Your search keyword '"Azeloglu, Evren U."' showing total 5 results

1. A reference tissue atlas for the human kidney

Author

Hansen, Jens, Sealfon, Rachel, Menon, Rajasree, Eadon, Michael T, Lake, Blue B, Steck, Becky, Anjani, Kavya, Parikh, Samir, Sigdel, Tara K, Zhang, Guanshi, Velickovic, Dusan, Barwinska, Daria, Alexandrov, Theodore, Dobi, Dejan, Rashmi, Priyanka, Otto, Edgar A, Rivera, Miguel, Rose, Michael P, Anderton, Christopher R, Shapiro, John P, Pamreddy, Annapurna, Winfree, Seth, Xiong, Yuguang, He, Yongqun, de Boer, Ian H, Hodgin, Jeffrey B, Barisoni, Laura, Naik, Abhijit S, Sharma, Kumar, Sarwal, Minnie M, Zhang, Kun, Himmelfarb, Jonathan, Rovin, Brad, El-Achkar, Tarek M, Laszik, Zoltan, He, John Cijiang, Dagher, Pierre C, Valerius, M Todd, Jain, Sanjay, Satlin, Lisa M, Troyanskaya, Olga G, Kretzler, Matthias, Iyengar, Ravi, Azeloglu, Evren U, and Project, Kidney Precision Medicine

Subjects

Biotechnology, Genetics, Kidney Disease, Aetiology, 2.1 Biological and endogenous factors, Underpinning research, 1.1 Normal biological development and functioning, Generic health relevance, Renal and urogenital, Good Health and Well Being, Humans, Kidney, Kidney Diseases, Metabolomics, Proteomics, Transcriptome, Kidney Precision Medicine Project

Abstract

Kidney Precision Medicine Project (KPMP) is building a spatially specified human kidney tissue atlas in health and disease with single-cell resolution. Here, we describe the construction of an integrated reference map of cells, pathways, and genes using unaffected regions of nephrectomy tissues and undiseased human biopsies from 56 adult subjects. We use single-cell/nucleus transcriptomics, subsegmental laser microdissection transcriptomics and proteomics, near-single-cell proteomics, 3D and CODEX imaging, and spatial metabolomics to hierarchically identify genes, pathways, and cells. Integrated data from these different technologies coherently identify cell types/subtypes within different nephron segments and the interstitium. These profiles describe cell-level functional organization of the kidney following its physiological functions and link cell subtypes to genes, proteins, metabolites, and pathways. They further show that messenger RNA levels along the nephron are congruent with the subsegmental physiological activity. This reference atlas provides a framework for the classification of kidney disease when multiple molecular mechanisms underlie convergent clinical phenotypes.

