Your search keyword '"Carten JD"' showing total 9 results

1. A Mechanistic Understanding of the Modes of Ca 2+ Ion Binding to the SARS-CoV-1 Fusion Peptide and Their Role in the Dynamics of Host Membrane Penetration.

Author

Carten JD, Khelashvili G, Bidon MK, Straus MR, Tang T, Jaimes JA, Whittaker GR, Weinstein H, and Daniel S

Subjects

Amino Acid Sequence, Calcium metabolism, Membrane Fusion physiology, Peptides chemistry, Ions, Severe acute respiratory syndrome-related coronavirus

Abstract

The SARS-CoV-1 spike glycoprotein contains a fusion peptide (FP) segment that mediates the fusion of the viral and host cell membranes. Calcium ions are thought to position the FP optimally for membrane insertion by interacting with negatively charged residues in this segment (E801, D802, D812, E821, D825, and D830); however, which residues bind to calcium and in what combinations supportive of membrane insertion are unknown. Using biological assays and molecular dynamics studies, we have determined the functional configurations of FP-Ca 2+ binding that likely promote membrane insertion. We first individually mutated the negatively charged residues in the SARS CoV-1 FP to assay their roles in cell entry and syncytia formation, finding that charge loss in the D802A or D830A mutants greatly reduced syncytia formation and pseudoparticle transduction of VeroE6 cells. Interestingly, one mutation (D812A) led to a modest increase in cell transduction, further indicating that FP function likely depends on calcium binding at specific residues and in specific combinations. To interpret these results mechanistically and identify specific modes of FP-Ca 2+ binding that modulate membrane insertion, we performed molecular dynamics simulations of the SARS-CoV-1 FP and Ca 2+ ions. The preferred residue pairs for Ca 2+ binding we identified (E801/D802, E801/D830, and D812/E821) include the two residues found to be essential for S function in our biological studies (D802 and D830). The three preferred Ca 2+ binding pairs were also predicted to promote FP membrane insertion. We also identified a Ca 2+ binding pair (E821/D825) predicted to inhibit FP membrane insertion. We then carried out simulations in the presence of membranes and found that binding of Ca 2+ to SARS-CoV-1 FP residue pairs E801/D802 and D812/E821 facilitates membrane insertion by enabling the peptide to adopt conformations that shield the negative charges of the FP to reduce repulsion by the membrane phospholipid headgroups. This calcium binding mode also optimally positions the hydrophobic LLF region of the FP for membrane penetration. Conversely, Ca 2+ binding to the FP E801/D802 and D821/D825 pairs eliminates the negative charge screening and instead creates a repulsive negative charge that hinders membrane penetration of the LLF motif. These computational results, taken together with our biological studies, provide an improved and nuanced mechanistic understanding of the dymanics of SARS-CoV-1 calcium binding and their potential effects on host cell entry.

Published

2024

2. An Impedance-Based Approach for Sensing Cyclodextrin-Mediated Modulation of Membrane Cholesterol.

Author

Bint E Naser SF, Liu HY, Su H, Kouloumpis A, Carten JD, and Daniel S

Subjects

Electric Impedance, Cell Membrane metabolism, Lipid Bilayers metabolism, Cholesterol metabolism, Membrane Microdomains metabolism, Cyclodextrins

Abstract

Cyclodextrin molecules are increasingly being used in biological research and as therapeutic agents to alter membrane cholesterol content, yet there is much to learn about their interactions with cell membranes. We present a biomembrane-based organic electronic platform capable of detecting interactions of cell membrane constituents with methyl-β-cyclodextrin (MβCD). This approach enables label-free sensing and quantification of changes in membrane integrity resulting from such interactions. In this work, we employ cholesterol-containing supported lipid bilayers (SLBs) formed on conducting polymer-coated electrodes to investigate how MβCD impacts membrane resistance. By examining the outcomes of MβCD interactions with SLBs of varying cholesterol content, we demonstrate that changes in membrane permeability or resistance can be used as a functional measure for predicting cyclodextrin-mediated cholesterol extraction from cellular membranes. Furthermore, we use the SLB platforms to electronically monitor cholesterol delivery to membranes following exposure to MβCD pre-loaded with cholesterol, observing that cholesterol enrichment is commensurate with an increase in resistance. This biomembrane-based bioelectronic sensing system offers a tool to quantify the modulation of membrane cholesterol content using membrane resistance and provides information regarding MβCD-mediated changes in membrane integrity. Given the importance of membrane integrity for barrier function in cells, such knowledge is essential for our fundamental understanding of MβCD as a membrane cholesterol modulator and therapeutic delivery vehicle.

