The kidney’s inherent complexity has made identifying cell-specific pathways challenging, particularly when temporally associating them with the dynamic pathophysiology of acute kidney injury (AKI). Here, we combine renal cell-specific luciferase reporter mice using a chemoselective luciferin to guide the acquisition of cell-specific transcriptional changes in C57BL/6 background mice. Hydrogen peroxide generation, a common mechanism of tissue damage, was tracked using a peroxy-caged-luciferin to identify optimum time points for immunoprecipitation of labeled ribosomes for RNA-sequencing. Together, these tools revealed a profound impact of AKI on mitochondrial pathways in the collecting duct. In fact, targeting the mitochondria with an antioxidant, ameliorated not only hydrogen peroxide generation, but also significantly reduced oxidative stress and the expression of the AKI biomarker, LCN2. This integrative approach of coupling physiological imaging with transcriptomics and drug testing revealed how the collecting duct responds to AKI and opens new venues for cell-specific predictive monitoring and treatment.
In highly heterogenous organs such as the kidney, associating pathophysiological changes such as generation of reactive oxygen species (ROS) with transcriptional signals at the cell-type level are challenging, if not impossible. Furthermore, monitoring these pathophysiological intercellular changes non-invasively and longitudinally has not been shown in the kidney. Here we present a coupled cell-specific image-guided transcriptomics approach to visualize ROS generation and associate it with gene expression changes in the injured kidney.
In vivo methods for optically monitoring cell-specific or temporal changes in reactive oxygen species (ROS) have been previously described in transplanted tissues1; however, none with a cell-specific approach within the heterogeneous structures of the kidney. Standard methods for quantifying oxidative stress has required serial sacrifice and measurement of lipid peroxidation or byproducts such as malondialdehyde (MDA)2. In addition, DNA/RNA damage, hydrogen peroxide (H2O2) and nitric oxide levels, as well as changes in antioxidants such as glutathione and catalase, have been measured ex vivo to assess oxidative stress. However, each of these methods is static and provides only cross-sectional assessments of oxidative stress without cell specificity.
The unmet need to identify and map damage to different types of epithelia within the nephron stems from our inadequate understanding of the diverse causes and cellular responses to acute changes in kidney function, currently lumped together under the umbrella term of acute kidney injury (AKI)3,4,5. The kidney is derived from the ureteric bud and the metanephrogenic mesenchyme; these two progenitor cell populations differentiate into more than 26 different cell types in the adult kidney6.
One common and essential mechanism for many types of AKI is unhindered activation of oxidative stress programs. Oxidative stress is generally a result of the cessation and subsequent reperfusion of renal blood flow leading to the generation of ROS. Excessive ROS can cause lipid peroxidation, DNA damage, inactivation of antioxidants, and cytoskeleton reorganization, which leads to inflammation, fibrosis and eventually the irreversible condition of end stage renal disease (ESRD)7. Oxidative stress can be induced by ischemia-reperfusion injury (IRI), shock, sepsis, surgery and the administration of imaging contrast or other nephrotoxic agents8,9. However, these processes have eluded targeted analysis because of the paucity of effective methods to visualize the sites of damage.
Here, we report the generation of a group of cell-specific transgenic luciferase reporter mice to longitudinally monitor H2O2 generation after kidney IRI. We quantified oxidative stress in a non-invasive, tissue-specific manner using bioluminescence as a readout to identify the optimal time point for cell-specific transcriptional analyses. We found that ischemia-reperfusion induced oxidative stress generation in different segments of the kidney but with different timing and dose sensitivity, a finding that sheds light on a long-standing debate concerning the relative responses of different kidney segments. Biomarkers of oxidative stress damage were significantly reduced following pretreatment with an antioxidant that moderated the ischemic injury in vivo. In sum, the ability to dynamically monitor cell-specific ROS generation and use it to pinpoint the optimum time for cell-specific transcriptional interrogation in animal models of human kidney disease provides a unique opportunity to understand the impact of different forms of AKI on the different cell types of the kidney. Most importantly, this coupled approach that exploits a cell-specific luciferase reporter with a chemoselective luciferin to guide time- and cell-specific RNA-isolation and transcriptional analysis can be applied to many other mouse models of human disease.
Non-invasive cell-specific imaging of kidney cells
In order to image ROS generation following kidney injury, we generated both global luciferase and tissue-specific reporters—the glomerulus (Podocin promoter), the proximal tubule (Slc34a1 promoter), and the collecting duct (HoxB7 promoter) (Fig. 1a). Activation of the firefly luciferase (luc) gene required Cre-mediated recombination of a loxP-flanked STOP fragment intercalated between the luc sequence and the Gt(ROSA)26Sor promoter10 (Fig. 1b) by the following Cre-recombinase mice: EIIa-Cre, with Cre-recombinase expression in every cell-type; Pod-Cre, with Cre-recombinase expression in podocin-positive glomerular cells under the control of the human NPHS2 gene, to make PodR26Luc/+; Slc34a1-Cre, with Cre-recombinase expression in S1 and S2 segments of the proximal tubule cells, to make to make Slc34a1R26Luc/+; and HoxB7-Cre, with Cre-recombinase expression in mesonephric duct and its derivatives, which includes the collecting duct and ureteral epithelia, to make HoxB7R26Luc/+ (Fig. 1a–c and Supplementary Table 1)11,12,13,14. Bioluminescence emanating from these specific reporter cells was captured in vivo by an optical imaging system (IVIS Spectrum, PerkinElmer) and interpreted using Living-Image (PerkinElmer) and InVivoAX (InVivo Analytics) software. Recombination was confirmed in EIIaR26Luc/+, PodR26Luc/+, Slc34a1R26Luc/+, and HoxB7R26Luc/+ luciferase reporter mice by imaging luciferase activity with a saturating dose of D-Luciferin (150 mg/kg: Supplementary Figs. 1–4, Supplementary Movies 1–3)15. Kidney-specific luciferase reporter activity was confirmed using bioluminescent tomographic reconstruction and alignment to the digital mouse atlas (InVivoPLOT)16. Luciferase reporter mice illuminated the expected expression domains in the kidney including the entire kidney (EIIa-promoter) (Supplementary Fig. 4a), and specific segments of the nephron (HoxB7, Slc34a1, and Podocin promoters; Supplementary Figs. 1–3) using D-luciferin (150 mg/kg).
