Abstract
Urinary markers for the assessment of kidney diseases in wild animals are limited, in part, due to the lack of urinary proteome data, especially for marine mammals. One of the most prevalent kidney diseases in marine mammals is caused by Leptospira interrogans, which is the second most common etiology linked to stranding of California sea lions (Zalophus californianus). Urine proteins from eleven sea lions with leptospirosis kidney disease and eight sea lions without leptospirosis or kidney disease were analyzed using shotgun proteomics. In total, 2694 protein groups were identified and 316 were differentially abundant between groups. Major urine proteins in sea lions were similar to major urine proteins in dogs and humans except for the preponderance of resistin, lysozyme C, and PDZ domain containing 1, which appear to be over-represented. Previously reported urine protein markers of kidney injury in humans and animals were also identified. Notably, neutrophil gelatinase-associated lipocalin, osteopontin, and epidermal fatty acid binding protein were elevated over 20-fold in the leptospirosis-infected sea lions. Consistent with leptospirosis infection in rodents, urinary proteins associated with the renin-angiotensin system were depressed, including neprilysin. This study represents a foundation from which to explore the clinical use of urinary protein markers in California sea lions.
- RAS
- renin-angiotensin system
- lepto
- leptospirosis
- SCr
- serum creatinine
- BUN
- blood urea nitrogen
Introduction
Leptospirosis, the disease caused by a bacterial infection with pathogenic species within the genus Leptospira, is the second most common reason for California sea lions (Zalophus californianus) to strand sick and dying along the California coast 1. It is the most common cause of renal compromise in sea lions. Sea lions with leptospirosis typically present with elevated serum creatinine (SCr) and blood urea nitrogen (BUN), hypernatremia and hyperphosphatemia, and, on histological examination, have multifocal, severe lymphoplasmocytic interstitial or tubulointerstitial nephritis which may vary from acute to chronic, and tubular epithelial necrosis 2-3. However recent studies indicate that some animals experience mild or subclinical infections with Leptospira4and serum correlates of renal function may fail to detect mild injury. For example, in a study of sea lions with detectable anti-Leptospira antibodies by microscopic agglutination testing (MAT), an indication of prior exposure and possibly current infection, elevated SCr or BUN was reported for only 57.6 % and 51.5 % of seropositive animals, respectively3. It remains unknown whether the animals without elevated values had recovered from initial renal compromise, never experienced compromise, or were experiencing renal compromise that was not being detected by these historical correlates of renal function. In a more recent study of leptospirosis infection in sea lions, both SCr and BUN have been shown to decline to normal range even though leptospires continued to be shed in the urine 4, and is consistent with the idea of maintenance hosts (chronic infection without clinical indicators of disease) 5-6.
The utility of SCr and BUN as filtration markers is known to be imperfect and cannot differentiate pre-renal azotemia from tubular injury. Serum creatinine changes can often lag behind renal injury by up to 48 h and in the chronic setting, secretion of creatinine or reduction in creatinine production can lead to the overestimation of renal function 7-13. Additionally, assessment of kidney damage in surveys of sea lions with no clinical history complicates diagnosis of mild renal injury because markers such as creatinine can vary with feeding status, hydration status, muscle mass, and assay bias in the presence of confounders such as bilirubin (as reviewed in 11). Furthermore, reference ranges based on age class and body mass can be difficult to validate with traditional renal clearance techniques, especially when sea lions undergo peripheral vasoconstriction in response to anesthesia14.
Assessment of renal injury using urine protein markers has been widely described for dogs, cats, livestock and humans15-16, with markers including urinary total protein, albumin, immunoglobulins, as well as more recent markers of tubular injury such as neutrophil gelatinase-associated lipocalin (NGAL; approved name lipocalin 2; approved symbol LCN2). To date urine protein markers have yet to be translated to marine mammal veterinary medicine for the monitoring of renal injury. In fact, it is unclear which proteins are excreted in the urine of marine mammals and whether kidney injury markers used to monitor kidney health in domestic animals are applicable to marine mammals. The purpose of this study was to explore the urinary proteome in wild California sea lions and to compare differences in the urinary proteome between sea lions with and without leptospirosis. Search methods included the use proteome databases of closely related species. These results highlight expected and potentially novel candidate urine protein markers of tubular interstitial nephritis across a spectrum of infection and may be useful in diagnosing more subtle renal disease in sea lions, regardless of the cause.