Published

2023

3. A human iPSC-derived hepatocyte screen identifies compounds that inhibit production of Apolipoprotein B.

Author

Liu JT, Doueiry C, Jiang YL, Blaszkiewicz J, Lamprecht MP, Heslop JA, Peterson YK, Carten JD, Traktman P, Yuan Y, Khetani SR, Twal WO, and Duncan SA

Subjects

Humans, Animals, Mice, Proprotein Convertase 9 genetics, Proprotein Convertase 9 pharmacology, Proprotein Convertase 9 therapeutic use, Cholesterol, LDL, Apolipoproteins B genetics, Apolipoproteins B pharmacology, Apolipoproteins B therapeutic use, Hepatocytes, Induced Pluripotent Stem Cells, Homozygous Familial Hypercholesterolemia, Hyperlipoproteinemia Type II drug therapy, Hyperlipoproteinemia Type II genetics, Anticholesteremic Agents pharmacology

Abstract

Familial hypercholesterolemia (FH) patients suffer from excessively high levels of Low Density Lipoprotein Cholesterol (LDL-C), which can cause severe cardiovascular disease. Statins, bile acid sequestrants, PCSK9 inhibitors, and cholesterol absorption inhibitors are all inefficient at treating FH patients with homozygous LDLR gene mutations (hoFH). Drugs approved for hoFH treatment control lipoprotein production by regulating steady-state Apolipoprotein B (apoB) levels. Unfortunately, these drugs have side effects including accumulation of liver triglycerides, hepatic steatosis, and elevated liver enzyme levels. To identify safer compounds, we used an iPSC-derived hepatocyte platform to screen a structurally representative set of 10,000 small molecules from a proprietary library of 130,000 compounds. The screen revealed molecules that could reduce the secretion of apoB from cultured hepatocytes and from humanized livers in mice. These small molecules are highly effective, do not cause abnormal lipid accumulation, and share a chemical structure that is distinct from any known cholesterol lowering drug., (© 2023. The Author(s).)

Published

2023

4. Structure-Function Analysis of Two Interacting Vaccinia Proteins That Are Critical for Viral Morphogenesis: L2 and A30.5.

Author

Carten JD, Greseth M, and Traktman P

Subjects

Amino Acid Motifs, Animals, Cell Line, Endoplasmic Reticulum metabolism, Genetic Complementation Test, Mutation, Protein Binding, Protein Conformation, alpha-Helical, Protein Stability, Vaccinia virus genetics, Vaccinia virus metabolism, Vaccinia virus ultrastructure, Viral Nonstructural Proteins chemistry, Viral Nonstructural Proteins genetics, Virion metabolism, Virion ultrastructure, Virus Assembly, Morphogenesis, Vaccinia virus growth & development, Viral Nonstructural Proteins metabolism