Longitudinal progression of oxidative stress in injured kidney
To simulate AKI in a manner consistent with clinical settings, we challenged conditional luciferase reporter mice with bilateral IRI to induce ROS17. Either 30 min of bilateral IRI or sham surgery was used in order to reproduce previous studies where AKI caused significant oxidative stress related injury, previously measured ex vivo18. A modified version of a H2O2 reporter caged-luciferin, called peroxy-caged luciferin (PC-Luciferin), was used to quantify Cre dependent, cell-specific, H2O2 generation (Supplementary Fig. 5)1. Chemical caging of firefly luciferin with alkyl group (selectively cleavable) prevents production of light from luciferin/luciferase reaction. As the result, no light is produced in the absence of a cleaving agent, H2O2. PC-Luciferin, unlike free D-Luciferin, is incapable of undergoing the luciferin/luciferase reaction unless first hydrolyzed by H2O2; hence, PC-Luciferin selectively detects H2O2 production in a concentration-dependent manner1.
To longitudinally and repetitively monitor ROS in vivo with a non-invasive and cell-specific method, we repetitively collected whole body optical images from the same reporter mouse 3, 6, 12, and 24 h after IRI using PC-luciferin (10 mg/kg) to map spatiotemporal H2O2 expression. The global luciferase reporter mouse, EIIaR26Luc/+, revealed a significant increase in H2O2 reporter activity in both kidneys 6 h (fold change: P = 0.0175) after IRI challenge (Fig. 1e, f). The EIIaR26Luc/+ luciferase-luciferin signal was not significantly modulated by the injury (Supplementary Fig. 4b, c); therefore, in this model the caged-luciferin activity is not impaired by changes in luciferase enzymatic activity.
In order to determine whether the time course of oxidative stress was associated with classical markers of AKI we obtained sequential in vivo measurements of oxidative stress with concomitant measurements of tissue markers of lipid peroxidation (LPOs) at 3, 6, 12, and 24 h after IRI. Blood parameters were analyzed using a handheld clinical analyzer (Fig. 1g, h and Supplementary Table 2). To calibrate our in vivo measurements against established markers of IRI-AKI, excised kidneys were bisected and one half was processed for MDA (Fig. 1i and Supplementary Table 3) while total RNA was extracted from the other. Consistent with previous studies, IRI of the kidney resulted in significant increase in blood urea nitrogen (BUN: P < 0.001), serum creatinine (sCr: P < 0.0001), and LPOs (P < 0.05) over the 24 h period post injury (Fig. 1g–i)18. In vivo measures of EIIaR26Luc/+ PC-luciferin activity were in agreement with MDA levels, at 6 h after IRI (Fig. 1e, f, i). Hmox1, a gene induced by oxidative damage and a potential antioxidant, trended with MDA levels and the caged PC-Luciferin yield, indicating that peak oxidative stress occurred at 6 h in this model19,20. In sum, we demonstrated consistent associations between PC-Luciferin and classical markers of oxidation.
Collecting duct is a dominant source of ROS following AKI
An expression pattern similar to EIIaR26Luc/+ PC-luciferin (global) activity was found when HoxB7R26Luc/+ PC-luciferin (collecting duct) reporter mouse was challenged with IRI for 30 min (Fig. 2a, b). HoxB7R26Luc/+ showed a robust total change in photon emission (>106 photons s−1 cm−2 sr−1) from baseline and a 61.2 ± 17.7 mean fold change (P = 0.0249) at the 6 h time point. Lcn2 (Fig. 2c), a medullary kidney injury biomarker and iron scavenger15, mirrored the ROS activity at this time point by being significantly elevated at 6 h (287-fold: P = 0.0114), which was consistent with our previous findings15. A new marker of kidney stress derived from the kidney medulla, Tacstd221, was also significantly elevated (P < 0.05) in a dose-dependent manner (Fig. 2d). A time course of expression (Fig. 2e–f and Supplementary Table 4) confirmed a rapid genetic response to oxidative damage. Inflammatory cytokines Il1a, Il1b, and Il6, known to be induced by TNFa22 and hypoxia23 in ischemic renal injury, also peaked early. Egf, a candidate kidney injury biomarker, was significantly downregulated (P < 0.05) as observed clinically in patients with AKI and CKD. With a lower dose of IRI (15 min), collecting duct Lcn2 was activated only 39.9-fold, and ROS generation was restricted without a significant change in H2O2 reporter activity (Fig. 2i, j) or in LPOs generation17. These data imply that the collecting duct has a robust system of ROS scavenging, but these cells are still activated at lower doses of injury.
