Comprehensive analysis of the mouse renal cortex using two-dimensional HPLC – tandem mass spectrometry

BackgroundProteomic methodologies increasingly have been applied to the kidney to map the renal cortical proteome and to identify global changes in renal proteins induced by diseases such as diabetes. While progress has been made in establishing a renal cortical proteome using 1-D or 2-DE and mass spectrometry, the number of proteins definitively identified by mass spectrometry has remained surprisingly small. Low coverage of the renal cortical proteome as well as our interest in diabetes-induced changes in proteins found in the renal cortex prompted us to perform an in-depth proteomic analysis of mouse renal cortical tissue.ResultsWe report a large scale analysis of mouse renal cortical proteome using SCX prefractionation strategy combined with HPLC – tandem mass spectrometry. High-confidence identification of ~2,000 proteins, including cytoplasmic, nuclear, plasma membrane, extracellular and unknown/unclassified proteins, was obtained by separating tryptic peptides of renal cortical proteins into 60 fractions by SCX prior to LC-MS/MS. The identified proteins represented the renal cortical proteome with no discernible bias due to protein physicochemical properties, subcellular distribution, biological processes, or molecular function. The highest ranked molecular functions were characteristic of tubular epithelium, and included binding, catalytic activity, transporter activity, structural molecule activity, and carrier activity. Comparison of this renal cortical proteome with published human urinary proteomes demonstrated enrichment of renal extracellular, plasma membrane, and lysosomal proteins in the urine, with a lack of intracellular proteins. Comparison of the most abundant proteins based on normalized spectral abundance factor (NSAF) in this dataset versus a published glomerular proteome indicated enrichment of mitochondrial proteins in the former and cytoskeletal proteins in the latter.ConclusionA whole tissue extract of the mouse kidney cortex was analyzed by an unbiased proteomic approach, yielding a dataset of ~2,000 unique proteins identified with strict criteria to ensure a high level of confidence in protein identification. As a result of extracting all proteins from the renal cortex, we identified an exceptionally wide range of renal proteins in terms of pI, MW, hydrophobicity, abundance, and subcellular location. Many of these proteins, such as low-abundance proteins, membrane proteins and proteins with extreme values in pI or MW are traditionally under-represented in 2-DE-based proteomic analysis.

[1]  A. Evan,et al.  Analysis of insulin-like growth factors (IGF)-I, and -II, type II IGF receptor and IGF-binding protein-2 mRNA and peptide levels in normal and nephrectomized rat kidney. , 1995, Kidney international.

[2]  H. Mischak,et al.  Identification of urinary protein pattern in type 1 diabetic adolescents with early diabetic nephropathy by a novel combined proteome analysis. , 2005, Journal of diabetes and its complications.

[3]  K. Resing,et al.  Comparison of Label-free Methods for Quantifying Human Proteins by Shotgun Proteomics*S , 2005, Molecular & Cellular Proteomics.

[4]  T. Hirokawa,et al.  Proportion of membrane proteins in proteomes of 15 single-cell organisms analyzed by the SOSUI prediction system. , 1999, Biophysical chemistry.

[5]  M. Washburn,et al.  Quantitative proteomic analysis of distinct mammalian Mediator complexes using normalized spectral abundance factors , 2006, Proceedings of the National Academy of Sciences.

[6]  A. Burlingame,et al.  Proteomic analysis of plasma membrane vesicles isolated from the rat renal cortex , 2005, Proteomics.

[7]  Y. Kaneda,et al.  Normalizing mitochondrial superoxide production blocks three pathways of hyperglycaemic damage , 2000, Nature.

[8]  T. Furukawa,et al.  Mouse heparin binding protein-44 (HBP-44) associates with brushin, a high-molecular-weight glycoprotein antigen common to the kidney and teratocarcinomas. , 1993, Journal of biochemistry.

