these experiments, 6–8 week old Rag2−/− γc−/− knockout mice (i.e. deficient for B, T, and innate lymphoid cells) were intravenously injected with NTF2 low or NTF2 high cells. The latter group was divided into two cohorts, in which one was provided with doxycycline-containing food from the first day of injection and labeled as NTF2 high dox +. The group not treated with doxycycline was labeled NTF2 high dox-. Four months post-injection, the mice were sacrificed and lungs were examined for tumors. In the NTF2 low and NTF2 high dox- mice, tumors were always found on the lungs (Fig. 3A,B). The number of metastases and tumor sizes varied among individuals, and in some extreme cases large tumors covered most of the lungs. The NTF2 high dox + mice generally developed fewer and smaller tumors that covered less lung area (Fig. 3A,C). Tissue staining with Melan A and S100 confirmed that the tumors were human melanoma-derived (Fig. S3A-B). We also quantified statistically significant differences in lung weights between NTF2 low and NTF2 high dox + mice (Fig. 3D). We examined the brain, liver, and spinal cord for metastases but only infrequently observed small liver and spinal cord metastases in mice injected with NTF2 low cells (Fig. S3C). We only regularly observed lung metastases, justifying our focus on the lung and consistent with clinical studies showing the lung as the primary metastasis site for melanoma31,32.
We performed separate survival experiments with Rag2−/− γc−/− knockout mice intravenously injected with NTF2 high cells and fed doxycycline-containing food or normal food. The NTF2 high dox + mice showed better survival than the NTF2 high dox- mice, living 12 days longer based on median survival times (Fig. 3E). In parallel, we observed that mice injected with NTF2 low cells (dox-/ +) died two weeks earlier than NTF2 high dox + mice. This is roughly equivalent to extending human survival time by well over a year, and perhaps much longer, so the impact of NTF2 on the survival rate of melanoma patients is potentially quite high33. Together these data show that higher NTF2 levels can reduce melanoma metastasis and prolong overall survival of animals with metastatic melanoma. These results are consistent with human survival data where high NTF2 levels in melanoma correlate with a greater overall survival probability for the first two years, although the trend reverses at later times when other factors may more dominantly influence pathology and disease progression (Fig. S3D). Perhaps increasing NTF2 expression in early metastatic melanoma could represent a viable therapeutic approach.
Identification of differentially expressed genes in cells expressing different levels of NTF2
We next addressed how increasing NTF2 levels affects gene expression by performing triplicate whole transcriptome sequencing of the NTF2 low and NTF2 high dox + cell lines. Transcriptomes were compared to identify differentially expressed genes (DEGs) between these two cell groups. In all of our RNAseq experiments, cells were grown to 90% confluency and were contact-inhibited to minimize concerns that DEGs might be related to differences in cell cycle distributions. For the DEG analysis, Wald tests were performed to generate fold-changes in gene expression levels and associated p-values. While one of the NTF2 low samples showed an expression profile quite different from the other two samples, the replicates generally correlated within a given cell group (Fig. 4A). This was further confirmed by two-dimensional principal component analysis (PCA) where the NTF2 low and NTF2 high dox + samples fell into two distinct groups (Fig. 4B). Among replicates, the NTF2 high dox + samples showed less variability than the NTF2 low samples.
We identified 479 genes that were differentially expressed between the NTF2 low and NTF2 high dox + cell lines. Increased NTF2 expression led to the downregulation of 322 genes and upregulation of 157 genes (Table S1). Among those genes downregulated in NTF2 high dox + , many are associated with tumor promoting characteristics, including cell proliferation (RAMP1, B3GNT3), cell migration (LAMA5, PRKX, KIT), and angiogenesis (PRKX)34,35,36 (Fig. 4C). The KIT gene plays an important role in melanocyte development and migration and its expression is elevated in advanced melanomas, but downregulated in the NTF2 high dox + cells. Genes upregulated in NTF2 high dox + are involved in suppressing tumor growth and invasion (ADAMTS15, ANK3, CERS6) and prolonging patient survival (TP63, BMP5)37,38,39. For example, while low levels of CERS6 in melanoma are associated with increased cell proliferation and invasion40, CERS6 is upregulated in NTF2 high dox + . In another example, high levels of ANK3 suppress tumor cell invasion41. To test the functional significance of a subset of these DEGs, we performed gene knockdowns. Reducing KIT expression in NTF2 low cells decreased cell migration, while ANK3 knockdown in NTF2 high dox + cells increased cell migration (Fig. 4D,E).
To obtain a global view of the biological processes and gene families impacted by NTF2 expression levels, we performed gene ontology (GO) enrichment analysis for DEGs (Fig. 4F). Genes upregulated in NTF2 high dox + are involved in the regulation of programmed cell death (35 genes), positive regulation of cell differentiation (27 genes), and cell surface receptor signaling pathways (51 genes). GO analysis of genes downregulated in NTF2 high dox + are enriched for cell motility (43 genes), cell migration (42 genes), and extracellular matrix organization (19 genes). GO cellular components analysis showed that genes upregulated in NTF2 high dox + produce primarily nuclear proteins (e.g. components of nucleosomes, Cajal bodies, chromosomes, and chromatin), while downregulated gene-products are predominantly related to extracellular functions (e.g. components of the extracellular matrix, exocytic vesicles, and plasma membrane).
We also compared the NTF2 low transcriptome to that of NTF2 high dox-. While the PCA analysis showed two distinct groups, we noted that the replicates were more tightly clustered with higher NTF2 expression (Fig. S4). Comparing this PCA (Fig. S4B) to the PCA for NTF2 low versus NTF2 high dox + (Fig. 4B), we can conclude that replicate variability is reduced as NTF2 expression levels increase. These data are consistent with the idea that NTF2 expression can partially suppress the highly variable gene expression patterns characteristic of cancer cells42. Given their “leaky” NTF2 expression, NTF2 high dox- cells show a gene expression pattern more similar to that of NTF2 high dox + than to the NTF2 low parental cell line. We constructed Venn diagrams to identify similarities in gene expression profiles among these cell lines. About two-thirds of the same genes are differentially expressed when NTF2 high dox- and NTF2 high dox + are compared to NTF2 low. We also directly compared the transcriptomes of the NTF2 high dox- and NTF2 high dox + cell lines (Table S2), using a p-value cutoff < 0.05 because few genes passed the FDR < 0.05 test. 63 genes were upregulated and 260 genes were downregulated in NTF2 high dox + compared to NTF2 high dox-. Many of these genes correspond to long non-coding RNAs, some having been implicated in cell proliferation and oncogenesis (e.g. MIR155HG and SOX2-OT)43,44. Many of the differentially expressed protein-coding genes play roles in carcinogenesis (e.g. GAGE12J, VWA2, NUAK1, and MGAT4C), consistent with the transcriptional differences we identified between the NTF2 low and NTF2 high dox + cell lines45,46,47,48.