Experimental Section
Sea lions
Urine samples were collected from two groups of sea lions: sea lions (Lepto, n=11) that stranded along the California coast between 2011 and 2012 and were being treated for leptospirosis and for which Leptospira infection status was confirmed by detection of Leptospira DNA in urine or kidney tissue via PCR 17; and sea lions (Control, n=8) which were apparently healthy, free-ranging sea lions sampled along the coasts of California (n=3) and Oregon (n=5), and which had no evidence of current (i.e., negative urine Leptopira PCR results) or prior (i.e., no detectable anti-Leptospira antibodies via serum MAT) 18 Leptospira infection and no evidence of renal compromise via serum chemistry analysis. Samples from Lepto animals were collected under The Marine Mammal Center (TMMC; Sausalito, CA) National Oceanic Atmospheric Administration (NOAA)/National Marine Fisheries Service (NMFS) Stranding Agreement during the course of their routine clinical care and treatment at TMMC and from Control animals during the course of a study investigating Leptospira exposure in free-ranging sea lions (unpublished data) under NMFS Permit No. 17115-03 and NMFS Permit No. 16087. Serum samples were collected one to five days from admission to TMMC from Lepto animals and within 48 h of urine collection. Serum and urine were collected at the same time from Control animals. Urine was collected aseptically via free catch (Lepto n=1), cystocentesis (Lepto n=1; Control n=2) or urethral catheterization (Lepto n=5; Control n=6) (Table S5) while under isoflurane anesthesia, or via needle aspiration through the wall of the bladder during necropsy (Lepto n=4). Different urine collection methods were allowed to facilitate case-control matching of animals (Table 1). Urine was stored in 2 mL cryovials at −20 to −80 °C until further processing and analysis. Serum chemistry analyses of Lepto and Control serum samples were performed on an ACE® Clinical Chemistry System (Alfa Wassermann, Inc., West Caldwell, New Jersey, USA). Urine osmolality was determined using a Wescorp (Model 5100) vapor pressure osmometer. Total protein was determined using a microBCA assay. Urine creatinine was measured using a modified Jaffe method.
Trypsin digestion
Urines were thawed rapidly at 37 °C in a water bath and vortexed for 5 min prior to centrifugation at 3000 x gn for 30 s. Urine protein concentration was determined using the pyrogallol method (QuanTtest® Red, Total Protein Assay System, Quantimetrix Corp.). In Lo-Bind microcentrifuge tubes (Eppendorf), urine supernatant equal to 20 μg total protein was brought to a volume of 175 μL and spiked with 400 ng HIV GP80 as an internal standard to assess digestion. Proteins were sequentially digested with proteases LysC and Trypsin (Promega) following in-solution protocols with sodium deoxycholate as a detergent previously published 19. Briefly, sodium deoxycholate was added to the urine protein solution to a final volume fraction of 5 %. Proteins were reduced with dithiotretitol (final concentration 10 mmol/L) for 30 min at 60 °C and subsequently alkylated with iodoacetamide (final concentration 15 mmol/L) at room temperature in the dark for 30 min. Samples were diluted eight times by volume with 50 mmol/L ammonium bicarbonate, followed by addition of LysC protease at a 1:100 mass ratio (LysC:total protein), and the samples were incubated at 37 °C for 2 h. Trypsin was then added at a 1:20 mass ratio (trypsin:total protein) and incubated overnight at 37 °C. Trifluoroacetic acid (10 % volume fraction) was added to the sample to achieve a final volume fraction of 5% trifluoroacetic acid. The tryptic peptide solution underwent liquid:liquid extraction with water-saturated ethyl acetate and was repeated four times. The peptide containing bottom layer was dried under vacuum to reduce the final volume to approximately 200 μL in a Speedvac. One mL of 0.1 % formic acid (volume fraction) was added to the peptide solution, and peptides were extracted using solid phase cartridges (Strata-x, Phenomenex), then eluted in 40 % acetonitrile (volume fraction) in 0.1 % formic acid (volume fraction). Peptides were freeze-dried under vacuum and resuspended in 0.1 % formic acid (volume fraction) prior to separation and data acquisition by nanoLC-MS/MS.
