Your search keyword '"Sorrentino, James T."' showing total 6 results

1. Preparing glycomics data for robust statistical analysis with GlyCompareCT

Author

Zhang, Yujie, Krishnan, Sridevi, Bao, Bokan, Chiang, Austin WT, Sorrentino, James T, Schinn, Song-Min, Kellman, Benjamin P, and Lewis, Nathan E

Subjects

Bioinformatics, Molecular Biology, Systems Biology

Abstract

GlyCompareCT is a portable command-line tool to facilitate downstream glycomic data analyses, by addressing data inherent sparsity and non-independence. Inputting glycan abundances, users can run GlyCompareCT with one line of code to obtain the abundances of a minimal substructure set, named glycomotif, thereby quantifying hidden biosynthetic relationships between measured glycans. Optional parameters tuning and annotation are supported for personal preference. For complete details on the use and execution of this protocol, please refer to Bao et al. (2021).1.

Published

2023

2. Vascular Proteome Responses Precede Organ Dysfunction in a Murine Model of Staphylococcus aureus Bacteremia

Author

Sorrentino, James T, Golden, Gregory J, Morris, Claire, Painter, Chelsea D, Nizet, Victor, Campos, Alexandre Rosa, Smith, Jeffrey W, Karlsson, Christofer, Malmström, Johan, Lewis, Nathan E, Esko, Jeffrey D, and Toledo, Alejandro Gómez

Subjects

Hematology, Emerging Infectious Diseases, Infectious Diseases, Sepsis, Aetiology, 2.1 Biological and endogenous factors, Infection, Inflammatory and immune system, Mice, Humans, Animals, Staphylococcus aureus, Proteome, Multiple Organ Failure, Disease Models, Animal, Bacteremia, vascular glycocalyx, proteome, sepsis, DIA mass spectrometry, glycocalyx, vascular

Abstract

Vascular dysfunction and organ failure are two distinct, albeit highly interconnected, clinical outcomes linked to morbidity and mortality in human sepsis. The mechanisms driving vascular and parenchymal damage are dynamic and display significant molecular cross talk between organs and tissues. Therefore, assessing their individual contribution to disease progression is technically challenging. Here, we hypothesize that dysregulated vascular responses predispose the organism to organ failure. To address this hypothesis, we have evaluated four major organs in a murine model of Staphylococcus aureus sepsis by combining in vivo labeling of the endothelial cell surface proteome, data-independent acquisition (DIA) mass spectrometry, and an integrative computational pipeline. The data reveal, with unprecedented depth and throughput, that a septic insult evokes organ-specific proteome responses that are highly compartmentalized, synchronously coordinated, and significantly correlated with the progression of the disease. These responses include abundant vascular shedding, dysregulation of the intrinsic pathway of coagulation, compartmentalization of the acute phase response, and abundant upregulation of glycocalyx components. Vascular cell surface proteome changes were also found to precede bacterial invasion and leukocyte infiltration into the organs, as well as to precede changes in various well-established cellular and biochemical correlates of systemic coagulopathy and tissue dysfunction. Importantly, our data suggest a potential role for the vascular proteome as a determinant of the susceptibility of the organs to undergo failure during sepsis. IMPORTANCE Sepsis is a life-threatening response to infection that results in immune dysregulation, vascular dysfunction, and organ failure. New methods are needed for the identification of diagnostic and therapeutic targets. Here, we took a systems-wide approach using data-independent acquisition (DIA) mass spectrometry to track the progression of bacterial sepsis in the vasculature leading to organ failure. Using a murine model of S. aureus sepsis, we were able to quantify thousands of proteins across the plasma and parenchymal and vascular compartments of multiple organs in a time-resolved fashion. We showcase the profound proteome remodeling triggered by sepsis over time and across these compartments. Importantly, many vascular proteome alterations precede changes in traditional correlates of organ dysfunction, opening a molecular window for the discovery of early markers of sepsis progression.