NTF2 levels affect lamin A nuclear localization, nuclear size, heterochromatin distribution, and gene positioning
Because NTF2 associates with the NPC and can limit nuclear import of large cargo molecules like nuclear lamins, we next examined lamin A in our melanoma cell lines. Based on immunofluorescence, the total amount of nuclear lamin A was reduced in NTF2 high dox + cells compared to NTF2 low cells (Fig. 5A). Because total lamin A levels were not significantly altered by NTF2 expression (Fig. S5), the observation that NTF2 reduced the amount of lamin A within the nucleus is consistent with increased NTF2 at the NPC inhibiting lamin import, although lamin A import rates were not explicitly measured. The amount of lamin A localized to the nuclear envelope was also reduced in NTF2 high dox + cells without affecting the relative distribution of lamin A between the nuclear lamina and nucleoplasm (Fig. 5A and Fig. S3E). Furthermore, nuclear size and lamin A nuclear localization were greater in NTF2 low cells relative to cells with higher NTF2 expression (Fig. 5A,B), consistent with previous reports in Xenopus and mammalian cells12,21,23. We also found that ectopic NTF2 expression reduced nuclear size in LNCaP metastatic prostate cancer cells and altered colony morphology (Fig. S1E-F).
Adjacent to the inner nuclear membrane, the nuclear lamina contacts peripheral chromatin through lamina-associated domains that generally repress gene expression, and lamin levels and localization may regulate chromatin organization and gene expression49,50. Furthermore, our Gene Set Enrichment Analysis identified chromatin/gene silencing and nucleosome assembly pathways as being upregulated in NTF2 high dox + cells, consistent with the large number of downregulated genes in these cells. For these reasons, we examined the heterochromatin distribution in our cell lines. While H3K9me3 heterochromatin was fairly evenly distributed throughout the nucleus in NTF2 low and VGP primary melanoma cells, we observed a striking increase in the H3K9me3 signal at the nuclear envelope in NTF2 high dox + cells (Fig. 5C).
Given that NTF2 levels affect heterochromatin distribution and gene expression, we wanted to determine if the intranuclear positioning of DEGs might differ in our cell lines. To visualize gene positions, we performed DNA fluorescence in situ hybridization (FISH) on the following genes: KIT, PADI2, and RAMP1. KIT is often overexpressed in melanoma, where it activates several signaling pathways and increases cell proliferation and metastasis51,52. Our transcriptomics data showed that KIT gene expression is low in VGP primary melanoma and NTF2 high dox + cells but highly expressed in NTF2 low cells. Based on FISH, we found that the KIT gene is generally close to the nuclear periphery in NTF2 low cells, as opposed to its more central nuclear location in NTF2 high dox + cells and VGP primary melanoma cells (Fig. 6A). While genes localized to the nuclear periphery are generally silenced, some genes actually become activated upon moving to the periphery53, and the KIT gene appears to be another such example. In NTF2 low cells, the PADI2 gene is centrally located within the nucleus and its expression level is high, while in NTF2 high dox + cells PADI2 re-localizes to the nuclear envelope and is downregulated (Fig. 6B). To determine if lamin A levels affect gene positioning in our cells, we transiently overexpressed lamin A in NTF2 high dox + cells and performed FISH for the RAMP1 gene. We found that ectopic lamin A expression caused RAMP1 to re-localize from the nuclear periphery more toward the center of the nucleus (Fig. 6C). Taken together, we observed a correlation between the expression level and nuclear positioning of several genes.
Increasing NTF2 expression in metastatic melanoma produces cells with primary melanoma-like characteristics
Since increasing NTF2 expression in metastatic melanoma reduced nuclear size, altered gene positioning and expression, decreased cell motility and proliferation, and increased apoptosis, we conclude that certain cancer cell phenotypes can be abrogated by ectopic NTF2 expression. For this reason, we hypothesized that NTF2 high dox + cells might be more similar to VGP primary melanoma cells (WM983A). NTF2 levels are 1.9 ± 0.8 (average ± SD) fold higher in the VGP primary melanoma cells compared to NTF2 low metastatic melanoma cells, consistent with our previously published work showing an inverse correlation between NTF2 expression levels and cancer progression12. As predicted by these differences in NTF2 expression levels, VGP primary melanoma nuclei are smaller than nuclei in NTF2 low cells and similar in size to NTF2 high dox + nuclei (Fig. 5B).
We compared the transcriptomes of triplicate samples of VGP primary melanoma, NTF2 low, and NTF2 high dox +. 43% of the genes upregulated in NTF2 high dox + cells were also upregulated in VGP primary melanoma when compared to the metastatic parental cell line NTF2 low (Table S3). Similar pathways associated with DEGs were identified when comparing NTF2 low to both VGP primary melanoma and NTF2 high dox + (Figs. 7A and 4F). For instance, pathways regulating cell migration were increased in NTF2 low cells and decreased in NTF2 high dox + and VGP cells. Furthermore, Reactome pathway analysis implicated extracellular matrix degradation, collagen degradation, and laminin interaction pathways more strongly in NTF2 low cells than in VGP primary melanoma or NTF2 high dox + (Fig. 7B), processes that support higher cell motility in NTF2 low cells. More than half of the genes differentially expressed between NTF2 low and NTF2 high dox + were also differentially expressed comparing NTF2 low to VGP primary melanoma (Fig. 7C and Table S4). These data suggest that higher NTF2 levels in the NTF2 high dox + and VGP primary melanoma cells impact a similar subset of cancer-driving genes, including genes regulating cell motility. Consistent with this idea, we noted that KIT gene localization was similar in NTF2 high dox + cells and VGP primary melanoma cells (Fig. 6A). Lastly, cell migration assays showed that VGP primary melanoma cells migrate slower than NTF2 low cells and more similarly to NTF2 high dox + cells (Figs. 7D and 2E). Taken together, these data suggest that increasing NTF2 expression levels in metastatic melanoma can partially revert the cellular characteristics of metastatic cancer to an earlier stage of disease.
Discussion
In this study we present new cellular roles for NTF2 that are relevant to cancer progression. While NTF2 was previously known to function in nucleocytoplasmic transport, Ran recycling, and nuclear size regulation, we now show that NTF2 levels influence a number of cancer cell phenotypes in melanoma. During melanoma progression, there is a general reduction in NTF2 levels12. Increasing NTF2 expression in metastatic melanoma slowed cell motility to that observed in primary melanoma, reduced metastatic potential and cell proliferation, and increased apoptosis. Furthermore, our transcriptomics analysis revealed similarities in the gene expression profiles of metastatic melanoma cells expressing higher NTF2 levels and VGP primary melanoma cells. These data suggest that increasing NTF2 expression is sufficient to at least partially revert metastatic melanoma cells to a more primary melanoma character, supporting the idea that NTF2 is a melanoma tumor suppressor and potential new therapeutic target to treat metastatic melanoma.