Shotgun Proteomics (LC-MS/MS)
Peptide mixtures (approximately 1 μg) were analyzed using an UltiMate 3000 Nano LC coupled to a Fusion Lumos mass spectrometer (Thermo Fisher Scientific). Prior to analysis the sample order was randomized. Resulting peptide mixtures (10 μL) were loaded onto a PepMap 100 C18 trap column (75 μm id x 2 cm length; Thermo Fisher Scientific) at 3 μL/min for 10 min with 2 % acetonitrile (volume fraction) and 0.05% trifluoroacetic acid (volume fraction) followed by separation on an Acclaim PepMap RSLC 2 μm C18 column (75μm id x 25 cm length; Thermo Fisher Scientific) at 40°C. Peptides were separated along a 130 min gradient of 5 % to 27.5 % mobile phase B [80 % acetonitrile (volume fraction), 0.08 % formic acid (volume fraction)] over 105 min followed by a ramp to 40 % mobile phase B over 15 min and lastly to 95 % mobile phase B over 10 min at a flow rate of 300 nL/min. The Fusion Lumos was operated in positive polarity and data dependent mode (topN, 3 s cycle time) with a dynamic exclusion of 60 s (with 10 ppm error). Full scan resolution using the orbitrap was set at 120 000 and the mass range was set to 375 to 1500 m/z. Full scan ion target value was 4.0×105 allowing a maximum injection time of 50 ms. Monoisotopic peak determination was used, specifying peptides and an intensity threshold of 1.0×104 was used for precursor selection. Data-dependent fragmentation was performed using higher-energy collisional dissociation (HCD) at a normalized collision energy of 32 with quadrupole isolation at 0.7 m/z width. The fragment scan resolution using the orbitrap was set at 30 000, 110 m/z as the first mass, ion target value of 2.0×105and 60 ms maximum injection time.
Raw files were converted to peak lists in the mgf format using Proteome Discoverer (v2.0.0.802). These data were searched using the Mascot algorithm (v2.6.0; Matrix Science). The following databases specified within Mascot: Leptonychotes weddellii (Weddell seal), NCBI RefSeq Release 100, GCF_000349705.1_LepWed1.0, 25 718 sequences; Odobenus rosmarus divergens (Pacific walrus), NCBI RefSeq Release 101, GCF_000321225.1_Oros_1.0, 31 370 sequences; iRT peptide, 1 sequence; HIV envelope glycoprotein, 2 sequences (UniprotKB Q72502V and P04577V); and the common Repository of Adventitious Proteins database (cRAP; 2012.01.01; the Global Proteome Machine), 107 sequences. The following search parameters were used: trypsin was specified as the enzyme allowing for two mis-cleavages; carbamidomethyl (C) was fixed and deamidated (NQ) pyro-Glu (n-term Q), and oxidation (M) were variable modifications; 10 ppm precursor mass tolerance and 0.02 Da fragment ion tolerance; instrument type was specified as ESI-FTICR; the decoy setting was used within Mascot to provide local FDR. Mascot results were confirmed using Scaffold (v. 4.7.2; Proteome Software, Portland, OR, USA), with a minimum protein threshold of 1 % false discovery rate (FDR), and 1 % FDR at the peptide level. Experiment wide grouping was used which resulted in 2694 protein families identified at 0.9 % FDR (as determined by Mascot’s local FDR), after removal of cRAP and decoy hits. Weighted spectrum counts were exported from Scaffold for downstream analysis. In order to evaluate the differentially abundant proteins and proteins relevant to AKI and RAS pathways, these protein families were converted to a human equivalent protein with a HUGO Gene Nomenclature Committee (HGNC) gene symbol. This was based either on the NCBI RefSeq protein description exactly matching an HGNC description or on human sequence similarity search results via NCBI’s BLAST (Basic Local Alignment Search Tool). Although these names and symbols often align, there were four notable exceptions where the HGNC approved name and symbol have diverged from the common clinical name: KIM1 (kidney injury molecule 1; HGNC approved symbol HAVCR1), NGAL (neutrophil gelatinase-associated lipocalin; HGNC approved symbol LCN2), neprilysin (HGNC approved symbol MME), and osteopontin (HGNC approved symbol SPP1). Raw data, search results and databases have been deposited to the ProteomeXchange Consortium via the PRIDE20 partner repository with the dataset identifier PXD009019 and 10.6019/PXD009019.