Differential ROS generation in the nephron
In comparison to the collecting ducts, proximal tubule Slc34a1-Cre H2O2 dependent bioluminescence was delayed, and only significantly (P < 0.05) visible at 12 and 24 h following 30 min of IRI. Nor did it correlate with peak LPO signal. Furthermore, the proximal nephron H2O2 bioluminescent signal was a log order of magnitude less than the collecting duct even at its peak (Fig. 3a, b). The PodR26Luc/+ mice also produced significant (P < 0.05) ROS-induced luciferase signal in the glomerular compartment, however, at a much smaller delta change in photon emission and overall fold change (Supplementary Fig. 6a, b). These results were unexpected since the proximal tubule comprises the majority of kidney epithelia and baseline reporter activity was comparable in each reporter demonstrating that this result is specific to the peroxide reaction, not luciferase expression (Supplementary Figs. 1–3). The limited response of the glomeruli was consistent with histological evidence that glomerular epithelia have limited gene responsiveness and evident injury in AKI and consistent with the limited response of the proximal tubules20,21 after 30 min of IRI. In addition, baseline luciferase activity (D-luciferin), which we monitored immediately after each PC-luciferin imaging session, was not significantly changed from baseline, suggesting that the IRI procedure did not impair luciferase reporter activity (Supplementary Fig. 4). Perhaps the limited H2O2 reporter activity in the proximal tubule was due to antioxidant scavenging activities which rapidly clear the ROS burden. Alternatively and most likely, enhanced sensitivity of this segment to hypoxic stress might render the cells either quiescent or apoptotic. To test the latter possibility, we examined the kidney at a reduced ischemic dose of 15 min IRI, monitored for a period of 7 days to observe recovery, and found a more rapid increase in H2O2 reporter activity in the proximal tubule (Fig. 3c, d). Expression of the proximal tubule injury biomarker Kim1 (Fig. 3f) was upregulated 95-fold at 15 min post IRI, while 30 min of IRI resulted in 35-fold increase, which mirrored the Slc34a1-Luciferase H2O2 reporter findings of 4.6 × 106 change in photons versus 7.2 × 105 change at 24 h, respectively. A time course of proximal tubule kidney injury after 30 min of IRI with biomarkers such as Krt20 and Kim121,24 demonstrated significant (P < 0.05) induction at 12 h after injury, consistent with the time course of expression of Slc34a1-Cre dependent luciferase (Slc34a1R26Luc/+) in the proximal tubule (Fig. 3b, g, h and Supplementary Table 4). The gene expression data indicate a significant (P < 0.05) activation of this compartment at 12 h after IRI, which mirrored H2O2 reporter activity, although substantially less than that generated by the collecting duct with 30 min of IRI.
In sum, by longitudinal monitoring of cell-specific oxidative stress in real-time, we demonstrated that the collecting duct is a particularly prominent and specific site of ROS generation. The response of the collecting duct differs in both timing and dose dependence to that of the proximal tubule. Our real-time ROS imaging data are consistent in timing with tissue-specific biomarkers (e.g., Lcn2, Krt20, and Kim1) and are in agreement with classical markers of cellular injury (sCr, BUN, and MDA).
Transcriptional mapping of collecting duct after kidney IRI
We were surprised by the prominent expression of oxidative stress by the collecting duct. In order to examine its mechanisms, we determined whether H2O2 imaging overlapped spatiotemporally with nascent gene expression (Fig. 4). Mice with collecting duct ribosome-tagged mRNA were generated by breeding Hoxb7-Cre with Gt(ROSA)26Sor-mCherry-Rpl10a (RiboTRAP) mice (Supplementary Fig. 7) and these HoxB7RPL/+ offspring were challenged with 30 min IRI (Fig. 4a, b). Kidneys were collected 9 h after injury which followed the peak of the H2O2 collecting duct signal. At this time point the injury induced transcriptional response25 is robust and serum creatinine (1.1 mg/dL) and tissue parameters (kidney injury biomarkers LCN2/KIM1) have confirmed initiation of injury. To confirm that the RiboTRAP system is specific for collecting duct we analyzed expression of Aqp2 which is expressed specifically in the principal cells of the collecting duct. Aqp2 was enhanced by 18 ± 2.8-fold in pulldown of RiboTRAP mRNA compared with whole kidney RNA extract. RNA from four sham and four IRI HoxB7RPL/+ mice were isolated by magnetic immunoprecipitation (Fig. 4c–f) and sequenced with a HiSeq system (Illumina). We observed profound transcriptional changes in the collecting duct in response to ischemic injury with almost 8000 differentially up- and downregulated genes between IRI vs. sham HoxB7+ populations (FDR < 0.01) (Fig. 4g, h). Consistent with our previous observations, hypoxia inducible genes Hspa1b (4.4-fold) and Hmox1 were upregulated (4.2-fold) along with the pro-inflammatory cytokines Il1b and Il6 (12- and 190-fold). Interestingly, profibrotic genes were also modulated. Rasal1 was downregulated 4.4-fold following IRI, consistent with the observation of RASAL1 hypermethylation leading to prolonged fibroblast activation and fibrogenesis after iAKI26. Tgfβ1 and Fgf227 were upregulated by 4.0-fold and 9.5-fold, respectively, both of which can induce fibroblast activation in vivo28. In addition, S100A9, a cytoplasmic Ca binding protein, was also upregulated 35-fold in response to ischemia. Kidney injury genes Krt20 (proximal nephron), Clu, Spp1, Lcn2, and Tacstd2 (distal nephron) were upregulated 4.9-, 6.8-, 2.7-, 22-, and 2.7-fold, respectively. This sample of modulated genes confirms that the proximal nephron and the collecting ducts were activated by the injury.