Open questions remain about the mechanisms that account for reductions in NTF2 levels during progression from normal melanocytes to VGP primary melanoma to metastatic melanoma. There may be changes in the transcriptional program that regulates NTF2 expression and/or acquisition of NTF2-destabilizing mutations. Consistent with this idea, TCGA (https://www.cancer.gov/tcga) shows that NTF2 is mutated in a wide array of different cancers. Another possibility is that the tumor microenvironment plays a role in epigenetically altering NTF2 expression during cancer progression54,55,56,57,58. Our study also raises questions about additional factors that regulate nuclear architecture and their role in, not only melanoma, but also other cancers.
How might NTF2 levels influence the various cancer cell characteristics examined in this study? It is now well established that chromosomes occupy specific positions within the nucleus, so-called chromosome territories, that in turn influence gene expression59,60. One possibility is that NTF2-induced changes in nuclear size cause chromosomes and genes to re-position. It is also known that specific chromosomal regions interact with the nuclear lamina, forming lamina-associated domains (LADs) that generally correspond to heterochromatic silenced regions of the genome49. Because NTF2 levels influence the amount of lamin A at the NE, another model is that LADs are altered when NTF2 expression is manipulated. In either case, the prediction is that NTF2 levels influence gene positioning and expression, both results borne out in our DNA FISH, heterochromatin localization, and transcriptomics data. Of note, increasing NTF2 expression upregulated pathways involved in gene silencing, nucleosome assembly and organization, and negative epigenetic gene regulation. Thus, we propose that increasing NTF2 expression in metastatic melanoma reduces lamin A import and nuclear size, concomitantly altering gene positioning and expression and reducing cell proliferation, migration, and metastasis.
Interestingly, another nuclear transport and sizing factor, importin α, has already been suggested for use as a cancer biomarker. Higher importin α expression correlates with poor survival rates in breast cancer61, and importin α knockdown in non-small cell lung carcinoma suppressed cell proliferation and migration62,63. Similarly, it has been shown that changes in importin α levels have prognostic value in many different cancers, including lung, prostate, brain, and liver cancer62,64,65,66. Consistent with these observations, we found that ectopic importin α overexpression in NTF2 high dox + cells resulted in larger nuclei and higher rates of cell proliferation (data not shown).
Increasing NTF2 levels in metastatic melanoma upregulated expression of a number of genes known to be associated with better survival rates in patients. ANK3, a negative regulator of cell invasion, was one of the most highly expressed genes in NTF2 high dox + cells and VGP melanoma. ANK3, TP63, and ADAMTS15 were each highly upregulated in NTF2 high dox + cells and are associated with improved patient survival in certain cancers37,41,67,68. Another highly expressed gene in NTF2 high dox + cells was BMP5, a gene whose downregulation in breast cancer is associated with disease recurrence39. Thus, NTF2 overexpression generates a gene expression profile associated with improved prognosis in many cancers, consistent with our mouse studies showing that increasing NTF2 levels in metastatic melanoma cells reduces lung metastases and increases survival.
Might increasing NTF2 expression represent a novel approach to cancer treatment? In cultured metastatic prostate cancer cells, increasing NTF2 expression reduced cell proliferation and nuclear size. With regard to melanoma, most currently available drugs inhibit BRAF and MAPK signaling69,70. Despite some of these drugs being temporarily effective against melanoma, most patients develop drug resistance over time. For example, roughly half of melanoma patients treated with Dabrafenib or Trametinib develop resistance within 6–7 months after starting therapy71. One factor known to contribute to resistance is increased expression of the growth factor binding protein IGFBP272. Highly expressed in our NTF2 low metastatic melanoma cells, IGFBP2 was downregulated upon NTF2 overexpression, suggesting these cells might show an improved drug response. Given that combination therapy often leads to better outcomes, we propose the exploration of approaches to increase NTF2 expression in cancer, approaches that may improve patient survival especially when combined with currently available drug treatments.
Methods
Cell lines
The human melanocyte cell line (AG21857) was obtained from the NIA Cell Culture Repository through the Coriell Institute (only used in Fig. 5B). Melanoma cell lines (WM983A and WM983B) were obtained from the Wistar repository through the Coriell Institute. These melanoma cell lines were isolated from the same patient and correspond to VGP primary melanoma (WM983A) and metastatic melanoma (WM983B). The WM983B metastatic melanoma cell line is the main cell line used throughout this study and corresponds to NTF2 low, NTF2 high dox-, and NTF2 high dox +. Anywhere that we refer to VGP primary melanoma we are using the WM983A cell line. The human metastatic prostate cancer cell line (LNCaP) was obtained from Jay Gatlin (University of Wyoming). AG21857 cells were maintained in Medium 254 (#M254500, Invitrogen) supplemented with HMGS (#S0025, Invitrogen). WM983A and WM983B cells were maintained in 4:1 MCDB153 (#M7403, Sigma-Aldrich) and Leibovitz L-15 (#L4386, Sigma-Aldrich), supplemented with 5 µg/ml insulin (#I9278, Sigma-Aldrich), 2% FBS, 1.68 mM CaCl2, and 50 IU/ml penicillin and streptomycin. LNCaP cells were maintained in RPMI-1640 (Sigma) supplemented with 7.5% FBS and 50 IU/ml penicillin and streptomycin. Tet-free FBS was used for experiments where NTF2 expression was induced with doxycycline. All cells were grown at 37 °C and 5% CO2.
Plasmids
Plasmid pDL23 was described previously and consists of human NTF2 cloned into pEmCherry-C2 (a derivative of pEGFP-C2, a gift from Anne Schlaitz)12. The mCherry-NTF2 fragment was excised from pDL23 at AgeI/BclII and cloned into pTetOne (#634303 Clontech, Takara) at AgeI/BamHI to generate pTetOne mCherry-NTF2 (pDL65). Plasmid pDL65 was digested with EcoRI to remove mCherry and recircularized to generate pTetOne NTF2 (pDL66). Plasmid pTet-tTs was from Clontech (#631011). A plasmid consisting of human lamin A cloned into pcDNA3.1(+) was described previously (pDL80)23. Human importin α (hSRP1α) was cloned from pKW230 (a gift from Karsten Weis) into pEmCherry-C2 at EcoRI/KpnI to generate pEmCherry-C2 importin α (pDL21).