Data analysis
For all analysis unless otherwise stated, Matlab (R2015a) was used. For differential analysis of proteomic data, a two-sided Wilcoxon rank sum test was utilized. False discovery rate for multiple hypothesis testing was estimated using the method of Benjamini and Hochberg (BH; 21). Differentially abundant proteins were defined as a BH corrected p-value < 0.05. Log2 fold-change values were calculated as the difference in log-average counts between groups (if average counts were 0, then half of the smallest group average was used, which was 0.0427). For display purposes only, a custom implementation of a membership function was used to normalize the weighted spectral counts to a value between 0 and 1 before clustering. These normalized values were used for hierarchical clustering with a Euclidean distance metric. Differences between clinical and demographic data were determined using a Mann-Whitney U test or Chi-Square. Groups were deemed different if p-value < 0.05. Gene ontology and pathway inference was generated by the Reactome Pathway Database 22. Protein accession numbers were converted to homologous human accession numbers for ontology and pathways analysis.
Results
Sea lion blood and urine chemistry
Sea lions with leptospirosis kidney disease, i.e., Lepto animals, displayed elevations in serum creatinine (SCr), blood urea nitrogen (BUN), plasma sodium (Na), plasma chloride (Cl), plasma potassium (K), and plasma phosphorus (P) (Table 1) compared to age and sex matched animals, characteristic of a renal disease phenotype. Measures of urine concentration (urine creatinine, urine osmolality, urine specific gravity, and urine creatinine/serum creatinine) were depressed in sea lions with leptospirosis consistent with tubular injury and a reduction in urine concentrating ability (Table 1). Renal injury in the Lepto group was also markedly depicted by the 15-fold elevation in mean urine protein concentration and 73-fold elevation in urine protein/urine creatinine ratio (Table 1). Twenty-four hour renal protein excretion was not measured.
Sea lion urine proteins
There were 2694 protein groups identified across the analysis, excluding contaminant proteins (Table S1). Proteins identified from sea lions in the Control group represented 1636 in total with a mean and standard deviation of 794 ± 162 proteins per individual. Proteins identified in the Lepto group represented 2235 in total, with a mean and standard deviation of 831 ± 408 proteins per individual. There was no difference between the number of proteins identified between groups (p > 0.8; Mann-Whitney U test).
For Control sea lions the most abundant protein in the urine as determined by spectral counting was albumin, followed by uromodulin and protein AMBP. Of the 34 most abundant proteins in sea lion urine (Figure 1), several ranked proteins were unexpected compared to a rank classification of relative abundance reported for the human urine proteome 23. Resistin was the 11th top ranked protein in sea lion urine; whereas, in humans resistin is ranked 414 23. Similarly, lysozyme C and PDZ domain containing 1 were found at a much lower rank (i.e., higher abundance) compared to normal human urine (human rank: 525 and 1002, respectively) and PDZ domain containing 1 was not reported in the supernatant of the dog urine proteome 24. Both resistin and lysozyme C belong to pathways involved in neutrophil degranulation as classified by the Reactome Knowledge Database 22.
Protein differences: Control versus Lepto
There were 316 proteins differentially abundant proteins between the control and leptospirosis groups (Benjamini-Hochberg corrected p < 0.05; Wilcoxon rank sum test). Of these, 98 proteins were elevated and 218 proteins reduced in the Lepto group compared to the Control group. (Figure 2, Table S1). Of these differential proteins, osteopontin (HGNC name: secreted phosphoprotein 1; HGNC gene symbol, SPP1) displayed the greatest positive log2-fold change (log2 FC) relative to the Control group (log2 FC, 8.28), and AXL receptor tyrosine kinase (HGNC gene symbol, AXL) displayed the greatest negative log2-fold change (log2FC, −7.46). Reactome overrepresentation analysis (Table S1) of positively changing proteins (Lepto versus Control) resulted in significant grouping within pathways: 1) Platelet degranulation, 2) Complement cascade, 3) Regulation of Insulin-like Growth Factor transport and uptake by Insulin-like Growth Factor Binding Proteins. Overrepresentation analysis of negative changing proteins (Lepto versus Control) resulted in significant grouping within pathways: 1) Post-translational protein phosphorylation, 2) Regulation of Insulin-like Growth Factor transport and uptake by Insulin-like Growth Factor Binding Proteins, 3) Molecules associated with elastic fibers, 4) Neutrophil degranulation.