Published

2022

3. Endothelial Heparan Sulfate Mediates Hepatic Neutrophil Trafficking and Injury during Staphylococcus aureus Sepsis

Author

Golden, Gregory J, Toledo, Alejandro Gómez, Marki, Alex, Sorrentino, James T, Morris, Claire, Riley, Raquel J, Spliid, Charlotte, Chen, Qiongyu, Cornax, Ingrid, Lewis, Nathan E, Varki, Nissi, Le, Dzung, Malmström, Johan, Karlsson, Christofer, Ley, Klaus, Nizet, Victor, and Esko, Jeffrey D

Subjects

Liver Disease, Sepsis, Infectious Diseases, Hematology, Digestive Diseases, Emerging Infectious Diseases, Clinical Research, Chronic Liver Disease and Cirrhosis, 2.1 Biological and endogenous factors, Aetiology, Cardiovascular, Inflammatory and immune system, Animals, Disease Models, Animal, Endothelial Cells, Female, Glycocalyx, Heparitin Sulfate, Liver, Lung, Male, Mice, Mice, Inbred C57BL, Neutrophil Activation, Neutrophils, Staphylococcus aureus, heparan sulfate, intravital microscopy, liver, neutrophils, proteomics, sepsis, thrombosis, Microbiology

Abstract

Hepatic failure is an important risk factor for poor outcome in septic patients. Using a chemical tagging workflow and high-resolution mass spectrometry, we demonstrate that rapid proteome remodeling of the vascular surfaces precedes hepatic damage in a murine model of Staphylococcus aureus sepsis. These early changes include vascular deposition of neutrophil-derived proteins, shedding of vascular receptors, and altered levels of heparin/heparan sulfate-binding factors. Modification of endothelial heparan sulfate, a major component of the vascular glycocalyx, diminishes neutrophil trafficking to the liver and reduces hepatic coagulopathy and organ damage during the systemic inflammatory response to infection. Modifying endothelial heparan sulfate likewise reduces neutrophil trafficking in sterile hepatic injury, reflecting a more general role of heparan sulfate contribution to the modulation of leukocyte behavior during inflammation. IMPORTANCE Vascular glycocalyx remodeling is critical to sepsis pathology, but the glycocalyx components that contribute to this process remain poorly characterized. This article shows that during Staphylococcus aureus sepsis, the liver vascular glycocalyx undergoes dramatic changes in protein composition associated with neutrophilic activity and heparin/heparan sulfate binding, all before organ damage is detectable by standard circulating liver damage markers or histology. Targeted manipulation of endothelial heparan sulfate modulates S. aureus sepsis-induced hepatotoxicity by controlling the magnitude of neutrophilic infiltration into the liver in both nonsterile and sterile injury. These data identify an important vascular glycocalyx component that impacts hepatic failure during nonsterile and sterile injury.

Published

2021

4. Correcting for sparsity and interdependence in glycomics by accounting for glycan biosynthesis.

Author

Bao, Bokan, Kellman, Benjamin P, Chiang, Austin WT, Zhang, Yujie, Sorrentino, James T, York, Austin K, Mohammad, Mahmoud A, Haymond, Morey W, Bode, Lars, and Lewis, Nathan E

Subjects

Humans, Fucosyltransferases, Gangliosides, Polysaccharides, Erythropoietin, Mucins, Cluster Analysis, Biological Transport, Glycosylation, Biosynthetic Pathways, Glycomics, Gene Knockout Techniques, Data Analysis

Abstract

Glycans are fundamental cellular building blocks, involved in many organismal functions. Advances in glycomics are elucidating the essential roles of glycans. Still, it remains challenging to properly analyze large glycomics datasets, since the abundance of each glycan is dependent on many other glycans that share many intermediate biosynthetic steps. Furthermore, the overlap of measured glycans can be low across samples. We address these challenges with GlyCompare, a glycomic data analysis approach that accounts for shared biosynthetic steps for all measured glycans to correct for sparsity and non-independence in glycomics, which enables direct comparison of different glycoprofiles and increases statistical power. Using GlyCompare, we study diverse N-glycan profiles from glycoengineered erythropoietin. We obtain biologically meaningful clustering of mutant cell glycoprofiles and identify knockout-specific effects of fucosyltransferase mutants on tetra-antennary structures. We further analyze human milk oligosaccharide profiles and find mother's fucosyltransferase-dependent secretor-status indirectly impact the sialylation. Finally, we apply our method on mucin-type O-glycans, gangliosides, and site-specific compositional glycosylation data to reveal tissues and disease-specific glycan presentations. Our substructure-oriented approach will enable researchers to take full advantage of the growing power and size of glycomics data.