NTF2-inducible melanoma cells
WM983B cells were seeded into 6-well plates and transfected at 70% confluency using Xfect Transfection Reagent (#631317, Clontech) with 5 μg of pTetOne NTF2 (pDL66) and 100 ng of linear hygromycin marker (#631625, Clontech). After 4 h at 37 °C, the media was replaced. 48 h post transfection, confluent cells were split into 4 × 10 cm dishes. 96 h post transfection, selective antibiotic hygromycin (#631309, Clontech) was added at 200 μg/ml. Antibiotic-resistant colonies appeared after two weeks. Each colony was transferred to a well of a 24-well plate to expand and test for NTF2 expression. To screen for NTF2 induction, clonal cell populations were treated with 1, 5, 10, 20, 50, 100, or 1000 ng/ml of doxycycline (#631311, Clontech), and NTF2 levels were assayed by western blot after 24 and 48 h. For our studies, we acknowledge that there are caveats to comparing the parental NTF2 low cell line (WM983B) to the NTF2-transfected cell line. However, we believe that these comparisons are informative because it allows us to examine three different NTF2 concentrations. Importantly, we observe similar quantitative trends for cellular phenotypes and gene expression across these different NTF2 concentrations, further supporting the idea that NTF2 is responsible for the observed phenotypes and justifying the inclusion of the parental cell line comparisons.
NTF2-overexpressing metastatic prostate cancer cells
LNCaP cells were seeded into 6-well plates and transfected at 70% confluency using Xfect Transfection Reagent (#631317, Clontech) with 5 μg of pEmCherry-C2 NTF2 (pDL23). After 4 h at 37 °C, the media was replaced. 48 h post transfection, confluent cells were split into 4 × 10 cm dishes. 96 h post transfection, selective antibiotic geneticin was added at 500 μg/ml. Antibiotic-resistant colonies appeared after two weeks. Each colony was transferred to a well of a 24-well plate to expand and test for NTF2 expression.
Transient transfections
Cells were grown to 70–80% confluency and transient transfections were performed using Lipofectamine 3000 (Invitrogen, L3000008). In one tube, 2.5 µg of DNA were added to 125 µl of OptiMEM media plus 5 µl of P3000 reagent. In another tube, 5 µl of Lipofectamine 3000 reagent was added to 125 µl of Opti-MEM media. The contents of both tubes were mixed and incubated for 5 min at room temperature. 250 µl of DNA-lipofectamine complex were added to each well of a 6-well plate. The media was changed after 24 h, and cells were fixed and visualized 48 h post-transfection. Transient RNAi transfections were performed using Lipofectamine RNAiMAX (Invitrogen, 13,778,075). Briefly, 3 µl of 10 µM siRNA were diluted in 50 µl of Opti-MEM media, 3 µl of Lipofectamine RNAiMAX reagent were diluted in 50 µl of Opti-MEM media, and the two were mixed and incubated for 5 min at room temperature. The 100 µl transfection mixture was added to 500 µl of culture media and incubated for 48 h. The following RNAi constructs were used: ANK3 (#187683817, IDT), KIT (#187683808, IDT), transfection control TYE 563-labeled DsiRNA (#51-01-20-19, IDT). After transient transfections, cells on coverslips were washed with PBS (without Mg2+ and Ca2+), fixed with 4% paraformaldehyde for 20 min, washed, stained with 5 µg/ml Hoechst for 5 min, washed, mounted in Vectashield (Vector Laboratories), and sealed with nail polish.
Immunofluorescence
Cells grown on glass coverslips or in chamber slides (Thermo Fisher Scientific, #177437PK) were washed twice with PBS, fixed with 4% paraformaldehyde for 20 min at room temperature, and then subjected to three 5-min washes with PBS. Cells were permeabilized for 10 min with 0.5% Triton X-100 in PBS and washed three times with PBS for 5 min each. Blocking was performed for 40 min at room temperature with 5% BSA and 0.05% Tween 20 in PBS, and then incubated overnight at 4 °C with primary antibody diluted in 1% BSA in PBS. Cells were washed three times in PBS plus 0.05% Tween 20 for 5 min each and incubated at room temperature for 1 h with secondary antibodies diluted in 1% BSA in PBS. Cells were then stained with 5 µg/ml Hoechst in PBS for 5 min and washed three times in PBS plus 0.05% Tween 20 for 5 min each. Coverslips were mounted in Vectashield (Vector Laboratories) and sealed with nail polish. Primary antibodies included: H3K9me3 monoclonal mouse antibody (Abgent, ADN10307) used at 1:200 and lamin A/C monoclonal mouse antibody (Santa Cruz Biotechnology, sc-376248) used at 1:1000. Secondary antibodies included: Alexa Fluor 488 and Alexa Fluor 568 conjugated goat anti-mouse IgG (Thermo Fisher Scientific, A-11001 and A-11004) used at 1:500.
Western blots
Whole cell lysates were prepared using SDS-PAGE sample buffer supplemented with benzonase nuclease (Sigma, E1014) and boiled for 5 min. Proteins were separated on SDS-PAGE gels (4–20% gradient) and transferred to PVDF membrane. Membranes were blocked in Odyssey PBS Blocking Buffer (Li-Cor, 927–40,000). The primary antibodies used were mouse anti-NTF2 at 1:500 (Sigma, N9527), rabbit anti-NTF2 at 1:200 (Aviva System Biology, ARP64840_P050), mouse anti-lamin A/C at 1:500 (Santa Cruz Biotech sc-376248), rabbit anti-lamin B1 at 1:2000 (Abcam 16,048), and mouse anti-actin at 1:200 (Abgent, AM1965b). The secondary antibodies were IRDye 680RD anti-mouse used at 1:20,000 (Li-Cor 925-68070) and IRDye 800CW anti-rabbit used at 1:20,000 (Li-Cor 925-32211). Blots were scanned on a Li-Cor Odyssey CLx instrument and band quantification was performed with ImageStudio. For a given sample, NTF2 band intensity was normalized to the actin signal, and lamin band intensity was normalized to Ponceau-stained total protein. For western blots on LNCaP cell lysates, HRP detection was used as previously described73.
Animal study
All mouse (Mus musculus) procedures and studies were conducted in compliance with the US Department of Health and Human Services Guide for the Care and Use of Laboratory Animals. Protocols were approved by the University of Wyoming Institutional Animal Care and Use Committee (DHHS/NIH/OLAW Assurance D16-00135, #A-3216-01). This study was carried out in compliance with the ARRIVE guidelines. Mice were housed in specialized microisolator cages under specific pathogen-free conditions at the University of Wyoming Animal Facility. Mice were maintained in 12 h light/dark cycles. 6–8 week old female Rag2−/− γc−/− knockout mice in the B6 background (#4111, Taconic Biosciences, Inc.) were used for metastasis assays. 8–10 week old female Rag2−/− γc−/− mice in the BALB/c background (#014593, Jackson Laboratory) were used for survival assays. Mice were fed autoclavable Teklad Global 18% Protein Rodent Diet (#2018S, Envigo). For NTF2 induction, doxycycline hyclate (200 mg/kg) was added to the base diet (En#TD.00502, Envigo). Metastasis and survival assays were performed after intravenous injection of 2.5 × 105 NTF2 low or NTF2 high dox- melanoma cells in 100 µl physiological sterile PBS with 10% OptiMem. For metastasis assays, mice were sacrificed around 4 months after injections to examine metastasis formation. For survival assays, mice were inspected daily until death, assessing mouse weight and behavior74.