Urinary protein markers of renal injury in sea lions
Select urine protein marker protein classes related to kidney injury in humans and domestic veterinary animals (primarily extracted from references within 15-16, 25) were clustered across samples to display the relationship of these markers with Lepto and Control sea lion groups (Figure 3 and Table S2). Notably, neutrophil gelatinase-associated lipocalin (NGAL; HGNC name, lipocalin 2; HGNC gene symbol LCN2), osteopontin (HGNC gene symbol SPP1), and epidermal-type fatty-acid binding protein (HGNC gene symbol FABP5) were elevated more than 20-fold (log2 FC, >4.3) over the Control group. Other previously reported markers of kidney injury that were elevated in the Lepto group include: clusterin (HGNC gene symbol CLU) and tissue inhibitor of matrix metalloproteinase 1 (HGNC symbol TIMP1).
The following urinary markers of kidney injury were reduced in the Lepto group compared to Control: uromodulin (HGNC gene symbol UMOD), gamma-glutamyltranspeptidase 1 (HGNC gene symbol GGT1), vanin 1 (HGNC gene symbol VNN1), insulin like growth factor binding protein 7 (HGNC gene symbol IGFBP7), and alanyl aminopeptidase (HGNC gene symbol ANPEP), and kidney injury molecule 1 (KIM1; HGNC name, hepatitis A virus cellular receptor 1; HGNC gene symbol HAVCR1).
The following urinary markers of renal injury were not differentially abundant between Control and Lepto groups: interleukin 18 (HGNC gene symbol IL18), beta-2-microglobulin (HGNC gene symbol B2M), liver type fatty acid binding protein (HGNC gene symbol FABP1), transferrin (HGNC gene symbol TF), albumin (HGNC gene symbol ALB), retinal binding protein 4 (HGNC gene symbol RBP4), cystatin C (HGNC gene symbol CST3), alkaline phosphatase (HGNC gene symbol ALPL), alpha-1-microglobulin (HGNC gene symbol AMBP), haptoglobin (HGNC gene symbol HP), tissue inhibitor of matrix metalloproteinase 2 (HGNC gene symbol, TIMP2), angiotensinogen (HGNC gene symbol AGT), N-acetyl-β-D-glucosaminidase (HGNC gene symbol HEXB), alpha glutathione-S-transferase (HGNC gene symbol GSTA3), glutathione S-transferase P-like (HGNC gene symbol, GSTP1), and epidermal growth factor (HGNC gene symbol EGF).
Putative renal injury markers not found in the results include: YKL-40 (HGNC gene symbol CHI3L1), C-reactive protein (HGNC gene symbol CRP), cysteine rich protein 61 (HGNC gene symbol CYR61), sodium/hydrogen exchanger 3 (HGNC gene symbol SLC9A3).
Renin-Angiotensin System
Based on a previous report 26, a reduction in polypeptide components of the renin-angiotensin system (RAS), e.g., neprilysin and angiotensin I, in rodents infected with Leptospira 26appear to be characteristic of the response to infection. For this reason, data associated with these RAS proteins were specifically extracted to determine whether a similar response was characteristic of large mammals presenting with a natural course of disease (Figure 4). The following RAS-related proteins were reduced in the Lepto group: neprilysin (HGNC gene symbol MME, −3.69 log2 FC), angiotensin converting enzyme 1 (HGNC gene symbol ACE, −3.46 log2 FC), angiotensin converting enzyme 2 (HGNC gene symbol ACE2, −2.50 log2 FC), glutamyl aminopeptidase (alternative name, aminopeptidase A; HGNC gene symbol ENPEP, −3.36 log2FC), alanyl aminopeptidase (alternative name, aminopeptidase N; HGNC gene symbol ANPEP, - 1.2 log2 FC), carboxypeptidase A1 (HGNC gene symbol CPA1, −2.62 log2 FC), cathepsin D (HGNC gene symbol CTSD, −0.8 log2 FC). The following RAS-related proteins were not differentially abundant between groups: angiotensinogen (HGNC gene symbol AGT), carboxypeptidase A2 (HGNC gene symbol CPA2), cathepsin B (HGNC gene symbol CTSB), aspartyl aminopeptidase (HGNC gene symbol DNPEP), prolyl endopeptidase (HGNC gene symbol PREP), dipeptidyl peptidase 3 (HGNC gene symbol DPP3), cathepsin G (HGNC gene symbol CTSG), renin receptor (HGNC gene symbol ATP6AP2). The following RAS-related proteins were not identified: renin (HGNC gene symbol REN), chymase (HGNC gene symbol CMA1), thimet oligopeptidase (HGNC gene symbol THOP1), and prolyl carboxypeptidase (HGNC gene symbol PRCP).
