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Lipopolysaccharide induces filtrate leakage from renal tubular lumina into the interstitial space via a proximal tubular Toll-like receptor 4–dependent pathway and limits sensitivity to fluid therapy in mice

2019; Elsevier BV; Volume: 97; Issue: 5 Linguagem: Inglês

10.1016/j.kint.2019.11.024

1523-1755

Daisuke Nakano, Kento Kitada, Ningning Wan, Xiaoyan Zhang, Helge Wiig, Wararat Kittikulsuth, Motoko Yanagita, Syann Lee, Lin Jia, Jens Titze, Akira Nishiyama,

Traumatic Brain Injury and Neurovascular Disturbances

Sustained oliguria during fluid resuscitation represents a perplexing problem in patients undergoing therapy for septic acute kidney injury. Here, we tested whether lipopolysaccharide induces filtrate leakage from the proximal tubular lumen into the interstitium, thus disturbing the recovery of urine output during therapy, such as fluid resuscitation, aiming to restore the glomerular filtration rate. Intravital imaging of the tubular flow rate in the proximal tubules in mice showed that lipopolysaccharide did not change the inflow rate of proximal tubule filtrate, reflecting an unchanged glomerular filtration rate, but significantly reduced the outflow rate, resulting in oliguria. Lipopolysaccharide disrupted tight junctions in proximal tubules and induced both paracellular leakage of filtered molecules and interstitial accumulation of extracellular fluid. These changes were diminished by conditional knockout of Toll-like receptor 4 in the proximal tubules. Importantly, these conditional knockout mice showed increased sensitivity to fluid resuscitation and attenuated acute kidney injury. Thus, lipopolysaccharide induced paracellular leakage of filtrate into the interstitium via a Toll-like receptor 4-dependent mechanism in the proximal tubules of endotoxemic mice. Hence, this leakage might diminish the efficacy of fluid resuscitation aiming to maintain renal hemodynamics and glomerular filtration rate. Sustained oliguria during fluid resuscitation represents a perplexing problem in patients undergoing therapy for septic acute kidney injury. Here, we tested whether lipopolysaccharide induces filtrate leakage from the proximal tubular lumen into the interstitium, thus disturbing the recovery of urine output during therapy, such as fluid resuscitation, aiming to restore the glomerular filtration rate. Intravital imaging of the tubular flow rate in the proximal tubules in mice showed that lipopolysaccharide did not change the inflow rate of proximal tubule filtrate, reflecting an unchanged glomerular filtration rate, but significantly reduced the outflow rate, resulting in oliguria. Lipopolysaccharide disrupted tight junctions in proximal tubules and induced both paracellular leakage of filtered molecules and interstitial accumulation of extracellular fluid. These changes were diminished by conditional knockout of Toll-like receptor 4 in the proximal tubules. Importantly, these conditional knockout mice showed increased sensitivity to fluid resuscitation and attenuated acute kidney injury. Thus, lipopolysaccharide induced paracellular leakage of filtrate into the interstitium via a Toll-like receptor 4-dependent mechanism in the proximal tubules of endotoxemic mice. Hence, this leakage might diminish the efficacy of fluid resuscitation aiming to maintain renal hemodynamics and glomerular filtration rate. see commentary on page 847 see commentary on page 847 Translational StatementUsing a mouse model of acute kidney injury, our results suggest that leakage of filtrate at the proximal tubules could be a cause of sustained oliguria during fluid resuscitation. The proximal tubular flow rate and urine volume at a normal glomerular filtration rate were reduced in lipopolysaccharide-injected endotoxemic mice, indicating that the filtrate diffused into the interstitium at the proximal tubules. Additional volume load did not alleviate oliguria under these conditions because the increased filtrate simply leaked at the tubules. Targeting this leakage may improve the efficacy of