Mouse tissue collection
Mice were euthanized with isoflurane followed by cervical dislocation. Organs were manually dissected, washed in PBS, fixed overnight in 10% neutral buffered formalin (HT501128, Sigma-Aldrich), and preserved in 70% ethanol. For histology, tissue was embedded in paraffin and 5 mm sections were cut using a microtome. Hematoxylin and eosin (H&E) tissue staining was performed using HAE-2-IFU (ScyTek Laboratories, Inc). Briefly, slides were deparaffinized in xylene, followed by sequential incubations in 100%, 95%, and 70% ethanol. Tissue sections were stained with Mayer’s Hematoxylin (Lillie’s Modification) for 5 min, washed with two changes of distilled water, incubated with Bluing Reagent for 10–15 s, washed with two changes of distilled water, washed with ethanol, stained with Eosin Y Solution (Modified Alcoholic) for 2–3 min, and washed with three changes of ethanol. Some of the histology work was performed as a fee-for-service by Dr. Jonathan Fox (Department of Veterinary Sciences, University of Wyoming), including H&E, S100, and Melan A staining.
Cell migration assays
Would healing migration assays were performed. Briefly, 5 × 105 cells were seeded on collagen-coated, chambered coverslips (Ibidi, #80286). After 24 h when cells reached confluency, pipette tips were used to generate scratches (P2 tips for narrow scratches and P20 tips for wider scratches). After changing the media, time lapse confocal imaging was performed for 12–16 h, imaging every 5 min. Culture conditions were maintained at 37 °C and 5% CO2 using an INU series Microscope Stage Top Incubator (Tokai Hit; provided by Dr. John Oakey, University of Wyoming). Videos were compiled with NIH ImageJ software (Version 2.3.0; https://imagej.net/software/fiji/). For narrow scratches, individual cells were tracked using the MTrackJ plugin in ImageJ75, using the cell nucleus as the central tracking point to measure the total distance traveled. For wide scratches, the scratch area was manually quantified using MetaMorph software (Version 7.8.0.0; https://www.moleculardevices.com/products/cellular-imaging-systems/acquisition-and-analysis-software/metamorph-microscopy#gref).
Cell proliferation assays
2 × 105 cells were initially plated in 6-well plates. Every 24 h, cells from one plate were trypsinized for 5 min, stained with trypan blue, and counted using a Countess Automated Cell Counter (Invitrogen; provided by Dr. Don Jarvis, University of Wyoming).
Apoptosis assays
For apoptosis assays, cells were incubated for 30 min with 40 µl/ml CellEvent Caspase-3/7 Green ReadyProbes Reagent (#R37111, Life Technologies). Cells were washed with PBS (without Mg2+ and Ca2+), fixed with 4% paraformaldehyde for 20 min, washed, stained with 5 µg/ml Hoechst for 5 min, washed, mounted in Vectashield (Vector Laboratories), and sealed with nail polish. Green apoptotic cells were counted and presented as a percent of the total number of cells.
Fluorescence in situ hybridization (FISH)
FISH was performed following established protocols provided by Agilent Technologies, with slight modifications. Briefly, cells grown on chambered coverslips were washed three times with PBS, fixed with 4% paraformaldehyde for 20 min, washed three times with PBS for 5 min each, permeabilized with 0.1% Triton X-100 for 5 min, and washed three times with PBS for 5 min each. Cells were then incubated in boiling SSC buffer (15,557–044, Invitrogen) for 1 min in an 1100-W microwave, followed by a 10-min incubation in SSC buffer maintained just below boiling in the microwave. Slides were washed with Dako Wash buffer (K5499, Dako) and then washed for two minutes each in increasing concentrations of ethanol (70%, 85%, 100%). After air-drying the slides, probes were added and DNA denaturation was promoted by incubation at 72–74 °C for 10 min. For hybridization, slides were incubated at 37 °C for 12 h in dark, humid chambers, followed by washing with Dako Stringent Buffer (#K5499) at 63 °C for 10 min. Slides were then washed for one minute each in increasing concentrations of ethanol (70%, 80%, 100%), dried, and mounted in Dako Florescence Mounting Medium (#K5499) containing 20 µg/ml Hoechst.
The following FISH probes were acquired from Agilent Technologies: SureFISH 4q12KIT 155 kb red for the KIT gene (#G101058R, Dako), SureFISH chr4 CEP 613 kb green for the centromere of chromosome 4 (#G101066G, Dako), FISH RAMP1 red for the RAMP1 gene (#G110996X-8, Agilent Technologies), SureFISH chr2 CEP 448 kb green for the centromere of chromosome 2 (#G101089, Dako), SureFISH PADI2 red for the PADI2 gene (#G110996X-8, Agilent Technologies), SureFISH chr1 CEP 541 kb green for the centromere of chromosome 1 (#G101064G, Dako). Prior to use, 1 μl of each probe provided by Agilent was mixed with 8 µl IQFISH Fast Hybridization Buffer (#G9415A, Agilent Technologies, Inc).
RNA sequencing
RNA extraction, RNA library preparation, and RNA-sequencing were performed as a fee-for-service by GENEWIZ, Inc. For each cell line, frozen cell pellets were provided in triplicate to GENEWIZ, Inc and sequencing was performed using an Illumina HiSeq2500 platform in 2 × 100 bp paired-end configuration in High Output mode (V4 chemistry). Bioinformatics analysis was performed by GENEWIZ, Inc using CLC Genomics Workbench software (Qiagen): sequence quality control, trimming low quality bases and adapter sequences, mapping reads to the genome, determining the read density on genes/exons and annotating, calculating total hit counts and RPKM values for transcripts/genes, and comparing transcript expression levels. CLC Genomics Workbench detects differential gene expression based on metadata associated with the samples. Similar to EdgeR or DESeq2, the fit of a Generalized Linear Model with a negative binomial distribution was used as the basis for the statistics. Fold changes in expression levels and p-values were generated using the Wald test. For each comparison, genes with a false discovery rate (FDR) < 0.05 and absolute fold-change > 2 were considered as differentially expressed genes. For comparing NTF2 high dox- and NTF2 high dox + , a p-value < 0.05 was used as the cutoff. Heat maps were generated with iDEP.80 (http://bioinformatics.sdstate.edu/idep/) using the heatmap.2 function. Principal component analysis was performed with iDEP.80. Gene ontology enrichment analysis for DEGs was performed with iDEP.80 for biological processes and for cellular components. Pathway analysis was performed with iDEP.80, which takes into account fold-change values for all genes and is independent of DEGs. For pathway analysis, the significance cutoff was an FDR of 0.2, and Gene Set Enrichment Analysis was performed using the preranked mode in the fgsea package. Pathway analysis was also performed using the Reactome Pathway Database (https://reactome.org/) in order to determine the number of genes involved in specific pathways.