[9]  Fang Liu,et al.  Attenuation of Interstitial Fibrosis and Tubular Apoptosis in db/db Transgenic Mice Overexpressing Catalase in Renal Proximal Tubular Cells , 2008, Diabetes.

[10]  E. Nouwen,et al.  EGF and TGF-alpha in the human kidney: identification of octopal cells in the collecting duct. , 1994, Kidney International.

[11]  Juri Rappsilber,et al.  Exploring the hidden human urinary proteome via ligand library beads. , 2005, Journal of proteome research.

[12]  H. Lan,et al.  Transforming growth factor‐β and Smad signalling in kidney diseases , 2005, Nephrology.

[13]  A. Tsugita,et al.  Two‐dimensional electrophoretic profiling of normal human kidney glomerulus proteome and construction of an extensible markup language (XML)‐based database , 2005, Proteomics.

[14]  Shin-Yoon Kim,et al.  Establishment of a near‐standard two‐dimensional human urine proteomic map , 2004, Proteomics.

[15]  R. Atkins,et al.  Expression of macrophage migration inhibitory factor in human glomerulonephritis. , 2000, Kidney international.

[16]  N. Thornberry,et al.  Dipeptidyl Peptidase‐4 Inhibitors for the Treatment of Type 2 Diabetes: Focus On Sitagliptin , 2007, Clinical pharmacology and therapeutics.

[17]  J. Yates,et al.  Proteomic identification of palmitoylated proteins. , 2006, Methods.

[18]  K. Sharma,et al.  Profiling of human mesangial cell subproteomes reveals a role for calmodulin in glucose uptake. , 2007, American journal of physiology. Renal physiology.

[19]  E. Nouwen,et al.  EGF and TGF-α in the human kidney: Identification of octopal cells in the collecting duct , 1994 .

[20]  D. Tomlinson Mitogen-activated protein kinases as glucose transducers for diabetic complications , 1999, Diabetologia.

[21]  Rembert Pieper,et al.  Characterization of the human urinary proteome: A method for high‐resolution display of urinary proteins on two‐dimensional electrophoresis gels with a yield of nearly 1400 distinct protein spots , 2004, Proteomics.

[22]  K. Sharma,et al.  Two‐dimensional fluorescence difference gel electrophoresis analysis of the urine proteome in human diabetic nephropathy , 2005, Proteomics.

[23]  Brad T. Sherman,et al.  DAVID: Database for Annotation, Visualization, and Integrated Discovery , 2003, Genome Biology.

[24]  K. Okubo,et al.  Induction of Glia Maturation Factor-β in Proximal Tubular Cells Leads to Vulnerability to Oxidative Injury through the p38 Pathway and Changes in Antioxidant Enzyme Activities* , 2003, Journal of Biological Chemistry.

[25]  H. D. de Wardener,et al.  Relationship between renal function and histological changes found in renal-biopsy specimens from patients with persistent glomerular nephritis. , 1968, Lancet.

[26]  S. Moestrup,et al.  Cubilin- and megalin-mediated uptake of albumin in cultured proximal tubule cells of opossum kidney. , 2000, Kidney international.

[27]  J. Yates,et al.  Large-scale analysis of the yeast proteome by multidimensional protein identification technology , 2001, Nature Biotechnology.

[28]  M. Mann,et al.  Analysis of the mouse liver proteome using advanced mass spectrometry. , 2007, Journal of proteome research.

[29]  Allan R Brasier,et al.  Diabetes‐induced changes in the renal cortical proteome assessed with two‐dimensional gel electrophoresis and mass spectrometry , 2007, Proteomics.

[30]  J. Ingelfinger,et al.  Catalase overexpression attenuates angiotensinogen expression and apoptosis in diabetic mice. , 2007, Kidney international.

[31]  A. Kenny,et al.  Metabolism of neuropeptides. Hydrolysis of the angiotensins, bradykinin, substance P and oxytocin by pig kidney microvillar membranes. , 1987, The Biochemical journal.