fluid therapy during endotoxemic acute kidney injury. Using a mouse model of acute kidney injury, our results suggest that leakage of filtrate at the proximal tubules could be a cause of sustained oliguria during fluid resuscitation. The proximal tubular flow rate and urine volume at a normal glomerular filtration rate were reduced in lipopolysaccharide-injected endotoxemic mice, indicating that the filtrate diffused into the interstitium at the proximal tubules. Additional volume load did not alleviate oliguria under these conditions because the increased filtrate simply leaked at the tubules. Targeting this leakage may improve the efficacy of fluid therapy during endotoxemic acute kidney injury. Oliguria in septic acute kidney injury (AKI) is thought to be caused by glomerular filtration rate (GFR) reductions induced by hypoperfusion or vascular dehydration. However, fluid resuscitation and treatment with additional vasoactive agents to maintain renal hemodynamics frequently fail to restore urine output. The mechanism by which urine output starts declining or becomes unresponsive to the therapy maintaining renal circulation during AKI has not been elucidated. In 1929, the medical literature first reported that phenolsulfonphthalein, a freely filtered dye, disappeared from the kidney tubular lumen of frogs in mercury-induced renal failure.1Richards A.N. Direct observations of change in function of the renal tubule caused by certain poisons.Trans Assoc Am Physicians. 1929; 44: 64Google Scholar More than 43 years later, Bank et al.2Bank N. Mutz B.F. Aynedjian H.S. The role of "leakage" of tubular fluid in anuria due to mercury poisoning.J Clin Invest. 1967; 46: 695-704Crossref PubMed Scopus (102) Google Scholar elegantly demonstrated (using a micropuncture method in combination with intravital imaging) that lissamine green, another freely filtered dye injected i.v., also disappeared from the proximal tubular lumen, whereas GFR (measured by inulin clearance in each segment) was maintained within the normal range in rats with mercury-induced renal injury. In 2015, we reported that lipopolysaccharide (LPS) accumulated in the proximal tubular wall in mice and induced a reduced tubular flow rate, but not GFR; this was visualized using freely filtered dyes such as Lucifer yellow and fluorescein isothiocyanate-inulin using multiphoton microscopy analysis.3Nakano D. Doi K. Kitamura H. et al.Reduction of tubular flow rate as a mechanism of oliguria in the early phase of endotoxemia revealed by intravital imaging.J Am Soc Nephrol. 2015; 26: 3035-3044Crossref PubMed Scopus (36) Google Scholar All these findings indicate a fluid "disappearance" from the proximal tubules that could cause oliguria independent of GFR reduction during AKI. Because in previous studies4Good D.W. George T. Watts III, B.A. Lipopolysaccharide directly alters renal tubule transport through distinct TLR4-dependent pathways in basolateral and apical membranes.Am J Physiol Renal Physiol. 2009; 297: F866-F874Crossref PubMed Scopus (58) Google Scholar,5Schmidt C. Hocherl K. Schweda F. et al.Regulation of renal sodium transporters during severe inflammation.J Am Soc Nephrol. 2007; 18: 1072-1083Crossref PubMed Scopus (129) Google Scholar it was found that mercury and LPS downregulated electrolyte reabsorption through intracellular transporter pathways, we hypothesized that both a slowed tubular flow rate and oliguria occurred from leakage of tubular flow through a paracellular pathway in the proximal tubules. Furthermore, we hypothesized that this leakage at the proximal tubules created the poor efficacy of fluid therapy, even if the GFR was adjusted. Finally, because we previously observed that tubular flow decreased specifically in the proximal tubules that accumulated fluorophore-conjugated LPS, we further examined whether Toll-like receptor 4 (TLR4), an LPS receptor expressed in proximal tubules, was responsible for the reduced tubular flow rate. There was no statistically significant difference in the urine outputs at 0 and 6 hours after LPS injection (5 or 15 mg/kg) (Figure 