Microscopy and image quantification
For wide-field microscopy, nuclei were visualized using an Olympus BX51 fluorescence microscope with the following Olympus objectives: UPLFLN 40 × (NA 0.75, air) and UPLANAPO 60 × (NA 1.20, water). Images were acquired with a QIClick Digital charge-coupled device camera, mono, 12-bit (QIClick-F-M12) and cellSens software (Olympus). Cross-sectional nuclear areas were measured from the original thresholded images using MetaMorph software (Molecular Devices). For each coverslip, at least 50, and usually > 800, nuclei were quantified for nuclear size measurements. Colony morphology images were acquired with an Olympus SZX16 research fluorescence stereomicroscope, equipped with Olympus DP72 camera, 11.5 × zoom microscope body, and SDFPLAPO1XPF objective. Confocal imaging was performed on a spinning-disk confocal microscope based on an Olympus IX71 microscope stand equipped with a five-line LMM5 laser launch (Spectral Applied Research) and Yokogawa CSU-X1 spinning-disk head. Confocal images were acquired with an EM-CCD camera (ImagEM, Hamamatsu) using the following Olympus objectives: UPLFLN 10 × (NA 0.50, air) and UPLSAPO 60x (NA 0.85, oil). Z-axis focus was controlled using a piezo Pi-Foc (Physik Instrumentes), and multiposition imaging was achieved using a motorized Ludl stage. Generally, z-stacks were acquired with a z-slice thickness of 0.2 µm. Image acquisition and all system components were controlled using Metamorph software. Images were acquired with the same exposure time for fluorescence intensity measurements. Heterochromatin H3K9me3 staining distribution was quantified in ImageJ by drawing three straight lines per nucleus (4.5 μm in length) from the nuclear rim to the nuclear center, perpendicular to the nuclear envelope, and measuring pixel intensities along the lines. Pixel intensities along the line scans were then averaged for at least 50 nuclei from two independent experiments. Lamin A staining distribution was quantified in ImageJ by drawing a line (3 μm in length) perpendicular to the nuclear envelope and measuring pixel intensities along the line. Pixel intensities along the line scans were then averaged for at least 50 nuclei from two independent experiments. For FISH experiments, the z-slice with maximum signal intensity was selected. The centroid measurement function in ImageJ was used to determine the center of the nucleus. A line was drawn from the nucleus center to the nucleus rim passing through the FISH signal. The distance between the nucleus center and FISH signal was measured, and the distance between the nucleus center and rim was defined as the nucleus radius. The distance between the gene signal and nucleus center was divided by the nucleus radius, such that a value of 0 or 1 indicates the gene is located at the nucleus center or rim, respectively. For publication, images were cropped and pseudocolored using ImageJ, but were otherwise unaltered.
Statistics
Averaging and statistical analysis were performed for independently repeated experiments. Two-tailed Student’s t-tests assuming equal variances were performed in Excel (Microsoft). ANOVA tests were performed in GraphPad Prism. Log-rank (Mantel-Cox) tests for survival curves were performed in GraphPad Prism. The p-values, number of independent experiments, and error bars are denoted in the Figure Legends.
Data availability
All data and materials are available from the corresponding author upon request.
References
Weinberg, R. A. The Biology of Cancer 2nd edn. (Garland Science, Taylor & Francis Group, LLC, 2014).
Zink, D., Fischer, A. H. & Nickerson, J. A. Nuclear structure in cancer cells. Nat Rev Cancer 4, 677–687 (2004).
Chow, K. H., Factor, R. E. & Ullman, K. S. The nuclear envelope environment and its cancer connections. Nat. Rev. Cancer 12, 196–209 (2012).
Jevtic, P. & Levy, D. L. Mechanisms of nuclear size regulation in model systems and cancer. Adv. Exp. Med. Biol. 773, 537–569 (2014).
Bignold, L. P., Coghlan, B. L. & Jersmann, H. P. Cancer morphology, carcinogenesis and genetic instability: A background. Cancers https://doi.org/10.1007/3-7643-7378-4_1 (2006).
Stolz, W., Schmoeckel, C., Ryckmanns, F., Gross, J. & Braun-Falco, O. Morphometric and ultrastructural analyses of melanocytes, nevus cells, and melanoma cells. Arch. Dermatol. Res. 279, 167–172 (1987).
Mossbacher, U. et al. Increased nuclear volume in metastasizing “thick” melanomas. J. Invest. Dermatol. 106, 437–440 (1996).
Sorensen, F. B. & Erlandsen, M. Intralesional and metastatic heterogeneity in malignant melanomas demonstrated by stereologic estimates of nuclear volume. Lab Invest 62, 646–654 (1990).
Leiter, U. & Garbe, C. Epidemiology of melanoma and nonmelanoma skin cancer–the role of sunlight. Adv. Exp. Med. Biol. 624, 89–103 (2008).
Clark, W. H. Jr. et al. A study of tumor progression: The precursor lesions of superficial spreading and nodular melanoma. Hum. Pathol. 15, 1147–1165 (1984).
Ciarletta, P., Foret, L. & Ben Amar, M. The radial growth phase of malignant melanoma: Multi-phase modelling, numerical simulations and linear stability analysis. J. R. Soc. Interface 8, 345–368 (2011).
Vukovic, L. D., Jevtic, P., Zhang, Z., Stohr, B. A. & Levy, D. L. Nuclear size is sensitive to NTF2 protein levels in a manner dependent on Ran binding. J. Cell. Sci. 129, 1115–1127 (2016).
Paschal, B. M. & Gerace, L. Identification of NTF2, a cytosolic factor for nuclear import that interacts with nuclear pore complex protein p62. J. Cell Biol. 129, 925–937 (1995).
Clarkson, W. D., Kent, H. M. & Stewart, M. Separate binding sites on nuclear transport factor 2 (NTF2) for GDP-Ran and the phenylalanine-rich repeat regions of nucleoporins p62 and Nsp1p. J. Mol. Biol. 263, 517–524 (1996).
Corbett, A. H. & Silver, P. A. The NTF2 gene encodes an essential, highly conserved protein that functions in nuclear transport in vivo. J. Biol. Chem. 271, 18477–18484 (1996).
Madrid, A. S. & Weis, K. Nuclear transport is becoming crystal clear. Chromosoma 115, 98–109 (2006).
Bayliss, R. et al. Structural basis for the interaction between NTF2 and nucleoporin FxFG repeats. Embo J 21, 2843–2853 (2002).
Bayliss, R. et al. Interaction between NTF2 and xFxFG-containing nucleoporins is required to mediate nuclear import of RanGDP. J. Mol. Biol. 293, 579–593 (1999).
Feldherr, C., Akin, D. & Moore, M. S. The nuclear import factor p10 regulates the functional size of the nuclear pore complex during oogenesis. J. Cell Sci. 111(Pt 13), 1889–1896 (1998).