The reduction in the RAS enzyme, neprilysin (HGNC gene symbol MME), was validated using Western blotting (Figure 5). A single immunoreactive protein band was detected between 75 kDa and 100 kDa (predicted molecular weight 86 kDa). Densitometry of the band across individual sea lions indicated a significant reduction (p < 0.01, Mann-Whitney U test) in urinary neprilysin protein normalized either by total protein loaded on the gel (Figure 5B) or normalized per volume of urine (Figure 5C).
Natriuretic proteins
Leptospirosis associated with renal failure leads to a hypernatremic state in sea lions, therefore we extracted information regarding natriuretic proteins from the urine data for description. The following natriuretic proteins were identified: guanylin (HGNC gene symbol GUCA2A), uroguanylin (alternative name, guanylate cyclase activator 2B; HGNC gene symbol GUCA2B), C-type natriuretic peptide (HGNC gene symbol NPPC), natriuretic peptides A (HGNC gene symbol NPPA), and natriuretic peptides B (HGNC gene symbol NPPB). Only guanylin was significantly elevated in sea lions from the Lepto group.
Discussion
California sea lions excrete a urine similar in protein composition to other mammals 23-24,27, where proteins such as albumin, uromodulin, and protein AMBP dominate abundance (Figure 1, TableS1). Unlike rodents, where the urine is dominated by major urinary proteins 28, or cats, in which the urinary protein cauxin dominates the proteome 27; sea lions excrete a repertoire of proteins that closely parallels that of dogs. 24 and humans 23. Some features of the sea lion urinary proteome were unexpected such as the predominance of two low molecular weight proteins, resistin (12 kDa) and lysozyme C (16 kDa), as estimated by ranking proteins by spectral counts in Control group animals. Both proteins are elevated in immune cells either in response to lipopolysaccharide to promote inflammation 29 or in defense of elevated lipopolysaccharide to promote bacterial lysis 30, respectively. Over-abundance of these two innate immune system proteins may indicate elevated innate protection against pathogenic, considering likely constant environmental pathogen exposure in the wild.
Leptospirosis
In an effort to extend the utility of this study into veterinary diagnostics, e.g., discovery of candidate urine markers of interstitial nephritis, urine proteins from sea lions with leptospirosis kidney disease were included as a separate group. Sea lions in the leptospirosis (Lepto) group included in this study displayed a range of urine protein to creatinine ratios and SCr levels that may reflect a range of renal injury severity and chronicity. Sea lions accepted for rehabilitation are discovered during strand surveys or citizen reports, therefore the clinical history, and hence the duration of infection, is unknown. Inclusion of data from the Lepto group resulted in the identification of an additional 1058 proteins, providing a more comprehensive urine proteome picture which was derived from urine from sea lions experiencing severe renal compromise as well as from those with apparently healthy kidneys. Similar to urinary proteomic results from rats with chronic Leptospira infection 26, sea lions with leptospirosis had a larger proportion of urinary proteins that were reduced in abundance compared to uninfected sea lions. Despite significant proteinuria in the Lepto group, urinary albumin concentration was not different between groups based on weighted spectral counts. This is consistent with changes in proteinuria from tubular, not glomerular, origin as has been reported from dogs with leptospirosis 31.
Urinary proteins as markers of renal injury and repair continue to be extensively studied and evaluated for use as human clinical diagnostics and domestic veterinary diagnostics 15-16. Not surprising, marine mammal veterinary diagnostics have lagged behind these other fields. To test whether previously described renal injury markers for humans and domestic veterinary species change with renal injury status, a subset of proteins were extracted from the data based on their precedent as biomarkers of renal tubular injury (Figure 3). Neutrophil gelatinase-associated lipocalin (LCN2) and osteopontin (SPP1) were notably abundant in urine from the Lepto group. Both are considered tubular injury markers of acute kidney injury 25 and drug-mediated nephrotoxicosis 32. Whereas, neutrophil gelatinase-associated lipocalin seems to promote recovery, osteopontin appears to promote monocyte infiltration and fibrosis 33. Regardless of mechanism, these proteins clearly have a mechanistic role in the pathogenesis of Leptospira infection and potential value as urinary biomarkers similar to other species.