1a). LPS injection at both doses led to reduced urine output between 6 and 12 hours after injection compared with saline injection. In mice injected with LPS at 5 mg/kg, the difference in oliguria between 12 and 24 hours after injection was less than that between 6 and 12 hours after injection, whereas mice that received LPS at 15 mg/kg showed sustained oliguria, regardless of the time elapsed. Intravital imaging by 2-photon microscopy showed that tubules maintained their lumina (central black areas in blue tubules, Figure 1b) at 6 hours after injection of LPS at 5 mg/kg. In contrast, tubules showed shrunken tubular lumina at 6 hours after LPS injection at 15 mg/kg (Figure 1b). These results suggest that injection of LPS at 15 mg/kg reduced the GFR and the tubular flow rate, whereas LPS injection at 5 mg/kg allowed the GFR to remain at a level sufficient to maintain tubular lumen volume 6 hours after injection. We then evaluated the inflow and outflow rates of tubular flow in the early segments of the proximal tubules via i.v. bolus injections of Lucifer yellow, a dye freely filtered from glomeruli, to estimate the GFR and washout of tubular flow from the proximal tubules to the downstream nephron, respectively (Figure 1c).3Nakano D. Doi K. Kitamura H. et al.Reduction of tubular flow rate as a mechanism of oliguria in the early phase of endotoxemia revealed by intravital imaging.J Am Soc Nephrol. 2015; 26: 3035-3044Crossref PubMed Scopus (36) Google Scholar,6Kitamura H. Nakano D. Sawanobori Y. et al.Guanylyl cyclase A in both renal proximal tubular and vascular endothelial cells protects the kidney against acute injury in rodent experimental endotoxemia models.Anesthesiology. 2018; 129: 296-310Crossref PubMed Scopus (8) Google Scholar Injection of LPS at 5 mg/kg did not significantly change the inflow time, suggesting that the GFR was maintained at a normal level. In contrast, the outflow time was significantly extended compared with that of the saline-injected mice, indicating that the tubular flow rate was reduced at the proximal tubules, as we previously reported.3Nakano D. Doi K. Kitamura H. et al.Reduction of tubular flow rate as a mechanism of oliguria in the early phase of endotoxemia revealed by intravital imaging.J Am Soc Nephrol. 2015; 26: 3035-3044Crossref PubMed Scopus (36) Google Scholar Injection of LPS at 15 mg/kg significantly extended both inflow and outflow times, indicating reduced GFR. In all subsequent experiments, LPS was injected at 5 mg/kg unless otherwise indicated. Factors that reduce the proximal tubular flow rate are increases in sodium and water reabsorption or paracellular water transport or leakage. Because previous studies have shown that LPS reduced, rather than increased, the expression levels of Na+/H+ exchanger 3, a major sodium transporter in proximal tubules,5Schmidt C. Hocherl K. Schweda F. et al.Regulation of renal sodium transporters during severe inflammation.J Am Soc Nephrol. 2007; 18: 1072-1083Crossref PubMed Scopus (129) Google Scholar we focused on paracellular leakage as a potential cause of the slowed tubular flow rate. We first attempted to find direct evidence of paracellular leakage using intravital imaging. We assessed the fluorescein isothiocyanate-inulin–derived fluorescence between the proximal tubular cells (Figure 2a), while visible detection was very occasional because of the physical spatial limitations in cell–cell junctions compared with the spatial resolution of microscopy, in addition to quick washout in the interstitium. Indeed, either fluorescein isothiocyanate-inulin or Lucifer yellow infused in the subcapsular space (interstitium) was not visibly detectable in the interstitium/capillary area, and appeared in the tubular lumen >1 minute later (Supplementary Movie S1); this suggests that the injected Lucifer yellow was cleared from the interstitium into the venous blood, returned to the systemic circulation, filtered from the glomeruli, and then condensed in the tubular lumen, making the fluorescent level visible. To support the paracellular leakage hypothesis, we