Goldberg, M. W. et al. Ran alters nuclear pore complex conformation. J. Mol. Biol. 300, 519–529 (2000).
Levy, D. L. & Heald, R. Nuclear size is regulated by importin alpha and Ntf2 in Xenopus. Cell 143, 288–298 (2010).
Dittmer, T. A. & Misteli, T. The lamin protein family. Genome Biol. 12, 222 (2011).
Jevtic, P. et al. Concentration-dependent effects of nuclear lamins on nuclear size in xenopus and mammalian cells. J. Biol. Chem. 290, 27557–27571 (2015).
Adam, S. A., Sengupta, K. & Goldman, R. D. Regulation of nuclear lamin polymerization by importin alpha. J. Biol. Chem. 283, 8462–8468 (2008).
Gambus, A., Khoudoli, G. A., Jones, R. C. & Blow, J. J. MCM2-7 form double hexamers at licensed origins in Xenopus egg extract. J. Biol. Chem. 286, 11855–11864 (2011).
Makarov, A. A. et al. Lamin A molecular compression and sliding as mechanisms behind nucleoskeleton elasticity. Nat. Commun. 10, 3056 (2019).
Papatheodorou, I. et al. Expression Atlas update: From tissues to single cells. Nucleic Acids Res. 48, D77–D83 (2020).
Cheng, H. et al. RICTOR amplification defines a novel subset of patients with lung cancer who may benefit from treatment with mTORC1/2 inhibitors. Cancer Discov. 5, 1262–1270 (2015).
Schadendorf, D. et al. Melanoma. Lancet 392, 971–984 (2018).
Yang, H., Ganguly, A. & Cabral, F. Inhibition of cell migration and cell division correlates with distinct effects of microtubule inhibiting drugs. J. Biol. Chem. 285, 32242–32250 (2010).
Dasgupta, T. & Brasfield, R. Metastatic melanoma. A clinicopathological study. Cancer 17, 1323–1339 (1964).
Damsky, W. E., Rosenbaum, L. E. & Bosenberg, M. Decoding melanoma metastasis. Cancers (Basel) 3, 126–163 (2010).
Dutta, S. & Sengupta, P. Men and mice: Relating their ages. Life Sci. 152, 244–248 (2016).
Logan, M., Anderson, P. D., Saab, S. T., Hameed, O. & Abdulkadir, S. A. RAMP1 is a direct NKX3.1 target gene up-regulated in prostate cancer that promotes tumorigenesis. Am. J. Pathol. 183, 951–963 (2013).
Zhang, W., Hou, T., Niu, C., Song, L. & Zhang, Y. B3GNT3 expression is a novel marker correlated with pelvic lymph node metastasis and poor clinical outcome in early-stage cervical cancer. PLoS ONE 10, e0144360 (2015).
Li, X., Iomini, C., Hyink, D. & Wilson, P. D. PRKX critically regulates endothelial cell proliferation, migration, and vascular-like structure formation. Dev. Biol. 356, 475–485 (2011).
Porter, S. et al. ADAMTS8 and ADAMTS15 expression predicts survival in human breast carcinoma. Int. J. Cancer 118, 1241–1247 (2006).
Monti, P. et al. TP63 mutations are frequent in cutaneous melanoma, support UV etiology, but their role in melanomagenesis is unclear. Oncol. Rep. 38, 1985–1994 (2017).
Romagnoli, M. et al. Epithelial-to-mesenchymal transition induced by TGF-beta1 is mediated by Blimp-1-dependent repression of BMP-5. Cancer Res. 72, 6268–6278 (2012).
Tang, Y. et al. Silencing of CerS6 increases the invasion and glycolysis of melanoma WM35, WM451 and SK28 cell lines via increased GLUT1-induced downregulation of WNT5A. Oncol. Rep. 35, 2907–2915 (2016).
Wang, T. et al. Ankyrin G expression is associated with androgen receptor stability, invasiveness, and lethal outcome in prostate cancer patients. J. Mol. Med. (Berl) 94, 1411–1422 (2016).
Dagogo-Jack, I. & Shaw, A. T. Tumour heterogeneity and resistance to cancer therapies. Nat. Rev. Clin. Oncol. 15, 81–94 (2018).
Wang, Z., Tan, M., Chen, G., Li, Z. & Lu, X. LncRNA SOX2-OT is a novel prognostic biomarker for osteosarcoma patients and regulates osteosarcoma cells proliferation and motility through modulating SOX2. IUBMB Life 69, 867–876 (2017).
Due, H. et al. miR-155 as a Biomarker in B-Cell Malignancies. Biomed. Res. Int 2016, 9513037 (2016).
Gonzalez, B., Fece de la Cruz, F., Samuelsson, J. K., Alibes, A. & Alonso, S. Epigenetic and transcriptional dysregulation of VWA2 associated with a MYC-driven oncogenic program in colorectal cancer. Sci. Rep. 8, 11097 (2018).
Demichelis, F. et al. Identification of functionally active, low frequency copy number variants at 15q21.3 and 12q21.31 associated with prostate cancer risk. Proc. Natl. Acad. Sci. U S A 109, 6686–6691 (2012).
Huang, X., Lv, W., Zhang, J. H. & Lu, D. L. miR96 functions as a tumor suppressor gene by targeting NUAK1 in pancreatic cancer. Int. J. Mol. Med. 34, 1599–1605 (2014).
Chen, P., Li, K., Liang, Y., Li, L. & Zhu, X. High NUAK1 expression correlates with poor prognosis and involved in NSCLC cells migration and invasion. Exp. Lung Res. 39, 9–17 (2013).
van Steensel, B. & Belmont, A. S. Lamina-associated domains: Links with chromosome architecture, heterochromatin, and gene repression. Cell 169, 780–791 (2017).
Lochs, S. J. A., Kefalopoulou, S. & Kind, J. Lamina associated domains and gene regulation in development and cancer. Cells 8, 271. https://doi.org/10.3390/cells8030271 (2019).
Curtin, J. A., Busam, K., Pinkel, D. & Bastian, B. C. Somatic activation of KIT in distinct subtypes of melanoma. J. Clin. Oncol. 24, 4340–4346 (2006).
Willmore-Payne, C., Holden, J. A., Hirschowitz, S. & Layfield, L. J. BRAF and c-kit gene copy number in mutation-positive malignant melanoma. Hum. Pathol. 37, 520–527 (2006).
Shachar, S. & Misteli, T. Causes and consequences of nuclear gene positioning. J. Cell Sci. 130, 1501–1508 (2017).
Villanueva, J. & Herlyn, M. Melanoma and the tumor microenvironment. Curr. Oncol. Rep. 10, 439–446 (2008).
Molognoni, F. et al. Epigenetic reprogramming as a key contributor to melanocyte malignant transformation. Epigenetics 6, 450–464 (2011).