Fatty acid binding proteins (FABP) are abundant, low molecular weight proteins that act as lipid chaperones and play diverse roles including the formation of eicosanoids in macrophages 34. The most widely studied FABP relevant to kidney injury markers is the liver-type FABP 35,which is elevated in response to acute kidney injury of multiple etiologies. In the current study, the acute kidney injury marker liver-type FABP was not different between both groups, but interestingly, epidermal-type FABP was considerably elevated in the Lepto group relative to the Control group. Epidermal FABP is not typically associated with expression in the kidney 36, but has been detected in human kidney and reported in the Human Protein Atlas 37. Of the FABPs identified, the epidermal type may be of greater interest to prospective studies of tubular injury in sea lions, or at least should be considered alongside biomarker studies of liver-type FABPs.
Other notable differentially abundant proteins with biomarker precedence include clusterin and uromodulin. In dogs with leishmaniasis, characterized by glomerular mesangial proliferation and interstitial nephritis, urinary clusterin was elevated in more advanced renal cases 38. Gentamicin-induced tubular necrosis also resulted in an increase in urinary clusterin in beagles, suggesting that tubular dysfunction alone can cause increased urinary levels of this protein 39. In the current study, the elevation in urinary clusterin in sea lions suggests a similar urinary clusterin response is conserved in sea lions experiencing renal compromise. Uromodulin is a tubular protein primarily secreted at the thick ascending limb of the kidney and has been implicated in a myriad of roles including innate immunity and transporter regulation 40. Reduced uromodulin excretion is consistent with tubular injury, has been implicated as a risk factor for increased urinary tract infections in humans 41and has been associated with severe azotemia in dogs 42. Lepto sea lions also displayed a lower level of uromodulin in the urine and we hypothesize that injury response mechanisms, similar to those described for humans 40, are conserved in sea lions.
Tyrosine kinase receptor AXL was the protein most reduced in abundance in Lepto sea lions. Its ligand, growth arrest specific protein (HGNC gene symbol GAS6) was also reduced. GAS6/AXL is known to reduce tubulo-interstitial apoptosis in chronic kidney injury models 43 and upregulation of this axis promotes glomerular hypertrophy in diabetic mice 44. AXL expression is primarily located in vascular endothelia and the proximal tubule 45. A survey of human kidneys with inflammatory disease provides evidence of gross upregulation in the tissue which was shown to be elevated, in part, through Angiotensin II in cell culture models 46. If AXL/GAS6 expression is driven by inflammatory mechanisms, then this axis should be elevated in Lepto sea lions, but in fact, both urinary AXL and GAS6 were reduced. It remains possible that the large reduction in AXL/GAS6 could simply be due to substantial tubular damage. From a different perspective, the GAS6/AXL partners are typically reduced in the normal human kidney to the point where they are barely detectable 46. However, in Control sea lions, urinary GAS6/AXL appears to be abundant. Given that diving results in peripheral vasoconstriction 47, and that the GAS6/AXL axis has been reported to be protective of ischemia reperfusion injury 48, we hypothesize that GAS6/AXL may play a protective role in Control sea lions and that the loss of these proteins seen in the Lepto group may reflect a loss of renal cell survival. Despite a large number of studies of the GAS6/AXL axis in humans and laboratory rodent models 49, studies regarding the GAS6/AXL axis in normal marine mammal physiology are non-existent and the detection of AXL/GAS6 in Control sea lions may indicate the presence of an anti-apoptotic, pro-survival protective mechanism that is affected during Leptospira infection in sea lions.
Although many established tubular injury markers were not significantly altered, or in some cases levels changed in the opposing direction than expected, we cannot discount these proteins as potential urinary biomarkers for sea lions based on this study. In addition to the small numbers of individuals included in this study and lack of a species-specific proteome for the identification of proteins, low abundance peptides and proteins can lead to highly variable counts. Targeted absolute measurements with an appropriate standardized assay should always be considered in future prospective biomarker studies.