Published

2022

2. Rationale and design of the Kidney Precision Medicine Project

Author

de Boer, Ian H, Alpers, Charles E, Azeloglu, Evren U, Balis, Ulysses GJ, Barasch, Jonathan M, Barisoni, Laura, Blank, Kristina N, Bomback, Andrew S, Brown, Keith, Dagher, Pierre C, Dighe, Ashveena L, Eadon, Michael T, El-Achkar, Tarek M, Gaut, Joseph P, Hacohen, Nir, He, Yongqun, Hodgin, Jeffrey B, Jain, Sanjay, Kellum, John A, Kiryluk, Krzysztof, Knight, Richard, Laszik, Zoltan G, Lienczewski, Chrysta, Mariani, Laura H, McClelland, Robyn L, Menez, Steven, Moledina, Dennis G, Mooney, Sean D, O’Toole, John F, Palevsky, Paul M, Parikh, Chirag R, Poggio, Emilio D, Rosas, Sylvia E, Rosengart, Matthew R, Sarwal, Minnie M, Schaub, Jennifer A, Sedor, John R, Sharma, Kumar, Steck, Becky, Toto, Robert D, Troyanskaya, Olga G, Tuttle, Katherine R, Vazquez, Miguel A, Waikar, Sushrut S, Williams, Kayleen, Wilson, Francis Perry, Zhang, Kun, Iyengar, Ravi, Kretzler, Matthias, Himmelfarb, Jonathan, Project, Kidney Precision Medicine, Lecker, Stewart, Stillman, Isaac, Waikar, Sushrut, Mcmahon, Gearoid, Weins, Astrid, Short, Samuel, Hoover, Paul, Aulisio, Mark, Cooperman, Leslie, Herlitz, Leal, O’Toole, John, Poggio, Emilio, Sedor, John, Jolly, Stacey, Appelbaum, Paul, Balderes, Olivia, Barasch, Jonathan, Bomback, Andrew, Canetta, Pietro A, d’Agati, Vivette D, Kudose, Satoru, Mehl, Karla, Radhakrishnan, Jai, Weng, Chenhua, Alexandrov, Theodore, Ashkar, Tarek, Barwinska, Daria, Dagher, Pierre, Dunn, Kenneth, Eadon, Michael, Ferkowicz, Michael, Kelly, Katherine, Sutton, Timothy, Winfree, Seth, Parikh, Chirag, Rosenberg, Avi, Villalobos, Pam, Malik, Rubab, Fine, Derek, Atta, Mohammed, Trujillo, Jose Manuel Monroy, Slack, Alison, Rosas, Sylvia, and Williams, Mark

Subjects

Clinical Research, Transplantation, Kidney Disease, Prevention, Renal and urogenital, Good Health and Well Being, Acute Kidney Injury, Adult, Humans, Kidney, Precision Medicine, Prospective Studies, Proteomics, Renal Insufficiency, Chronic, acute kidney injury, chronic kidney disease, diabetes, hypertension, precision medicine, Kidney Precision Medicine Project, Clinical Sciences, Urology & Nephrology

Abstract

Chronic kidney disease (CKD) and acute kidney injury (AKI) are common, heterogeneous, and morbid diseases. Mechanistic characterization of CKD and AKI in patients may facilitate a precision-medicine approach to prevention, diagnosis, and treatment. The Kidney Precision Medicine Project aims to ethically and safely obtain kidney biopsies from participants with CKD or AKI, create a reference kidney atlas, and characterize disease subgroups to stratify patients based on molecular features of disease, clinical characteristics, and associated outcomes. An additional aim is to identify critical cells, pathways, and targets for novel therapies and preventive strategies. This project is a multicenter prospective cohort study of adults with CKD or AKI who undergo a protocol kidney biopsy for research purposes. This investigation focuses on kidney diseases that are most prevalent and therefore substantially burden the public health, including CKD attributed to diabetes or hypertension and AKI attributed to ischemic and toxic injuries. Reference kidney tissues (for example, living-donor kidney biopsies) will also be evaluated. Traditional and digital pathology will be combined with transcriptomic, proteomic, and metabolomic analysis of the kidney tissue as well as deep clinical phenotyping for supervised and unsupervised subgroup analysis and systems biology analysis. Participants will be followed prospectively for 10 years to ascertain clinical outcomes. Cell types, locations, and functions will be characterized in health and disease in an open, searchable, online kidney tissue atlas. All data from the Kidney Precision Medicine Project will be made readily available for broad use by scientists, clinicians, and patients.