Abstract

An enduring mystery in poxvirology is the mechanism by which virion morphogenesis is accomplished. A30.5 and L2 are two small regulatory proteins that are essential for this process. Previous studies have shown that vaccinia A30.5 and L2 localize to the ER and interact during infection, but how they facilitate morphogenesis is unknown. To interrogate the relationship between A30.5 and L2, we generated inducible complementing cell lines (CV1-HA-L2; CV1-3xFLAG-A30.5) and deletion viruses (vΔL2; vΔA30.5). Loss of either protein resulted in a block in morphogenesis and a significant (>100-fold) decrease in infectious viral yield. Structure-function analysis of L2 and A30.5, using transient complementation assays, identified key functional regions in both proteins. A clustered charge-to-alanine L2 mutant (L2-RRD) failed to rescue a vΔL2 infection and exhibits a significantly retarded apparent molecular weight in vivo (but not in vitro ), suggestive of an aberrant posttranslational modification. Furthermore, an A30.5 mutant with a disrupted putative N-terminal α-helix failed to rescue a vΔA30.5 infection. Using our complementing cell lines, we determined that the stability of A30.5 is dependent on L2 and that wild-type L2 and A30.5 coimmunoprecipitate in the absence of other viral proteins. Further examination of this interaction, using wild-type and mutant forms of L2 or A30.5, revealed that the inability of mutant alleles to rescue the respective deletion viruses is tightly correlated with a failure of L2 to stabilize and interact with A30.5. L2 appears to function as a chaperone-like protein for A30.5, ensuring that they work together as a complex during viral membrane biogenesis. IMPORTANCE Vaccinia virus is a large, enveloped DNA virus that was successfully used as the vaccine against smallpox. Vaccinia continues to be an invaluable biomedical research tool in basic research and in gene therapy vector and vaccine development. Although this virus has been studied extensively, the complex process of virion assembly, termed morphogenesis, still puzzles the field. Our work aims to better understand how two small viral proteins that are essential for viral assembly, L2 and A30.5, function during early morphogenesis. We show that A30.5 requires L2 for stability and that these proteins interact in the absence of other viral proteins. We identify regions in each protein required for their function and show that mutations in these regions disrupt the interaction between L2 and A30.5 and fail to restore virus viability.

Published

2022

5. Using fluorescent lipids in live zebrafish larvae: From imaging whole animal physiology to subcellular lipid trafficking.

Author

Anderson JL, Carten JD, and Farber SA

Subjects

Animals, Larva metabolism, Lipid Metabolism, Lipids analysis, Optical Imaging methods, Zebrafish growth & development, Zebrafish metabolism

Abstract

Lipids serve essential functions in cells as signaling molecules, membrane components, and sources of energy. Defects in lipid metabolism are implicated in a number of pandemic human diseases, including diabetes, obesity, and hypercholesterolemia. Many aspects of how fatty acids and cholesterol are absorbed and processed by intestinal cells remain unclear and present a hurdle to developing approaches for disease prevention and treatment. Numerous studies have shown that the zebrafish is an excellent model for vertebrate lipid metabolism. In this chapter, we review commercially available fluorescent lipids that can be deployed in live zebrafish to better understand lipid signaling and metabolism. In this chapter, we present criteria one should consider when selecting specific fluorescent lipids for the study of digestive physiology or lipid metabolism in larval zebrafish., (Copyright © 2016 Elsevier Inc. All rights reserved.)

Published

2016

6. Microbiota regulate intestinal absorption and metabolism of fatty acids in the zebrafish.

Author

Semova I, Carten JD, Stombaugh J, Mackey LC, Knight R, Farber SA, and Rawls JF

Subjects

Animals, Diet, Energy Metabolism, Fluorescence, Image Processing, Computer-Assisted, Intestinal Absorption, Intestinal Mucosa metabolism, Intestines microbiology, Liver metabolism, Fatty Acids metabolism, Metagenome, Zebrafish metabolism, Zebrafish microbiology

Abstract

Regulation of intestinal dietary fat absorption is critical to maintaining energy balance. While intestinal microbiota clearly impact the host's energy balance, their role in intestinal absorption and extraintestinal metabolism of dietary fat is less clear. Using in vivo imaging of fluorescent fatty acid (FA) analogs delivered to gnotobiotic zebrafish hosts, we reveal that microbiota stimulate FA uptake and lipid droplet (LD) formation in the intestinal epithelium and liver. Microbiota increase epithelial LD number in a diet-dependent manner. The presence of food led to the intestinal enrichment of bacteria from the phylum Firmicutes. Diet-enriched Firmicutes and their products were sufficient to increase epithelial LD number, whereas LD size was increased by other bacterial types. Thus, different members of the intestinal microbiota promote FA absorption via distinct mechanisms. Diet-induced alterations in microbiota composition might influence fat absorption, providing mechanistic insight into how microbiota-diet interactions regulate host energy balance., (Copyright © 2012 Elsevier Inc. All rights reserved.)