analyzed the expression of the renal tight junction components. LPS reduced occludin expression at the mRNA and protein levels in the kidney 6 hours after injection (Figure 2b and Supplementary Figure S1) and also reduced claudin 2 mRNA level but not protein level (Figure 2c and Supplementary Figure S1). Immunohistochemical staining of claudin 2 revealed that its localization was disrupted by LPS within 6 hours (Figure 2d). In cultured proximal tubular cells, LPS increased the permeability of Lucifer yellow through the tubular cell layer (Figure 2e) and reduced the continuity of Zonula occludens-1 (ZO-1) expression at cell–cell junctions and claudin 2 mRNA level after 6 hours of LPS incubation (Figure 2f and Supplementary Figure S2). The leakage of filtrate through proximal tubular cells during oliguria was predicted to cause fluid accumulation in the kidney. Indeed, LPS increased the wet kidney weight/body weight ratio, water content/dry kidney weight ratio, Na+ content/dry kidney weight ratio, and Na+/K+ ratio (Figure 3a). The increased Na+/K+ ratio indicated that there was a greater increase in extracellular fluid than in intracellular fluid after LPS injection, although LPS is supposed to increase the total number of cells in the kidney because of inflammatory cell infiltration. Furthermore, renal interstitial hydrostatic pressure was increased by LPS (Figure 3b). These results demonstrated that LPS increased extracellular fluid accumulation in the renal interstitium (Figure 3c). Tubular flow rate analysis using 2-photon microscopy provided information on the time needed for the tubular fluid to flow into the distal superficial nephron.3Nakano D. Doi K. Kitamura H. et al.Reduction of tubular flow rate as a mechanism of oliguria in the early phase of endotoxemia revealed by intravital imaging.J Am Soc Nephrol. 2015; 26: 3035-3044Crossref PubMed Scopus (36) Google Scholar,6Kitamura H. Nakano D. Sawanobori Y. et al.Guanylyl cyclase A in both renal proximal tubular and vascular endothelial cells protects the kidney against acute injury in rodent experimental endotoxemia models.Anesthesiology. 2018; 129: 296-310Crossref PubMed Scopus (8) Google Scholar We noted that 2-photon microscopy was unable to visualize changes deeper in the nephron. However, we presumed that leakage occurred mainly in the cortical proximal tubules because Na+ and water levels increased at similar rates, resulting in isotonic fluid accumulation (Supplementary Figure S3). Moreover, using the 2-photon microscopy technique, we previously reported that fluorophore-conjugated LPS accumulated in the proximal tubules of mice, and that only the tubular flow rate slowed in the LPS-accumulated tubules. We therefore conditionally knocked out (KO) TLR4 in the proximal tubules in Ndrg1CreERT2 mice (Supplementary Figure S4).7Endo T. Nakamura J. Sato Y. et al.Exploring the origin and limitations of kidney regeneration.J Pathol. 2015; 236: 251-263Crossref PubMed Scopus (50) Google Scholar LPS slowed the tubular flow in control TLR4-floxed mice at 6 hours, and proximal tubular TLR4 deletion remarkably suppressed this tubular flow rate reduction (Figure 4a). These results were accompanied by changes in urine volume for 6 hours (Figure 4b) and water accumulation in the kidney (Figure 4c). LPS reduced occludin protein levels in control TLR4-floxed mice but not in proximal tubular TLR4-KO mice at 6 hours (Figure 4d and Supplementary Figure S5). LPS had no effect on claudin 2 protein levels at 6 hours, but did disrupt its localization in control TLR4-floxed mice (Figure 4e and Supplementary Figure S5), whereas proximal tubular TLR4-KO mice maintained their claudin 2 expression pattern. The TLR4 inhibitor C34 prevented the LPS-induced tubular flow rate reduction by pre-LPS (at −1 hour) but not post-LPS (at 4 hours) treatment (Supplementary Figure S6) in normal C57Bl6 mice. C34 also prevented the increased permeability of Lucifer yellow and the disruption of ZO-1 continuity in the cultured proximal tubular cells (Figure 4f and g). Pharmacological inhibitors of nuclear factor