Seftor, E. A. et al. Epigenetic transdifferentiation of normal melanocytes by a metastatic melanoma microenvironment. Cancer Res. 65, 10164–10169 (2005).
Wu, L. W., Herlyn, M. & Zhang, G. In Melanoma Development (ed. Bosserhoff, A.) 357–368 (Springer, 2017).
Barcellos-Hoff, M. H. It takes a tissue to make a tumor: Epigenetics, cancer and the microenvironment. J. Mammary Gland Biol. Neoplasia 6, 213–221 (2001).
Cremer, T. & Cremer, M. Chromosome territories. Cold Spring Harb Perspect. Biol. 2, a003889 (2010).
Finn, E. H. & Misteli, T. Molecular basis and biological function of variability in spatial genome organization. Science 365, 9498. https://doi.org/10.1126/science.aaw9498 (2019).
Gluz, O. et al. Nuclear karyopherin alpha2 expression predicts poor survival in patients with advanced breast cancer irrespective of treatment intensity. Int. J. Cancer 123, 1433–1438 (2008).
Wang, C. I. et al. Importin subunit alpha-2 is identified as a potential biomarker for non-small cell lung cancer by integration of the cancer cell secretome and tissue transcriptome. Int. J. Cancer 128, 2364–2372 (2011).
Wang, C. I. et al. Quantitative proteomics reveals regulation of karyopherin subunit alpha-2 (KPNA2) and its potential novel cargo proteins in nonsmall cell lung cancer. Mol. Cell Proteom. 11, 1105–1122 (2012).
Christiansen, A. & Dyrskjot, L. The functional role of the novel biomarker karyopherin alpha 2 (KPNA2) in cancer. Cancer Lett. 331, 18–23 (2013).
Gao, C. L., Wang, G. W., Yang, G. Q., Yang, H. & Zhuang, L. Karyopherin subunit-alpha 2 expression accelerates cell cycle progression by upregulating CCNB2 and CDK1 in hepatocellular carcinoma. Oncol. Lett. 15, 2815–2820 (2018).
Gousias, K., Becker, A. J., Simon, M. & Niehusmann, P. Nuclear karyopherin a2: A novel biomarker for infiltrative astrocytomas. J. Neurooncol. 109, 545–553 (2012).
Ma, Y. et al. Expression of p63 and CK5/6 in early-stage lung squamous cell carcinoma is not only an early diagnostic indicator but also correlates with a good prognosis. Thorac Cancer 6, 288–295 (2015).
Wei, X. et al. Mutational and functional analysis reveals ADAMTS18 metalloproteinase as a novel driver in melanoma. Mol. Cancer Res. 8, 1513–1525 (2010).
Gibney, G. T. & Zager, J. S. Clinical development of dabrafenib in BRAF mutant melanoma and other malignancies. Expert Opin. Drug Metab. Toxicol. 9, 893–899 (2013).
Broman, K. K., Dossett, L. A., Sun, J., Eroglu, Z. & Zager, J. S. Update on BRAF and MEK inhibition for treatment of melanoma in metastatic, unresectable, and adjuvant settings. Expert Opin. Drug Saf. 18, 381–392 (2019).
Flaherty, K. T. et al. Combined BRAF and MEK inhibition in melanoma with BRAF V600 mutations. N. Engl. J. Med. 367, 1694–1703 (2012).
Strub, T. et al. SIRT6 haploinsufficiency induces BRAF(V600E) melanoma cell resistance to MAPK inhibitors via IGF signalling. Nat. Commun. 9, 3440 (2018).
Edens, L. J. & Levy, D. L. cPKC regulates interphase nuclear size during Xenopus development. J. Cell Biol. 206, 473–483 (2014).
Burkholder, T., Foltz, C., Karlsson, E., Linton, C. G. & Smith, J. M. Health evaluation of experimental laboratory mice. Curr. Protoc. Mouse Biol. 2, 145–165 (2012).
Meijering, E., Dzyubachyk, O. & Smal, I. Methods for cell and particle tracking. Methods Enzymol. 504, 183–200 (2012).
Jevtic, P. & Levy, D. L. Nuclear size scaling during Xenopus early development contributes to midblastula transition timing. Curr. Biol. 25, 45–52 (2015).
Acknowledgements
We thank Dr. Nicolas Blouin (INBRE, University of Wyoming) for bioinformatics assistance, Dr. Jay Gatlin (University of Wyoming) for use of his tissue culture room, Dr. John Oakey (University of Wyoming) for use of his microscope stage top incubator, Dr. Jonathan Fox (University of Wyoming) for mouse tissue analysis, Dr. Wei Guo (University of Wyoming) for use of equipment to prepare tissue slides, and Osimanjiang Wupu (University of Wyoming) for help with mouse spinal cord isolations. This work was supported by the National Institutes of Health/National Institute of General Medical Sciences (R35GM134885, R01GM113028, and P20GM103432) and the American Cancer Society (RSG-15-035-01-DDC).
Author information
Authors and Affiliations
Contributions
Conceptualization, L.D.V., D.L.L.; Investigation, L.D.V. (melanoma studies), P.C. (mCherry control experiments), S.M. (lamin western blots), K.H.W. (prostate cancer studies), J.P.G. (mouse husbandry and injections); Writing – Original Draft, L.D.V., D.L.L.; Writing – Review & Editing, L.D.V., P.C., S.M., K.H.W., J.P.G., D.L.L.; Funding Acquisition, D.L.L.; Supervision, D.L.L.
Corresponding author
Ethics declarations
Competing interests
The authors declare no competing interests.
Additional information
Publisher's note
Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
Supplementary Information
Supplementary Video 1.
Supplementary Video 2.
Rights and permissions
Open Access This article is licensed under a Creative Commons Attribution 4.0 International License, which permits use, sharing, adaptation, distribution and reproduction in any medium or format, as long as you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons licence, and indicate if changes were made. The images or other third party material in this article are included in the article's Creative Commons licence, unless indicated otherwise in a credit line to the material. If material is not included in the article's Creative Commons licence and your intended use is not permitted by statutory regulation or exceeds the permitted use, you will need to obtain permission directly from the copyright holder. To view a copy of this licence, visit http://creativecommons.org/licenses/by/4.0/.
About this article
Cite this article
Vuković, L.D., Chen, P., Mishra, S. et al. Nuclear Transport Factor 2 (NTF2) suppresses WM983B metastatic melanoma by modifying cell migration, metastasis, and gene expression. Sci Rep 11, 23586 (2021). https://doi.org/10.1038/s41598-021-02803-0
Received:
Accepted:
Published:
DOI: https://doi.org/10.1038/s41598-021-02803-0
This article is cited by
Comments
By submitting a comment you agree to abide by our Terms and Community Guidelines. If you find something abusive or that does not comply with our terms or guidelines please flag it as inappropriate.