Published

2021

3. The Library of Integrated Network-Based Cellular Signatures NIH Program: System-Level Cataloging of Human Cells Response to Perturbations

Author

Keenan, Alexandra B, Jenkins, Sherry L, Jagodnik, Kathleen M, Koplev, Simon, He, Edward, Torre, Denis, Wang, Zichen, Dohlman, Anders B, Silverstein, Moshe C, Lachmann, Alexander, Kuleshov, Maxim V, Ma'ayan, Avi, Stathias, Vasileios, Terryn, Raymond, Cooper, Daniel, Forlin, Michele, Koleti, Amar, Vidovic, Dusica, Chung, Caty, Schürer, Stephan C, Vasiliauskas, Jouzas, Pilarczyk, Marcin, Shamsaei, Behrouz, Fazel, Mehdi, Ren, Yan, Niu, Wen, Clark, Nicholas A, White, Shana, Mahi, Naim, Zhang, Lixia, Kouril, Michal, Reichard, John F, Sivaganesan, Siva, Medvedovic, Mario, Meller, Jaroslaw, Koch, Rick J, Birtwistle, Marc R, Iyengar, Ravi, Sobie, Eric A, Azeloglu, Evren U, Kaye, Julia, Osterloh, Jeannette, Haston, Kelly, Kalra, Jaslin, Finkbiener, Steve, Li, Jonathan, Milani, Pamela, Adam, Miriam, Escalante-Chong, Renan, Sachs, Karen, Lenail, Alex, Ramamoorthy, Divya, Fraenkel, Ernest, Daigle, Gavin, Hussain, Uzma, Coye, Alyssa, Rothstein, Jeffrey, Sareen, Dhruv, Ornelas, Loren, Banuelos, Maria, Mandefro, Berhan, Ho, Ritchie, Svendsen, Clive N, Lim, Ryan G, Stocksdale, Jennifer, Casale, Malcolm S, Thompson, Terri G, Wu, Jie, Thompson, Leslie M, Dardov, Victoria, Venkatraman, Vidya, Matlock, Andrea, Van Eyk, Jennifer E, Jaffe, Jacob D, Papanastasiou, Malvina, Subramanian, Aravind, Golub, Todd R, Erickson, Sean D, Fallahi-Sichani, Mohammad, Hafner, Marc, Gray, Nathanael S, Lin, Jia-Ren, Mills, Caitlin E, Muhlich, Jeremy L, Niepel, Mario, Shamu, Caroline E, Williams, Elizabeth H, Wrobel, David, Sorger, Peter K, Heiser, Laura M, Gray, Joe W, Korkola, James E, Mills, Gordon B, LaBarge, Mark, Feiler, Heidi S, Dane, Mark A, Bucher, Elmar, Nederlof, Michel, Sudar, Damir, and Gross, Sean

Subjects

Bioengineering, Cancer, Genetics, Biotechnology, 2.1 Biological and endogenous factors, Aetiology, Generic health relevance, Good Health and Well Being, Cataloging, Computational Biology, Databases, Chemical, Gene Expression Profiling, Gene Library, Humans, Information Storage and Retrieval, National Health Programs, National Institutes of Health (U.S.), Systems Biology, Transcriptome, United States, BD2K, L1000, MCF10A, MEMA, P100, data integration, lincsprogram, lincsproject, systems biology, systems pharmacology, Biochemistry and Cell Biology

Abstract

The Library of Integrated Network-Based Cellular Signatures (LINCS) is an NIH Common Fund program that catalogs how human cells globally respond to chemical, genetic, and disease perturbations. Resources generated by LINCS include experimental and computational methods, visualization tools, molecular and imaging data, and signatures. By assembling an integrated picture of the range of responses of human cells exposed to many perturbations, the LINCS program aims to better understand human disease and to advance the development of new therapies. Perturbations under study include drugs, genetic perturbations, tissue micro-environments, antibodies, and disease-causing mutations. Responses to perturbations are measured by transcript profiling, mass spectrometry, cell imaging, and biochemical methods, among other assays. The LINCS program focuses on cellular physiology shared among tissues and cell types relevant to an array of diseases, including cancer, heart disease, and neurodegenerative disorders. This Perspective describes LINCS technologies, datasets, tools, and approaches to data accessibility and reusability.