Published

2012

7. Visualizing digestive organ morphology and function using differential fatty acid metabolism in live zebrafish.

Author

Carten JD, Bradford MK, and Farber SA

Subjects

Animals, Biological Transport, Boron Compounds, Digestive System anatomy & histology, Digestive System metabolism, Egg Yolk metabolism, Fluorescent Dyes, Larva anatomy & histology, Larva physiology, Lipid Metabolism, Liposomes, Microscopy, Fluorescence, Palmitic Acids, Zebrafish anatomy & histology, Zebrafish Proteins metabolism, Fatty Acids metabolism, Zebrafish physiology

Abstract

Lipids are essential for cellular function as sources of fuel, critical signaling molecules and membrane components. Deficiencies in lipid processing and transport underlie many metabolic diseases. To better understand metabolic function as it relates to disease etiology, a whole animal approach is advantageous, one in which multiple organs and cell types can be assessed simultaneously in vivo. Towards this end, we have developed an assay to visualize fatty acid (FA) metabolism in larval zebrafish (Danio rerio). The method utilizes egg yolk liposomes to deliver different chain length FA analogs (BODIPY-FL) to six day-old larvae. Following liposome incubation, larvae accumulate the analogs throughout their digestive organs, providing a comprehensive readout of organ structure and physiology. Using this assay we have observed that different chain length FAs are differentially transported and metabolized by the larval digestive system. We show that this assay can also reveal structural and metabolic defects in digestive mutants. Because this labeling technique can be used to investigate digestive organ morphology and function, we foresee its application in diverse studies of organ development and physiology., (Copyright © 2011 Elsevier Inc. All rights reserved.)

Published

2011

8. Zebrafish lipid metabolism: from mediating early patterning to the metabolism of dietary fat and cholesterol.

Author

Anderson JL, Carten JD, and Farber SA

Subjects

Animals, Humans, Cholesterol metabolism, Dietary Fats metabolism, Lipid Metabolism physiology, Zebrafish metabolism

Abstract

Lipids serve essential functions in cells as signaling molecules, membrane components, and sources of energy. Defects in lipid metabolism are implicated in a number of pandemic human diseases, including diabetes, obesity, and hypercholesterolemia. Many aspects of how fatty acids and cholesterol are absorbed and processed by intestinal cells remain unclear and present a hurdle to developing approaches for disease prevention and treatment. Numerous studies have shown that the zebrafish is an excellent model for vertebrate lipid metabolism. In this chapter, we review studies that employ zebrafish to better understand lipid signaling and metabolism., (Copyright © 2011 Elsevier Inc. All rights reserved.)

Published

2011

9. A new model system swims into focus: using the zebrafish to visualize intestinal metabolism in vivo.

Author

Carten JD and Farber SA

Abstract

Many fundamental questions remain regarding the cellular and molecular mechanisms of digestive lipid metabolism. One major impediment to answering important questions in the field has been the lack of a tractable and sufficiently complex model system. Until recently, most studies of lipid metabolism have been performed in vitro or in mice, yet each approach possesses certain limitations. The zebrafish (Danio rerio) offers an excellent model system in which to study lipid metabolism in vivo, owing to its small size, genetic tractability and optical clarity. Fluorescent lipid dyes and optical reporters of lipid-modifying enzymes are now being used in live zebrafish to generate visible readouts of digestive physiology. Here we review recent advances in visualizing intestinal lipid metabolism in live larval zebrafish.

Published

2009