[32]  M. Mann,et al.  Status of complete proteome analysis by mass spectrometry: SILAC labeled yeast as a model system , 2006, Genome Biology.

[33]  J. Yates,et al.  DTASelect and Contrast: tools for assembling and comparing protein identifications from shotgun proteomics. , 2002, Journal of proteome research.

[34]  R. Danziger,et al.  Dietary NaCl Regulates Renal Aminopeptidase N: Relevance to Hypertension in the Dahl Rat , 2004, Hypertension.

[35]  Jian Cai,et al.  Proteomic Analysis Reveals Alterations in the Renal Kallikrein Pathway during Hypoxia-Induced Hypertension* , 2002, The Journal of Biological Chemistry.

[36]  Tao Xu,et al.  Quantitative Mass Spectrometry Identifies Insulin Signaling Targets in C. elegans , 2007, Science.

[37]  F. Locatelli,et al.  End-stage renal failure in type 2 diabetes: A medical catastrophe of worldwide dimensions. , 1999, American journal of kidney diseases : the official journal of the National Kidney Foundation.

[38]  Rong-Fong Shen,et al.  Large Scale Protein Identification in Intracellular Aquaporin-2 Vesicles from Renal Inner Medullary Collecting Duct*S , 2005, Molecular & Cellular Proteomics.

[39]  H. Dihazi,et al.  Proteomic Analysis of Cellular Response to Osmotic Stress in Thick Ascending Limb of Henle’s Loop (TALH) Cells* , 2005, Molecular & Cellular Proteomics.

[40]  Brendan K Faherty,et al.  Optimization and Use of Peptide Mass Measurement Accuracy in Shotgun Proteomics*S , 2006, Molecular & Cellular Proteomics.

[41]  H. Ito,et al.  Expression of epidermal growth factor in human tissues , 2005, Virchows Archiv A.

[42]  M. Goligorsky,et al.  Diagnostic potential of urine proteome: a broken mirror of renal diseases. , 2007, Journal of the American Society of Nephrology : JASN.

[43]  Barbara Sitek,et al.  Novel approaches to analyse glomerular proteins from smallest scale murine and human samples using DIGE saturation labelling , 2006, Proteomics.

[44]  Visith Thongboonkerd,et al.  Renal and urinary proteomics: Current applications and challenges , 2005, Proteomics.

[45]  J. Yates,et al.  A model for random sampling and estimation of relative protein abundance in shotgun proteomics. , 2004, Analytical chemistry.

[46]  Joshua E. Elias,et al.  Evaluation of multidimensional chromatography coupled with tandem mass spectrometry (LC/LC-MS/MS) for large-scale protein analysis: the yeast proteome. , 2003, Journal of proteome research.

[47]  J. Nyengaard,et al.  Hyperglycemic Pseudohypoxia and Diabetic Complications , 1993, Diabetes.

[48]  D. Healy,et al.  Kidney aminopeptidase A and hypertension, part II: effects of angiotensin II. , 1999, Hypertension.

[49]  R. Atkins,et al.  Interferon‐γ induces macrophage migration inhibitory factor synthesis and secretion by tubular epithelial cells , 2003, Nephrology.

[50]  M. Knepper,et al.  Proteomic analysis of the adaptive response of rat renal proximal tubules to metabolic acidosis. , 2007, American journal of physiology. Renal physiology.

[51]  J. Klein,et al.  Proteomic analysis defines altered cellular redox pathways and advanced glycation end-product metabolism in glomeruli of db/db diabetic mice. , 2007, American journal of physiology. Renal physiology.

[52]  J. Ingelfinger,et al.  Overexpression of angiotensinogen increases tubular apoptosis in diabetes. , 2008, Journal of the American Society of Nephrology : JASN.

[53]  H Birn,et al.  Cubilin is an albumin binding protein important for renal tubular albumin reabsorption. , 2000, The Journal of clinical investigation.