Published

2018

4. A Comparison of mRNA Sequencing with Random Primed and 3′-Directed Libraries

Author

Xiong, Yuguang, Soumillon, Magali, Wu, Jie, Hansen, Jens, Hu, Bin, van Hasselt, Johan GC, Jayaraman, Gomathi, Lim, Ryan, Bouhaddou, Mehdi, Ornelas, Loren, Bochicchio, Jim, Lenaeus, Lindsay, Stocksdale, Jennifer, Shim, Jaehee, Gomez, Emilda, Sareen, Dhruv, Svendsen, Clive, Thompson, Leslie M, Mahajan, Milind, Iyengar, Ravi, Sobie, Eric A, Azeloglu, Evren U, and Birtwistle, Marc R

Subjects

Human Genome, Genetics, Generic health relevance, Case-Control Studies, Cells, Cultured, Gene Expression Profiling, Gene Expression Regulation, Gene Library, High-Throughput Nucleotide Sequencing, Humans, Induced Pluripotent Stem Cells, Models, Statistical, Muscular Atrophy, Spinal, Myocytes, Cardiac, RNA, Messenger, Sequence Analysis, RNA

Abstract

Creating a cDNA library for deep mRNA sequencing (mRNAseq) is generally done by random priming, creating multiple sequencing fragments along each transcript. A 3'-end-focused library approach cannot detect differential splicing, but has potentially higher throughput at a lower cost, along with the ability to improve quantification by using transcript molecule counting with unique molecular identifiers (UMI) that correct PCR bias. Here, we compare an implementation of such a 3'-digital gene expression (3'-DGE) approach with "conventional" random primed mRNAseq. Given our particular datasets on cultured human cardiomyocyte cell lines, we find that, while conventional mRNAseq detects ~15% more genes and needs ~500,000 fewer reads per sample for equivalent statistical power, the resulting differentially expressed genes, biological conclusions, and gene signatures are highly concordant between two techniques. We also find good quantitative agreement at the level of individual genes between two techniques for both read counts and fold changes between given conditions. We conclude that, for high-throughput applications, the potential cost savings associated with 3'-DGE approach are likely a reasonable tradeoff for modest reduction in sensitivity and inability to observe alternative splicing, and should enable many larger scale studies focusing on not only differential expression analysis, but also quantitative transcriptome profiling.

Published

2017

5. Fragility of foot process morphology in kidney podocytes arises from chaotic spatial propagation of cytoskeletal instability.

Author

Falkenberg, Cibele V, Azeloglu, Evren U, Stothers, Mark, Deerinck, Thomas J, Chen, Yibang, He, John C, Ellisman, Mark H, Hone, James C, Iyengar, Ravi, and Loew, Leslie M

Subjects

Cells, Cultured, Cell Surface Extensions, Humans, Cell Polarity, Cell Size, Nonlinear Dynamics, Models, Biological, Computer Simulation, Podocytes, Actin Cytoskeleton, Spatio-Temporal Analysis, Cells, Cultured, Models, Biological, Mathematical Sciences, Biological Sciences, Information and Computing Sciences, Bioinformatics

Abstract

Kidney podocytes' function depends on fingerlike projections (foot processes) that interdigitate with those from neighboring cells to form the glomerular filtration barrier. The integrity of the barrier depends on spatial control of dynamics of actin cytoskeleton in the foot processes. We determined how imbalances in regulation of actin cytoskeletal dynamics could result in pathological morphology. We obtained 3-D electron microscopy images of podocytes and used quantitative features to build dynamical models to investigate how regulation of actin dynamics within foot processes controls local morphology. We find that imbalances in regulation of actin bundling lead to chaotic spatial patterns that could impair the foot process morphology. Simulation results are consistent with experimental observations for cytoskeletal reconfiguration through dysregulated RhoA or Rac1, and they predict compensatory mechanisms for biochemical stability. We conclude that podocyte morphology, optimized for filtration, is intrinsically fragile, whereby local transient biochemical imbalances may lead to permanent morphological changes associated with pathophysiology.

Published

2017