To gain deeper insight into the transcriptional programs altered by IRI, we performed functional enrichment analysis on differentially expressed genes based on public databases, including KEGG, Reactome, and Gene Ontology. This analysis was applied separately to differentially up- and downregulated genes with FDR threshold of <0.01 to identify significantly enriched pathways (Fig. 4i). Activated modules following IRI included those involved in inflammation/immunity, development, apoptosis, and response to ROS. In addition, we observed downregulation of many mitochondrion-associated processes, implying that ischemic/hypoxic injury leads to a change in the functional state, from generating ATP to generating peroxide, in the collecting duct. In fact, 11 out of 13 detected members of the nuclear DNA expressed mitochondrial complex I (Cx1) genes (NADH dehydrogenase (ubiquinone) alpha subcomplex 1-12) were significantly downregulated by an average of 1.3-fold (FDR range: 4.5E−20 to 0.03). Cx1 impairment and downregulation is known to cause H2O2 and ROS generation29,30.
In sum, our results show that leveraging the ROS-reporter animal uncovered the key pathways and kinetics of oxidative stress. Our results also distinguish generalized functional (sCr and BUN) and inflammatory responses (Hspa1b, Il1b) from ROS-associated responses (PC-Luciferin; Hmox1, Lcn2).
Reduction of ROS cellular injury with an antioxidant
Liberated iron complexes from mitochondria, necrotized cells and erythrocytes constitute ROS which subsequently oxidize cellular lipid and lipid released from necrotic tissue. Furthermore, mitochondria are a dominant source of cellular ROS31 and thus likely a critical driver of IRI in the collecting duct where mitochondria are abundant. To test this hypothesis, MitoTEMPO (MitoT), a mitochondria-specific superoxide scavenger, was used to investigate the role of ROS and in particular, mitochondrial ROS in IRI. A single bolus of 10 mg/kg of MitoT administered s.q. immediately prior to IRI surgery had a significant effect on H2O2 activity at 6 h (mean 57.5-fold vs 6.19-fold change; P < 0.001), and delaying the upregulation of ROS in the collecting duct till 12 h post IRI (mean 55.7-fold vs 34.9-fold with treatment: Fig. 5a, b). We did not observe a significant difference in sCr or BUN at 6 h (Fig. 5c, d) because blood metabolites do not change rapidly. However, MitoT was observed to protect the kidney from the other manifestations of IRI damage including inflammation and ROS lipid peroxidation as shown by the significant reduction in MDA levels 6 h (P = 0.0027) after IRI compared with the untreated group (Fig. 5c and Supplementary Table 3).
Collecting duct is a significant site of oxidative damage
LCN2 is an established marker of injury expressed in the thick ascending loop of Henle and the collecting duct15. The Lcn2-reporter mouse has been shown to be a significantly more sensitive system to test the time course of kidney injury than sCr or BUN15. Furthermore, we have shown that LCN2 is an iron scavenger in septic conditions32 and likely in aseptic conditions as well33. Consequently, we challenged the Lcn2-luciferase reporter mouse15 with 30 min of bilateral IRI with and without MitoT and longitudinally imaged oxidative stress with PC-luciferin. With a single application of MitoT immediately prior to ischemic injury, Lcn2-luciferase expression in the MitoT group returned to baseline by 24 h post IRI, whereas the untreated group maintained 20-fold Lcn2-luciferase reporter activity over baseline (Fig. 6a). These data reveal that even a modest reduction of mitochondrial oxidative stress can suppress responses characteristic of renal cell injury.
In this model, we also found that highly sensitive and rapidly responding kidney injury-associated genes showed significant (P < 0.05) reduction following MitoT treatment (Fig. 6b–j). Oxidative stress transcripts Hmox1, Hspa1b, and Hif1a were significantly (P < 0.05) downregulated (Fig. 6b–d) as was a panel of established kidney injury response genes (Fig. 6e–g). Furthermore, the inflammatory potential of IRI was reduced as shown by the significant (P < 0.05) reduction in pro-inflammatory cytokine expression (Fig. 6i and Supplementary Table 5)34. Interestingly, Il1b improved while Il6 was not ameliorated, suggesting reduced activation of the inflammasome (Fig. 6j)35.
Many acute human tissue injuries are identified through changes in the function of the target tissue, for example IRI results in decreased filtration which results in a rise in serum Creatinine (sCr) and blood urea (BUN). However, these clinically identifiable markers of tissue injury may be detected in only a fraction of injuries, are not well correlated with injury severity, and can have slow kinetics21,36. Indeed, sCr does not reflect renal pathology in the intensive care unit37,38, nor does sCr necessarily correlate with urinary biomarkers since the latter are expressed earlier than the rise in sCr and with greater sensitivity and specificity for tissue damage. In animal models, changes in blood chemistry, histology, and gene expression can all be used to identify and study injury response. However, these tools have limited temporal resolution, are invasive, and generally terminate the experiment. There is need for an approach which allows monitoring of the injury response non-invasively in laboratory animals in vivo.