κB and p38 MAP kinase attenuated the LPS-induced disruption of ZO-1 at 6 hours, but only the nuclear factor κB inhibitor suppressed it at 12 hours (Supplementary Figure S7). These results suggest that LPS induced filtrate leakage at the proximal tubules through a proximal tubular TLR4-dependent mechanism during early endotoxemia. Next, we examined whether proximal tubular TLR4 deletion rescued mice from LPS-induced AKI in a later phase of endotoxemia. When mice did not receive fluid resuscitation, there were no significant differences in urine output and blood urea nitrogen 24 hours after LPS injection between the control floxed and KO mice (Figure 5a). This may be because of the GFR reduction at this time point (Supplementary Figure S8); the presence of leakage at the proximal tubules does not impact urine output when the GFR is reduced (little fluid volume to be leaked). However, the KO mice, which did not show proximal tubular filtrate leakage, excreted more urine than the control mice in response to fluid resuscitation performed intermittently at 4 and 18 hours (50 ml/kg, subcutaneously) (Figure 5b). KO mice also showed significantly lower blood urea nitrogen, renal kidney injury molecule 1, and neutrophil gelatinase–associated lipocalin mRNA expression, but there was no significant difference in neutrophil gelatinase–associated lipocalin excretion in the urine, collected from 0 to 24 hours, between the groups (Figure 5c and d). The control floxed mice that excreted 18 hours after LPS).6Kitamura H. Nakano D. Sawanobori Y. et al.Guanylyl cyclase A in both renal proximal tubular and vascular endothelial cells protects the kidney against acute injury in rodent experimental endotoxemia models.Anesthesiology. 2018; 129: 296-310Crossref PubMed Scopus (8) Google Scholar The changes in renal inflammatory cytokine levels between the normal control and proximal tubular TLR4-KO mice did not achieve statistical significance, even though the KO mice experienced attenuated AKI. This may be due to the expression levels of TLR4 in the infiltrated inflammatory cells. Indeed, macrophages isolated from the kidneys of LPS-injected KO mice showed similar cytokine expression levels compared with control mice in the present study. These results indicate that renal inflammation involving nonproximal tubular cells occurred in both mouse strains with and without tubular flow leakage. AKI often causes coexisting damage in the respiratory system.12Doi K. Role of kidney injury in sepsis.J Intensive Care. 2016; 4: 17Crossref PubMed Scopus (64) Google Scholar,13Doi K. Ishizu T. Tsukamoto-Sumida M. et al.The high-mobility group protein B1-Toll-like receptor 4 pathway contributes to the acute lung injury induced by bilateral nephrectomy.Kidney Int. 2014; 86: 316-326Abstract Full Text Full Text PDF PubMed Scopus (49) Google Scholar The release of damage-associated proteins and inflammatory cells has been reported to ignite renal-pulmonary syndrome after bilateral nephrectomy13Doi K. Ishizu T. Tsukamoto-Sumida M. et al.The high-mobility group protein B1-Toll-like receptor 4 pathway contributes to the acute lung injury induced by bilateral nephrectomy.Kidney Int. 2014; 86: 316-326Abstract Full Text Full Text PDF PubMed Scopus (49) Google Scholar and ischemia/reperfusion injury14Andres-Hernando A. Okamura K. Bhargava R. et al.Circulating IL-6 upregulates IL-10 production in splenic CD4(+) T cells and limits acute kidney injury-induced lung inflammation.Kidney Int. 2017; 91: 1057-1069Abstract Full Text Full Text PDF PubMed Scopus (32) Google Scholar as models of kidney injury. The same study also showed that global TLR4-KO mice had attenuated renal-pulmonary syndrome.13Doi K. Ishizu T. Tsukamoto-Sumida M. et al.The high-mobility group protein B1-Toll-like receptor 4 pathway contributes to the acute lung injury induced by bilateral nephrectomy.Kidney Int. 2014; 86: 316-326Abstract Full Text Full Text PDF PubMed Scopus (49) Google Scholar Because deletion of TLR4 in the proximal tubules attenuated AKI in our study, we examined whether this proximal tubule–dependent