Renin-angiotensin system (RAS) and natriuretic proteins
Curiously, rats chronically infected with Leptospira display a less diverse urinary pattern of polypeptides including a reduction in RAS components; neprilysin (MME; alternative name, neutral endopeptidase) and angiotensin I 26. The reduction in urinary neprilysin protein was again reported by 2D-DIGE analysis in rats 50 as well as aminopeptidase N (alternative name, aminopeptidase M; HGNC approved name alanyl aminopeptidase, membrane), both of which play a role in the metabolism of angiotensin peptides in the intrarenal RAS 51. Commensurate to the rat studies, sea lions with leptospirosis displayed a reduction in many of the same components of the urinary RAS including neprilysin, aminopeptidase N, aminopeptidase A (HGNC approved name glutamyl aminopeptidase), angiotensin converting enzyme, angiotensin converting enzyme 2, carboxypeptidase A, and cathepsin D. The fact that renin was not discovered in the proteomic data for any sea lion, suggests that cathepsin D may be a major player in the sea lion intrarenal RAS as cathepsin D has been shown to be able to generate angiotensin I peptide from angiotensinogen 52.
The reduction in neprilysin was validated by immunoblot of sea lion urine proteins normalized to total protein or urine volume. Urinary neprilysin derived from proximal tubule has been recently reported to increase in humans with acute kidney injury patients due to sepsis 53, which is opposite of the urinary neprilysin phenotype of rats and sea lions with leptospirosis. A decrease in urinary neprilysin has been reported in db/db diabetic mice with hyperglycemia and microalbuminuria 54, which may be a response common to chronic renal inflammation 55. The consistent finding of urinary neprilysin reduction in two very different mammalian species suggests a possible targeted role for this enzyme in the response to leptospirosis.
Two notable clinic features of sea lions with leptospirosis are hypernatremia concomitant with a low urine osmolality. Hypernatremia may present in animals with reduced access to free water, diuresis due to azotemia, and renal impairment that results in a reduced ability to concentrate urine. More specifically, nephrogenic diabetes insipidus and renal vasopressin resistance appears to contribute to the urinary concentrating defect during leptospirosis infection, which might explain the hypernatremia concomitant with low urine osmolality56-58. In defense against hypernatremia, humans respond by inducing a natriuresis independent of blood pressure, atrial natriuretic peptide, and the RAS 59. To assess whether other natriuretic protein hormones may play a role in defending against hypernatremia, a survey of urinary natriuretic proteins in the two sea lion groups implicated the natriuretic pro-hormone guanylin as a potential regulator of sodium excretion. Pro-guanylin is primarily expressed in the gasterointestinal tract, but can be freely filtered by the kidney. The finding of elevated pro-guanylin abundance was unexpected because uroguanylin is anticipated to be more relevant in terms of expression in the kidney and detectability in the urine 60; however, pro-uroguanylin protein did not change suggesting that intestinal or renal guanylin may be upregulated in defense of normonatremia in sea lions. The link between sodium balance and natriuresis via an intestinal-renal natriuretic axis in healthy humans has been disputed 61making this observation in sea lions a potentially fascinating area of discovery regarding the regulation of sodium balance in leptospirosis kidney disease and in marine mammals in general.
Conclusions
Urine proteomes have become repositories for biomarker discovery and highlight mechanistic descriptions of normal and pathophysiology. To date, information regarding the urine proteome of marine mammals, such as the California sea lion, has been limited by a lack of proteomic efforts. There is a need for renal injury markers for marine mammals, in addition to SCr and BUN, in order to assess renal insufficiency beyond imperfect markers of filtration. Based on this study, there are many parallels between urine proteins from sea lions and published domestic veterinary and human clinical protein markers that can be used to accelerate biomarker assessment to classify mild and moderate renal injury.
Supporting Information
Supplemental Table S1. Protein identifications and differential analysis between groups. Supplemental Table S2. Identification and weighted spectral counts of 36 reported markers of kidney injury.
Supplemental Table S3. Identification and weighted spectral counts of proteins involved in the RAS pathway.
Supplemental Table S4. Identification and weighted spectral counts of proteins involved in the natriuretic pathway.
Supplemental Table 5. Serum and urine chemistry values for individual sea lions utilized to construct Table 1.
Acknowledgements
We would like to thank the veterinarians, biologists, and volunteers of The Marine Mammal Center (Sausalito, CA) and the Marine Mammal Laboratory (NOAA/NMFS) for their assistance in collecting samples. This work was supported by the National Science Foundation (OCE-1335657), the US Department of Defense Strategic Environmental Research and Development Program (RC01-020/RC-2635), the John H. Prescott Marine Mammal Rescue Assistance Grant Program, and the Hellman Family Foundation. Identification of certain commercial equipment, instruments, software or materials does not imply recommendation or endorsement by the National Institute of Standards and Technology, nor does it imply that the products identified are necessarily the best available for the purpose.
The authors declare no conflicts of interest.