In order to understand the anatomy and physiology of tissue injury, we instituted two different types of imaging technology. The first provides tissue specificity. The heterogeneous composition of the kidney is not typically considered when monitoring AKI by standard clinical tests or even when urinary biomarkers are measured by quantitative tests such as Elisa. It is also difficult to distinguish the contribution of each cell-type when interrogating the organ as a whole or to know which molecular pathway is primary or secondary to damage. A number of cell-specific animal models have become available to researchers39 and when combined with luciferase-based technology15, longitudinal and repetitive assessment of kidney injury is possible. Here we instituted a variety of tissue-specific Cre-recombinase mouse lines to provide a genetic means of activating luciferase in different compartments of the kidney.
The second tool that is necessary for physiologic interrogation is an assortment of biologically relevant reporters that monitor different cellular events. Caged-luciferin chemistry enables the interrogation of numerous processes with enzymatic activities such as cell-penetrating peptide conjugates40, cell surface glycosylation41, hydrogen peroxide fluxes1, and fatty acid uptake42. It also allows imaging of enzyme activities such as beta-galactosidase43, caspases44,45,46, furin47, and beta-lactamase48 in the presence of firefly luciferase. Hence this broad range of substrates can effectively map the kinetics of many different cellular functions in various forms of tissue damage or after treatment with protective medications. The broad applicability of this technique is demonstrated by caspase 3/7 caged-luciferin expression after IRI (Supplementary Fig. 8)49.
By combining the caged-luciferin technology with tissue-specific Cre-mediated luciferase, we obtained tissue-specific readouts of the activated form of PC-Luciferin to monitor the generation of a key ROS molecule, H2O2 after IRI. Surprisingly the collecting duct was a major source of H2O2 based on PC-Luciferin activated in the HoxB7-luciferase mouse. One-third of the cells of the collecting duct are mitochondrial rich intercalated (IC) cells, suggesting that these cells may be the primary source of the H2O2. We confirmed the mitochondrial basis of collecting duct responses to IRI by quantitative Bio-Imaging which identified multi-phasic production of ROS, highlighting informative time points for cell-specific HoxB7-RiboTRAP RNA-seq analysis. In turn, this approach guided our transcriptomics time point selection and RNA-seq analysis revealed key transcriptional responses that regulated the function of mitochondria and generated ROS, in particular, we identified downregulation of mitochondrial complex I (Cx1). Mitochondrial dysregulation is likely to be a critical mechanism for collecting duct injury because the IRI phenotype was ameliorated with a single bolus of a mitochondrial antioxidant (MitoTEMPO), which significantly reduced acute lipid peroxidation and decreased the expression of the kidney injury biomarkers Ngal and Kim1 (which may secondarily reflect collecting duct dysfunction). In sum, H2O2 generation, lipid peroxidation, biomarkers of injury and cytokine expression all correlated with, and were dependent on ROS generation in the collecting duct.
Liberated iron complexes from mitochondria, necrotized cells and erythrocytes make ROS which subsequently oxidize cellular lipid and lipid released from necrotic tissue. Furthermore, mitochondria are a dominant source of cellular ROS31 and thus likely a critical driver of IRI, in the collecting duct where mitochondria are abundant. MitoTEMPO as an antioxidant of the extracellular space may also play a role in the reduction of the observed lipid peroxidation of the kidneys. In this case, it is likely that mitoTEMPO is suppressing extracellular ROS activity due to liberated iron complexes from necrotized cells and erythrocytes. These ROS species are suppressed by the antioxidant activity of MitoTEMPO in the extracellular space and the reduction of the collecting duct kidney injury reporter and iron-scavenger LCN2 is reduced. In addition, the reduction of Kim1 expression, a proximal tubule injury reporter, indicates that kidney injury as a whole was reduced in the MitoTEMPO condition. These data support our previous findings that LCN2 can operates as an iron scavenger in aseptic conditions and is a sensitive reporter of kidney injury15,33.
Differences between collecting duct and proximal tubule response to IRI was apparent in our studies. The collecting duct ROS reporter and biomarker expression were dose responsive; 30 min of ischemia resulted in a larger signal than 15 min. Expression of the collecting duct injury marker Lcn2 and the distal nephron injury marker Tacstd2 were also dose responsive. In contrast, the proximal tubule showed maximal ROS signal responsiveness after 15 min of ischemia; doubling the ischemia time did not further increase the response. This result is consistent with the expression of the proximal tubule-specific injury biomarker Kim1 which is higher following 15 min of IRI than 30 min (Supplementary Fig. 9). ROS are generated by multiple mechanisms in vivo and have multiple functions and toxicities. ROS can be generated both by released heme, for example from necrotically damaged cells and mitochondria, and by a genetic program that alters mitochondrial function as well as altered expression of the extracellular peroxide pumps, the NOX complexes. ROS also act as signals of injury and an antipathogen function. Our transcriptomics data are consistent with the hypothesis that the collecting duct is actively generating ROS as part of its injury response. For example, the changes in expression of Cx1, and NOX suggest that collecting duct cells are actively generating increased ROS, perhaps as a component of their barrier function to inhibit bacterial growth or as a component of an injury signaling system. Consistent with this observation, we have shown collecting duct cells in response to a urinary tract infection also decrease the urinary pH and increase expression of the iron scavenger LCN2 (Paragas et al., JCI)32.