protection prevented renal-pulmonary syndrome in LPS-injected mice with systemic inflammation. However, lung pro- and anti-inflammatory cytokine levels were not significantly affected by the proximal tubular TLR4 deletion. Inhibition of inflammatory cell TLR4, rather than tubular TLR4 or AKI, might be essential for preventing renal-pulmonary syndrome coexisting with sepsis. TLR4-dependent tight junction disruption has been reported in nonrenal cell types, including intestinal epithelial cells15Guo S. Nighot M. Al-Sadi R. et al.Lipopolysaccharide regulation of intestinal tight junction permeability is mediated by TLR4 signal transduction pathway activation of FAK and MyD88.J Immunol. 2015; 195: 4999-5010Crossref PubMed Scopus (234) Google Scholar,16Wardill H.R. Bowen J.M. Van Sebille Y.Z. et al.TLR4-dependent claudin-1 internalization and secretagogue-mediated chloride secretion regulate irinotecan-induced diarrhea.Mol Cancer Ther. 2016; 15: 2767-2779Crossref PubMed Scopus (32) Google Scholar and cholangiocytes,17Sheth P. Delos Santos N. Seth A. et al.Lipopolysaccharide disrupts tight junctions in cholangiocyte monolayers by a c-Src-, TLR4-, and LBP-dependent mechanism.Am J Physiol Gastrointest Liver Physiol. 2007; 293: G308-G318Crossref PubMed Scopus (108) Google Scholar and has been implicated in barrier dysfunction and leakage in these organs. In kidney tubules, leakage of filtrate results in stagnant tubular flow downstream and decreased shear stress. Apical shear stress has been shown to maintain proximal tubular morphology, including tight junction formation.18Duan Y. Gotoh N. Yan Q. et al.Shear-induced reorganization of renal proximal tubule cell actin cytoskeleton and apical junctional complexes.Proc Natl Acad Sci U S A. 2008; 105: 11418-11423Crossref PubMed Scopus (128) Google Scholar,19Ferrell N. Cheng J. Miao S. et al.Orbital shear stress regulates differentiation and barrier function of primary renal tubular epithelial cells.ASAIO J. 2018; 64: 766-772Crossref PubMed Scopus (16) Google Scholar In addition, secreted substances including inflammatory cytokines and exosomes can stagnate, concentrating in the tubular lumen and inducing a tubule–tubule network.20Kalakeche R. Hato T. Rhodes G. et al.Endotoxin uptake by S1 proximal tubular segment causes oxidative stress in the downstream S2 segment.J Am Soc Nephrol. 2011; 22: 1505-1516Crossref PubMed Scopus (116) Google Scholar Thus, TLR4 and reduced tubular flow might create a vicious cycle leading to further tight junction loss in downstream proximal tubules. El-Achkar et al.21El-Achkar T.M. Huang X. Plotkin Z. et al.Sepsis induces changes in the expression and distribution of Toll-like receptor 4 in the rat kidney.Am J Physiol Renal Physiol. 2006; 290: F1034-F1043Crossref PubMed Scopus (140) Google Scholar reported that TLR4 was expressed in other parts of the kidney, such as the glomeruli and distal tubules. Neither their study nor our previous study observed labeled LPS binding or accumulation in the distal tubules during endotoxemia.3Nakano D. Doi K. Kitamura H. et al.Reduction of tubular flow rate as a mechanism of oliguria in the early phase of endotoxemia revealed by intravital imaging.J Am Soc Nephrol. 2015; 26: 3035-3044Crossref PubMed Scopus (36) Google Scholar LPS in the glomeruli diminished the glomerular filtration barrier22Maeda K. Otomo K. Yoshida N. et al.CaMK4 compromises podocyte function in autoimmune and nonautoimmune kidney disease.J Clin Invest. 2018; 128: 3445-3459Crossref PubMed Scopus (52) Google Scholar and may affect the fluid filtration rate. However, the reduction in the tubular flow rate in the proximal tubules occurred immediately after LPS exposure (<2 hours) while the GFR was still preserved,3Nakano D. Doi K. Kitamura H. et al.Reduction of tubular flow rate as a mechanism of oliguria in the early phase of endotoxemia revealed by intravital imaging.J Am Soc Nephrol. 