The Identification of Novel Potential Injury Mechanisms and Candidate Biomarkers in Renal Allograft Rejection by Quantitative Proteomics

Sigdel, Tara K.; Salomonis, Nathan; Nicora, Carrie; Ryu, Soyoung; He, Jintang; Dinh, V.; Orton, Daniel J.; Moore, Ronald J.; Hsieh, Szu Chuan; Dai, Hong; Thien-Vu, Minh; Xiao, Wenzhong; Smith, Richard D.; Qian, Weijun; Camp, David G.; Sarwal, Minnie M.

doi:10.1074/mcp.m113.030577

Cited by 75 publications

(67 citation statements)

References 48 publications

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“…Since antibodies to these proteins are not commercially available, we performed a global quantitative proteomic profiling by two-dimensional LC-MS/MS coupled with iTRAQ (isobaric tag for relative and absolute quantitation) labeling (Sigdel et al, 2014) to investigate whether MBH insulin induced downstream BCAA-catabolizing enzymes. This proteomic analysis led to the identification and quantification of 2418 proteins in these liver extracts, of which ~250 were significantly altered by MBH insulin infusion.…”

Section: Resultsmentioning

confidence: 99%

Brain Insulin Lowers Circulating BCAA Levels by Inducing Hepatic BCAA Catabolism

et al. 2014

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Summary Circulating branched-chain amino acid (BCAA) levels are elevated in obesity/diabetes and are a sensitive predictor for type 2 diabetes. Here we show in rats that insulin dose-dependently lowers plasma BCAA levels through induction of hepatic protein expression and activity of branched-chain α keto-acid dehydrogenase (BCKDH), the rate-limiting enzyme in the BCAA degradation pathway. Selective induction of hypothalamic insulin signaling in rats and genetic modulation of brain insulin receptors in mice demonstrate that brain insulin signaling is a major regulator of BCAA metabolism by inducing hepatic BCKDH. Short-term overfeeding impairs the ability of brain insulin to lower BCAAs in rats. High-fat feeding in non-human primates and obesity and/or diabetes in humans is associated with reduced BCKDH protein in liver. These findings support the concept that decreased hepatic BCKDH is a major cause of increased plasma BCAAs, and that hypothalamic insulin resistance may account for impaired BCAA metabolism in obesity and diabetes.

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Section: Resultsmentioning

confidence: 99%

Brain Insulin Lowers Circulating BCAA Levels by Inducing Hepatic BCAA Catabolism

et al. 2014

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“…A recent study by our group identified novel antigenic targets [endoglin, epidermal growth factor (EGF)-like repeats and discoidin I-like domains 3, intercellular adhesion molecule 4, and FMS-like tyrosine kinase-3 ligand], which were relevant to the development of acute ABMR as evidenced by a positive endothelial positive cross-match [37]. In addition, upregulation of nHLA proteins in acute rejection in transplant [38] have been described; it would be important to know whether these proteins serve as alloantigens.…”

Section: Non-hla Antibodiesmentioning

confidence: 97%

“…The ability to diagnose rejection at a molecular level from a blood or urine specimen is beneficial because it allows for non-invasive diagnosis and risk stratification of rejection without the traumatic biopsy of an organ that is already undergoing the trauma of rejection. Recently, studies have described patterns of gene expression [53,54] and microarray analysis [55][56][57], urine proteomics [38], and a constitution of both molecular and clinical markers specific to acute rejection [58,59] in solid organ transplants, including kidney transplants. Some of these studies [52,59] have led to the development of the kidney Solid Organ Response Test [60], which can accurately diagnose acute kidney rejection with a peripheral blood sample.…”

Section: Molecular Diagnosismentioning

confidence: 99%

Antibody-Mediated Rejection in Pediatric Kidney Transplantation: Pathophysiology, Diagnosis, and Management

Singh

Sarwal

2015

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Kidney transplant is the preferred treatment of pediatric end-stage renal disease. One of the most challenging aspects of pediatric kidney transplant is the prevention and treatment of antibody-mediated rejection (ABMR), which is one of the main causes of graft dysfunction and early graft loss. Most challenges are similar to those faced in adult kidney transplants; however, factors unique to the pediatric realm include naivety of the immune system and the small number of studies and randomized controlled trials available when considering pharmacological treatment options. Here, we present a case of ABMR in a pediatric patient and a review of the pathophysiology, diagnosis, and management of ABMR. ABMR in pediatric kidney transplant continues to be a frustrating condition to treat because (1) there still remain many unidentified potential antigens leading to ABMR, (2) children and adults are at different stages of their immune system development, and, thus, (3) the full pathophysiology of alloimmunity is still not completely understood, and (4) the efficacy and safety of treatment in adults may not be directly translated to children. As we continue to gain a better understanding towards the precise alloimmune mechanism that drives a particular ABMR, we can also improve pharmacotherapeutic choices. With continued research, they will become more precise in treating a particular mechanism versus using a broad scope of immunosuppression such as steroids. However, there is much more to be uncovered, such as identifying more non-human leukocyte antigens and their role in alloimmunity, determining the exact mechanism of adults achieving complete operational tolerance, and understanding the difference between pediatric and adult transplant recipients. Making strides towards a better understanding of these mechanisms will lead to continued efficacy and safety in treatment of pediatric ABMR.

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“…Other studies have applied a variety of proteomic techniques to identify protein expression in an unbiased high-throughput manner in allograft rejection, before utilizing targeted ELISA for validation of biomarker panels. 93,97,102 However as with the majority of promising proteomic studies to date, multicenter prospective trials are required to validate these candidate markers before meaningful conclusions can be made.…”

Section: Other ‘Omics: Proteomics Transcriptomics and Metabolomicsmentioning

confidence: 99%

The Use of Genomics and Pathway Analysis in Our Understanding and Prediction of Clinical Renal Transplant Injury

et al. 2016

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The development and application of high-throughput molecular profiling have transformed the study of human diseases. The problem of handling large, complex datasets has been facilitated by advances in complex computational analysis. In this review the recent literature regarding the application of transcriptional genomic information to renal transplantation, with specific reference to acute rejection, acute kidney injury in allografts, chronic allograft injury and tolerance is discussed, as is the current published data regarding other “omics” strategies- proteomics, metabolomics and the micro-RNA transcriptome. These data have shed new light on our understanding of the pathogenesis of specific disease conditions following renal transplantation but their utility as a biomarker of disease has been hampered by study design and sample size. This review aims to highlight the opportunities and obstacles that exist with genomics and other related technologies in order to better understand and predict renal allograft outcome.

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The Identification of Novel Potential Injury Mechanisms and Candidate Biomarkers in Renal Allograft Rejection by Quantitative Proteomics

Cited by 75 publications

References 48 publications

Brain Insulin Lowers Circulating BCAA Levels by Inducing Hepatic BCAA Catabolism

Brain Insulin Lowers Circulating BCAA Levels by Inducing Hepatic BCAA Catabolism

Antibody-Mediated Rejection in Pediatric Kidney Transplantation: Pathophysiology, Diagnosis, and Management

The Use of Genomics and Pathway Analysis in Our Understanding and Prediction of Clinical Renal Transplant Injury

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