Alternatively, the threshold effect for activation of the collecting duct may be due to a robust antioxidant scavenging system that requires 30 min of ischemia to achieve saturation before demonstrating lipid peroxidation and log order increases in tissue-specific H2O2 generation. Conversely, it may be that apoptosis, necrosis and/or cellular dysfunction of proximal tubule cells50 results in saturation of its dynamic range to generate H2O2 and Kim1 at higher levels of IRI whereas the collecting duct, in contrast, is not subject to cell death and instead responds in a dose-responsive manner to a greater range of IRI injury15. This model solves a long-standing debate as to the timing of which segment is affected in AKI and is consistent with previous findings concerning the dose response of collecting duct vs proximal tubule biomarkers in both mice and humans and to the varied histologic findings of different tubular segments in the AKI kidney51,52,53,54.
This study presents a new and powerful integrated framework to dynamically associate pathophysiological changes to transcriptional signals at the cellular level. However, it is only the glimpse into the kidney’s reaction to an acute injury, because the kidney has a great cellular heterogeneity and there are many different models of kidney injury to map. We used HB7R26Luc/+, Slc34a1R26Luc/+, and PodR26Luc/+ genetic models to map ROS activity in a subset of cells representing the cortex and medulla of the kidney. Clearly, there is a need to expand on this work and investigate the effect of different types of renal injury on the transcriptional responses of other segments of the nephron and distal tubule in order to discover common biomarkers and therapeutic targets in AKI.
In this paper we present an ‘image-guided omics’55 technology platform to monitor AKI progression through non-destructive tools. Our approach provides a system to temporally study kidney injury, gives insight into how the kidney utilizes endogenous mechanisms to regulate injury pathways, and allows testing and discovery of novel therapeutic interventions targeting ROS signaling pathways. Our system is a cell-specific, longitudinal, non-destructive, and non-invasive method to study of ROS dynamics using PC-luciferin in a novel application1. In contrast, other imaging systems such as multiphoton microscopy56 permit imaging only at a depth of a few millimeters from the lens, which limits visualization of the medulla. Further, they require animal surgery during the data acquisition phase, which may contribute to marked variability in the findings and they do not allow longitudinal monitoring over hours because of repetitive stress on the animal. Our non-invasive system is a log order more sensitive compared with traditional methods of ROS measurements by MDA.
LCN2 from the thick ascending limb and the collecting duct presaged the idea that these compartments respond to IRI15, here we visualized the collecting duct response in real-time and demonstrated that underlying mitochondrial genes are important components of this pathologic readout. In addition, we found that damage biomarkers correlated with the time course of ROS rather than the time course of serum creatinine, again highlighting the distinction between gross functional changes and segment specific molecular mechanisms. However, our findings have wider clinical implications beyond the kidney since application of these novel tools can help identify and test therapeutics targeting oxidative stress in many cell types spanning different organs. In each of these applications, the proposed luciferase system can be scaled to assess multiple physiological readouts, enabling the identification of meaningful disease endotypes within complex disorders (such as AKI) based on spatiotemporal functional mapping of distinct pathophysiologic and molecular events.
ROSA26 L-S-L-Luc/+[FVB.129S6(B6)-Gt(ROSA)26Sortm1(Luc)Kael/J, 005125] mice were bred with Aqp2-Cre [B6.Cg-Tg(Aqp2-cre)1Dek/J, 006881], EIIa-Cre [B6.FVB-Tg(EIIa-cre)C5379Lmgd/J, 003724], HoxB7-Cre [Tg(Hoxb7-cre)13Amc/J, 004692], Podocin-cre [B6.Cg-Tg(NPHS2-cre)295Lbh/J, 008205] obtained from Jackson Labs, Lcn2-Luciferase reporter from J.M.B., Slc34a1-CreER(T2) from A.K., and Gt(ROSA)26Sor-mCherry-Rpl10a from EMMA. Slc34a1-CreER(T2) expression is activated by tamoxifen administration. Briefly, tamoxifen was dissolved in filtered corn oil (20 mg/mL) at 37 °C and injected i.p. (100 mg/kg) every other day for 4 days using 8-week mice. After breeding the conditional luciferase expressers are known as EIIaR26Luc/+, PodR26Luc/+, Slc34a1R26Luc/+, HoxB7R26Luc/+, and Cdh5R26Luc/+. C57BL/6 (13 week) were obtained from Jackson Labs. Mice were single or group-housed on a 12∶12 light–dark cycle at 22 °C with food and water ad libatum. Ten- to sixteen-week-old male mice were used for all IRI experiments as previously published15. All animal studies were approved by and performed according to the guidelines approved by the Institutional Animal Care and Use Committee (IACUC) at University of Washington.
Cell-specific RiboTRAP animal
To determine gene expression in a single cell-type at a single time point during a AKI we bred the Gt(ROSA)26Sor-mCherry-Rpl10a (mCherryTRAP) mouse that labels ribosomes for immunoprecipitation isolation of RNA with a tissue-specific Cre-recombinase mouse57. HoxB7-Cre (HoxB7TRAP/+) was used to label ribosomes in the collecting duct. This strategy relies on Cre-recombinase dependent activation of a mCherry-Rpl10a ribosomal protein subunit, which allows translating ribosome affinity purification (TRAP) of mRNA populations in Cre-expressing cells. Immunostaining of RPL-mCherry and immune-precipitated RNAs demonstrated specific enrichment of HoxB7TRAP/+ (CD) populations by confocal microscopy and qPCR (Fig. S7).