2015; 26: 3035-3044Crossref PubMed Scopus (36) Google Scholar and urine volume was almost normalized in proximal tubular TLR4-KO mice. We therefore presumed that the contribution of TLR4 to tubular flow in the other segments of the nephron was scarce, at least, in an early phase ( 1000-fold increase in fluorescence intensity (12-bit images) per second to the time of peak fluorescence intensity; outflow time was defined as the time elapsed from peak fluorescence intensity to half peak intensity. Inflow and outflow times were measured in 3 to 4 spatially separated tubular lumens in each imaging window that showed Lucifer yellow at a similar time point. Separate groups of mice were injected with LPS and euthanized 6 hours later. Their kidneys were removed, weighed, desiccated at 90 °C for 72 hours, and then reweighed (dry kidney weight). The kidneys were then ashed at 600 °C for 48 hours and the Na+ and K+ concentrations were measured by flame photometry (EFOX5053, Eppendorf, Germany). All values in the normal control group were normally distributed, whereas skewing was observed in the oliguric groups. The results were expressed as mean ± SEM. Statistical significance was assessed using 1-way analysis of variance followed by Tukey multiple comparison test. Means were compared between the 2 groups using Student t test. All statistical analyses were performed using GraphPad Prism 6 (GraphPad Software Inc., La Jolla, CA), with values of P < 0.05 considered statistically significant. All the authors declared no competing interests. This work was supported by the MIU Foundation, The Uehara Memorial Foundation, Next Generation Leading Research Fund for 2017 and 2018 of Kagawa University Research Promotion Program, and JSPS KAKENHI grants (grant nos. 15K08236 and 15KK0346) to DN. We gratefully acknowledge the use of services provided by the Vanderbilt Cell Imaging Shared Resource. We thank Yumi Sakane, Miho Seki, and Yuji Yokota from the Department of Pharmacology, Kagawa University (Kagawa, Japan) and Tetyana Pedchenko and Yan Zhao from the Division of Clinical Pharmacology, Vanderbilt University Medical Center (Nashville, TN) for technical assistance and for help in maintaining the mouse colony. We thank Katrina Krogh and Susan Furness from Edanz Group (www.edanzediting.com/ac) for editing drafts of this manuscript. DN contributed to the conception and design of the research, prepared figures, drafted the manuscript, and prepared funding; DN, KK, NW, KW, and YZ performed experiments and analyzed data; DN, KK, HW, KW, and JMT interpreted results of experiments; DN, KK, and HW edited and revised the manuscript; MY, SL, and LJ developed the transgenic mouse line; and DN and AN approved the final version of the manuscript. Download .pdf (.96 MB) Help with pdf files Supplementary File (PDF)eyJraWQiOiI4ZjUxYWNhY2IzYjhiNjNlNzFlYmIzYWFmYTU5NmZmYyIsImFsZyI6IlJTMjU2In0.eyJzdWIiOiI1YzQ5MzNlMjUwOTA5YjEyMTRiYjIwYTUzNGQ4NDdlMSIsImtpZCI6IjhmNTFhY2FjYjNiOGI2M2U3MWViYjNhYWZhNTk2ZmZjIiwiZXhwIjoxNjc5MjM0NTI0fQ.JDT2Q1w-Vnk1qOVCXm4nmVgkNaw4Tx5IYDR56k_bcC6B5g951RTiQrjkzCsvrxN-CX_vncSP10Kg48wXj-InIOG3b7rKXoGPV84WJnD4glcg-mBIZP3KDaQfG8ycAtdeLF0RuD-VdHHEzKc-tK82jGfuO2JbR-7IZ-50mCQIExU0LQl3gM3w__tQDOU33Cll345LMuebwWlw_E7o8EWgokJEjxydEZJtJiogF4w9g8xAJxviBY9_UvHPz85eRg7rmo8XHk-HGOw7E7tGmVunKsfaWw940FBZrJUxK6BLzXygjkNMaH9nLjrcaHZWGrt-tP82kzX_JM8VUrVdG865hw Download .mp4 (0.26 MB) Help with .mp4 files Supplementary File (Movie) Novel strategy for septic acute kidney injury rescue: maintenance of the tubular integrityKidney InternationalVol. 97Issue 5PreviewFluid resuscitation for oliguria rescue in septic acute kidney injury (AKI) has limited success. By examination of the proximal tubular integrity, Nakano et al. identified paracellular renal filtrate leakage in proximal tubules after lipopolysaccharide induced tight junction disruption to contribute to oliguria. Suppression of lipopolysaccharide injury to proximal tubules by Toll-like receptor 4 knockout significantly ameliorated the oliguria and renal function loss in septic AKI. This commentary discusses the new therapeutic strategy for septic AKI rescue by proximal tubular integrity protection and the potential impact of tight junction injury in all AKI conditions. Full-Text PDF