[54]  C. Fraga,et al.  Enalapril and losartan attenuate mitochondrial dysfunction in aged rats , 2003, FASEB journal : official publication of the Federation of American Societies for Experimental Biology.

[55]  T. Nishikawa,et al.  The missing link: a single unifying mechanism for diabetic complications. , 2000, Kidney international. Supplement.

[56]  J. Eggermont,et al.  PDZ proteins retain and regulate membrane transporters in polarized epithelial cell membranes. , 2005, American journal of physiology. Cell physiology.

[57]  M. Yanagita The role of the vitamin K-dependent growth factor Gas6 in glomerular pathophysiology , 2004, Current opinion in nephrology and hypertension.

[58]  Rong-Fong Shen,et al.  Identification and proteomic profiling of exosomes in human urine. , 2004, Proceedings of the National Academy of Sciences of the United States of America.

[59]  Steven P Gygi,et al.  Target-decoy search strategy for increased confidence in large-scale protein identifications by mass spectrometry , 2007, Nature Methods.

[60]  Steven P Gygi,et al.  Comparative evaluation of mass spectrometry platforms used in large-scale proteomics investigations , 2005, Nature Methods.

[61]  B. Banas,et al.  Growth arrest specific protein 6/Axl signaling in human inflammatory renal diseases. , 2004, American journal of kidney diseases : the official journal of the National Kidney Foundation.

[62]  S. Bosari,et al.  Expanding the proteome two‐dimensional gel electrophoresis reference map of human renal cortex by peptide mass fingerprinting , 2005, Proteomics.

[63]  Bernhard Kuster,et al.  Profiling Core Proteomes of Human Cell Lines by One-dimensional PAGE and Liquid Chromatography-Tandem Mass Spectrometry*S , 2003, Molecular & Cellular Proteomics.

[64]  M. Janech,et al.  Proteomics in renal research. , 2007, American journal of physiology. Renal physiology.

[65]  Shigeki Mitaku,et al.  SOSUI: classification and secondary structure prediction system for membrane proteins , 1998, Bioinform..

[66]  J. Klco,et al.  Gene expression profiling in a renal cell carcinoma cell line: dissecting VHL and hypoxia-dependent pathways. , 2003, Molecular cancer research : MCR.

[67]  W. Lieberthal,et al.  Beta1 integrin-mediated adhesion between renal tubular cells after anoxic injury. , 1997, Journal of the American Society of Nephrology : JASN.

[68]  Bhattaram Pallavi,et al.  Apical targeting of syntaxin 3 is essential for epithelial cell polarity , 2006, The Journal of cell biology.

[69]  Rong-Fong Shen,et al.  LC-MS/MS Analysis of Apical and Basolateral Plasma Membranes of Rat Renal Collecting Duct Cells*S , 2006, Molecular & Cellular Proteomics.

[70]  X. Yao,et al.  Proteolytic 18O labeling for comparative proteomics: model studies with two serotypes of adenovirus. , 2001, Analytical chemistry.

[71]  S. Bagby Diabetic nephropathy and proximal tubule ROS: challenging our glomerulocentricity. , 2007, Kidney international.

[72]  Stephen M Hewitt,et al.  Discovery of protein biomarkers for renal diseases. , 2004, Journal of the American Society of Nephrology : JASN.

[73]  C. Wagner,et al.  PDZ proteins and proximal ion transport , 2004, Current opinion in nephrology and hypertension.

[74]  R. Zeng,et al.  Two‐dimensional gel electrophoresis maps of the proteome and phosphoproteome of primitively cultured rat mesangial cells , 2005, Electrophoresis.

[75]  Bo Xu,et al.  In-depth proteomic profiling of the normal human kidney glomerulus using two-dimensional protein prefractionation in combination with liquid chromatography-tandem mass spectrometry. , 2007, Journal of proteome research.

[76]  M. Mann,et al.  The human urinary proteome contains more than 1500 proteins, including a large proportion of membrane proteins , 2006, Genome Biology.