Purification of mRNA from tissue mCherry/TRAP mice
Kidneys from RiboTRAP mice were harvested, flash-frozen in liquid nitrogen and stored in −80 °C until homogenization. Frozen kidneys were homogenized and the lysate was added to Anti-RFP magnetic beads (MBL International, WA) and mCherry/TRAP bound beads were separated from the supernatant with a magnet (Fig. 4). RNA was eluted and purified using RNeasy Micro Kit (Qiagen) according to the manufacturer’s instructions. RNA integrity number (RIN) was measured using the Agilent 2200 TapeStation (Agilent Technologies, TX) and only samples with a RIN than or equal to 6.8 was used. qPCR was used to validate relative enhancement of tissue-specific genes of the collecting duct (Aqp2).
HiSeqLibrary was generated with 950 ng of mRNA using Illumina’s TruSeq RNA with Ribo-Zero protocol (Illumina, CA). RNA-seq (Illumina HiSeq) was performed at UW Cystic Fibrosis Genomics Core Center, followed by image analysis and base calling with Illumina’s RTA (v1.18) software. Demultiplexing and FASTQ format file generation and alignment was performed using HiSeq analysis software (TopHat v2.1.1) with UCSC mouse genome build mm10. Quality control was then performed with RNA-SeQC v1.1.8 and counts generated using HTSeq-counts v0.7.2. Differential gene expression between IRI and sham conditions was determined using DESeq2 package in R environment58 using a false discovery rate (FDR) cutoff <0.01. Functional enrichment of differentially expressed genes was performed using Webgestalt program59 and was based on pathways and processes from multiple resources, including KEGG, Reactome, and Gene Ontology (GO). An enrichment FDR < 0.01 was used to designate significant overrepresentation of functional categories and pathways.
Kidney ischemia-reperfusion injury (IRI) model
The renal artery was clamped using vascular clamps for a period of 30 min according to an established model of warm IRI to induce ischemic acute renal failure15. Briefly, 10–16-week-old male mice were anesthetized with gas anesthesia (isoflurane). The body temperature was maintained at 37 °C throughout the procedure. Kidneys renal pedicles were clamped for 30 min using nontraumatic microaneurysm clips (Fine Science Tools). Restoration of blood flow was monitored before closing incisions with surgical staples. Sham-operated mice underwent the same procedure except for clamping of the arteries. MitoTEMPO (Sigma) was suspended in sterile saline to 2.5 mg/ml and given s.q. immediately prior to IRI surgery.
In vivo animal imaging: An IVIS Spectrum instrument (PerkinElmer) was used for bioluminescent imaging in all animal experiments. Mice were anesthetized prior to injection and during imaging via inhalation of isoflurane (Phoenix Pharmaceuticals, Inc.) mixed with medical-grade oxygen (Praxair). Validation of luciferase expression was done using the potassium salt of D-luciferin (PerkinElmer) resuspended in PBS from ThermoFisher Scientific and injected i.p. (150 mg Luciferin/kg body weight).
Image data analysis
Planar bioluminescent images were quantified using LivingImage (PerkinElmer) software and tomographic bioluminescent images with InVivoAX (InVivo Analytics, Inc.) software. For kinetic image analysis of caged-luciferin with LivingImage, bioluminescent kidney radiance (photons s−1 cm−2 sr−1) was measured by manually drawing two equally sized circular ROIs (1 cm in diameter) over both the left and right kidney. Each kidney was treated as a separate data point. PC-Luciferin signal acquired in an untreated animal was used throughout the experiment as the baseline for delta change in radiance and as the denominator for fold-change calculations. The delta in total photon flux for each condition was calculated by dividing the total photon flux for the experimental condition by the total photon flux for the pre-IRI alone to allow a direct comparison between various kidney-specific luciferase reporter animals. Kinetic curves of HoxB7-luciferase, Slc34a1-luciferase and Pod-luciferase calculated with images acquired every 3 min (n = 20) starting 1 min post D-luciferin injection.
Bioluminescent tomographic reconstruction
Animals placed body conforming animal mold (InVivo Analytics, Inc.) and multi-view multi-spectral image acquired with the InVivoPLOT mirror-gantry. Multi-view multi-spectral images were reconstructed using InVivoAX (InVivo Analytics, Inc.) cloud-based software and aligned to digital mouse atlas. Photon image density was determined using InVivoAX (InVivo Analytics, Inc.) software. The source density is the amount of emitted photons per unit volume and time unit (photons cm−3 s−1). The relative source density method permits accurate and quantitative comparisons across all image data sets.