Published

2021

5. A consensus-based and readable extension of Linear Code for Reaction Rules (LiCoRR)

Author

Kellman, Benjamin P, Zhang, Yujie, Logomasini, Emma, Meinhardt, Eric, Godinez-Macias, Karla P, Chiang, Austin WT, Sorrentino, James T, Liang, Chenguang, Bao, Bokan, Zhou, Yusen, Akase, Sachiko, Sogabe, Isami, Kouka, Thukaa, Winzeler, Elizabeth A, Wilson, Iain BH, Campbell, Matthew P, Neelamegham, Sriram, Krambeck, Frederick J, Aoki-Kinoshita, Kiyoko F, and Lewis, Nathan E

Subjects

Organic Chemistry, Chemical Sciences, glycoinformatics, linear code, systems glycobiology, Organic chemistry

Abstract

Systems glycobiology aims to provide models and analysis tools that account for the biosynthesis, regulation, and interactions with glycoconjugates. To facilitate these methods, there is a need for a clear glycan representation accessible to both computers and humans. Linear Code, a linearized and readily parsable glycan structure representation, is such a language. For this reason, Linear Code was adapted to represent reaction rules, but the syntax has drifted from its original description to accommodate new and originally unforeseen challenges. Here, we delineate the consensuses and inconsistencies that have arisen through this adaptation. We recommend options for a consensus-based extension of Linear Code that can be used for reaction rule specification going forward. Through this extension and specification of Linear Code to reaction rules, we aim to minimize inconsistent symbology thereby making glycan database queries easier. With a clear guide for generating reaction rule descriptions, glycan synthesis models will be more interoperable and reproducible thereby moving glycoinformatics closer to compliance with FAIR standards. Here, we present Linear Code for Reaction Rules (LiCoRR), version 1.0, an unambiguous representation for describing glycosylation reactions in both literature and code.

Published

2020

6. Vascular Proteome Responses Precede Organ Dysfunction in a Murine Model of Staphylococcus aureus Bacteremia

Author

Sorrentino, James T., Golden, Gregory J., Morris, Claire, Painter, Chelsea D., Nizet, Victor, Campos, Alexandre Rosa, Smith, Jeffrey W., Karlsson, Christofer, Malmström, Johan, Lewis, Nathan E., Esko, Jeffrey D., Toledo, Alejandro Gómez, and Schmidt, Frank

Subjects

DIA mass spectrometry, Staphylococcus aureus, Proteome, Animal, Multiple Organ Failure, vascular glycocalyx, Inflammatory and immune system, Bacteremia, Hematology, sepsis, Mice, Emerging Infectious Diseases, Infectious Diseases, SDG 3 - Good Health and Well-being, vascular, Disease Models, Animals, Humans, 2.1 Biological and endogenous factors, Aetiology, Infection, glycocalyx

Abstract

Vascular dysfunction and organ failure are two distinct, albeit highly interconnected, clinical outcomes linked to morbidity and mortality in human sepsis. The mechanisms driving vascular and parenchymal damage are dynamic and display significant molecular cross talk between organs and tissues. Therefore, assessing their individual contribution to disease progression is technically challenging. Here, we hypothesize that dysregulated vascular responses predispose the organism to organ failure. To address this hypothesis, we have evaluated four major organs in a murine model of Staphylococcus aureus sepsis by combining in vivo labeling of the endothelial cell surface proteome, data-independent acquisition (DIA) mass spectrometry, and an integrative computational pipeline. The data reveal, with unprecedented depth and throughput, that a septic insult evokes organ-specific proteome responses that are highly compartmentalized, synchronously coordinated, and significantly correlated with the progression of the disease. These responses include abundant vascular shedding, dysregulation of the intrinsic pathway of coagulation, compartmentalization of the acute phase response, and abundant upregulation of glycocalyx components. Vascular cell surface proteome changes were also found to precede bacterial invasion and leukocyte infiltration into the organs, as well as to precede changes in various well-established cellular and biochemical correlates of systemic coagulopathy and tissue dysfunction. Importantly, our data suggest a potential role for the vascular proteome as a determinant of the susceptibility of the organs to undergo failure during sepsis. IMPORTANCE Sepsis is a life-threatening response to infection that results in immune dysregulation, vascular dysfunction, and organ failure. New methods are needed for the identification of diagnostic and therapeutic targets. Here, we took a systems-wide approach using data-independent acquisition (DIA) mass spectrometry to track the progression of bacterial sepsis in the vasculature leading to organ failure. Using a murine model of S. aureus sepsis, we were able to quantify thousands of proteins across the plasma and parenchymal and vascular compartments of multiple organs in a time-resolved fashion. We showcase the profound proteome remodeling triggered by sepsis over time and across these compartments. Importantly, many vascular proteome alterations precede changes in traditional correlates of organ dysfunction, opening a molecular window for the discovery of early markers of sepsis progression.

Published

2022