In vivo ROS monitoring
Mice were i.p. injected with PC-luciferin (0.5 μmol in PBS) as previously described in Van Bittner et al.1. Following injections, mice were imaged with an IVIS Spectrum for 1 h to capture the peak bioluminescent signal generated by uncaged PC-luciferin. PC-luciferin probe free acid was prepared according to published procedure1 starting from 6-hydroxybenzo[d]thiazole-2-carbonitrile (ABCR), 2-(4-(bromomethyl)phenyl)-4,4,5,5-tetramethyl-1,3,2-dioxaborolane (TCI), D-cysteine (ABCR). The product was purified by preparative HPLC (RP silica with a gradient over 10 min of 5–100% acetonitrile in water), converted into potassium salt by a reaction with potassium bicarbonate (Sigma Aldrich) in methanol–water 2:1 mixture, and finally lyophilized to give PC-luciferin as a white powder. The change in total photon flux for each condition was calculated by dividing the total photon flux for the experimental condition ROI by the total photon flux for PCL-1 pre-IRI condition ROI to allow a direct comparison between various kidney-specific luciferase reporter animals. Clearance of PCL-1 probe was determined by imaging E2a-Luciferase mice over 3 h with PC-luciferase (0.5 μmol in PBS). ROS activity and PC-Luciferin clearance monitored by response to hydrogen peroxide challenge (24 mM in 100 µl of PBS) before imaging and 2 h after first injection. Hydrogen peroxide challenge was consistent with work described in Van Bittner et al.1.
Real-time PCR analysis
Total RNA was isolated with Trizol (Invitrogen), quantified by NanoDrop Spectrophotometer and the first strand cDNA was synthesized using High-Capacity cDNA Reverse Transcription Kit (Applied Biosystems). Real-time PCR was performed to quantify Ngal/Lcn2 (Mm.PT.58.10167155), Kim1/Havcr1 (Mm.PT.58.31303329), Hmox1 (Mm.PT.58.8600055), IL1a (Mm.PT.58.32778767), IL18 (Mm.PT.58.42776691), Umod (Mm.PT.58.7038212), Clu (Mm.PT.58.11183004), Egf (Mm.PT.58.6246680), Gsta4 (Mm.PT.58.17030386), Hspa1b (Mm.PT.58.31570020.g), Spp1 (Mm.PT.58.43709208), Vegfa (Mm.PT.58.14200306), Hif1a (Mm.PT.58.11211292), Tnf (Mm.PT.58.12575861), Mx1 (Mm.PT.58.12101853.g), IL1b (Mm.PT.58.41616450), IL6 (Mm.PT.58.10005566), C3 (Mm.PT.58.17325540), C1q (Mm.PT.58.7482171), Ifit1 (Mm.PT.58.32674307), and bACT (Mm.PT.39a.22214843.g) mRNA expression in a LightCycler 96 (Roche) qPCR system with PrimeTime® Gene Expression Master Mix (IDT) and probe-based PrimeTime® qPCR Assays (IDT). β-actin was quantified as the housekeeping gene. The 2ΔΔCT method was used to calculated fold amplification of transcripts.
Measurement of lipid peroxides
The levels of lipid peroxides (LPOs) in each kidney were determined by measuring malondialdehyde (MDA) content using the TBARS (TCA Method) Assay Kit (Cayman Chemical Company) according to manufacturer’s instruction. Briefly, fresh kidney was bisected (other half used for qPCR) and homogenized in RIPA buffer (Alfa Aesar) containing protease inhibitor (cOmplete, Mini, Roche) at a ratio of 25 mg of tissue in 250 µl of RIPA buffer. Half of left and right kidney was processed for each mouse. The tissue was homogenized on ice using glass dounce, centrifuged at 1600 × g for 10 min at 4 °C, and the supernatant was used for both the MDA and protein analyses. Absorbance was read at 535 nm and calculated using the derived standard curve. Protein levels were measured using a Qubit Protein Assay Kit (ThermoFisher Scientific) according to manufacturer’s instruction. MDA was normalized in each sample in relation to total protein concentration and data are presented at nmol MDA/mg protein.
Heparinized blood was analyzed using the clinical blood analyzer iStat (Abbott). The Crea and the EC8 + cartridges were used for creatinine and Na, K, Glu, pH, PCO2, BUN/Urea, Hct, HCO3, TCO2, BE, AnGap, and Hb, respectively.
Statistics and reproducibility
Data were presented as mean ± SEM. GraphPad Prism software, version 6.0c (GraphPad Software Inc., San Diego, CA) was used for statistical analyses. Repeated measures one-way ANOVA with Dunnett’s multiple comparisons test was used to compare the luminescence data. One-way ANOVA with Dunnett’s multiple comparisons test or two-way ANOVA with Tukey’s multiple comparisons test was used to compare BUN, creatinine and MDA levels. One-way ANOVA with Dunnett’s multiple comparisons test or two-way ANOVA with Tukey’s multiple comparisons test was used to compare qPCR. P-value < 0.05 was considered a statistically significant difference.
Further information on research design is available in the Nature Research Reporting Summary linked to this article.
Sequence data that support the findings of this study have been deposited in the Gene Expression Omnibus (GEO) with the primary accession code GSE133184. All other data can be obtained from the corresponding author upon request.
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This work was supported by a kind gift from Bill and June Boeing and the Aldara Foundation, startup funding from the University of Washington School of Medicine and Division of Nephrology, the National Institutes of Health (NIH)/National Institute of Diabetes and Digestive and Kidney Diseases (NIDDK) grant DK094873 and pilot awards DK017047 and DK89507.
N.P. and A.D.K. are co-founders and shareholders of InVivo Analytics, Inc. The remaining authors declare no competing interests.
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Miyazaki, T., Gharib, S.A., Hsu, YW.A. et al. Cell-specific image-guided transcriptomics identifies complex injuries caused by ischemic acute kidney injury in mice. Commun Biol 2, 326 (2019). https://doi.org/10.1038/s42003-019-0571-7
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