Your search keyword '"Jessica Siltberg-Liberles"' showing total 9 results

1. Potential Autoimmunity Resulting from Molecular Mimicry between SARS-CoV-2 Spike and Human Proteins

Author

Janelle Nunez-Castilla, Vitalii Stebliankin, Prabin Baral, Christian A. Balbin, Masrur Sobhan, Trevor Cickovski, Ananda Mohan Mondal, Giri Narasimhan, Prem Chapagain, Kalai Mathee, and Jessica Siltberg-Liberles

Subjects

vaccine design, AlphaFold2, coronavirus, molecular dynamics, machine learning, protein structure comparison, Microbiology, QR1-502

Abstract

Molecular mimicry between viral antigens and host proteins can produce cross-reacting antibodies leading to autoimmunity. The coronavirus SARS-CoV-2 causes COVID-19, a disease curiously resulting in varied symptoms and outcomes, ranging from asymptomatic to fatal. Autoimmunity due to cross-reacting antibodies resulting from molecular mimicry between viral antigens and host proteins may provide an explanation. Thus, we computationally investigated molecular mimicry between SARS-CoV-2 Spike and known epitopes. We discovered molecular mimicry hotspots in Spike and highlight two examples with tentative high autoimmune potential and implications for understanding COVID-19 complications. We show that a TQLPP motif in Spike and thrombopoietin shares similar antibody binding properties. Antibodies cross-reacting with thrombopoietin may induce thrombocytopenia, a condition observed in COVID-19 patients. Another motif, ELDKY, is shared in multiple human proteins, such as PRKG1 involved in platelet activation and calcium regulation, and tropomyosin, which is linked to cardiac disease. Antibodies cross-reacting with PRKG1 and tropomyosin may cause known COVID-19 complications such as blood-clotting disorders and cardiac disease, respectively. Our findings illuminate COVID-19 pathogenesis and highlight the importance of considering autoimmune potential when developing therapeutic interventions to reduce adverse reactions.

Published

2022

2. Comparative Analysis of Structural Features in SLiMs from Eukaryotes, Bacteria, and Viruses with Importance for Host-Pathogen Interactions

Author

Heidy Elkhaligy, Christian A. Balbin, and Jessica Siltberg-Liberles

Subjects

short linear motifs, SLiMs, ELM database, intrinsic disordered protein regions, molecular mimicry, protein flexibility, Medicine

Abstract

Protein-protein interactions drive functions in eukaryotes that can be described by short linear motifs (SLiMs). Conservation of SLiMs help illuminate functional SLiMs in eukaryotic protein families. However, the simplicity of eukaryotic SLiMs makes them appear by chance due to mutational processes not only in eukaryotes but also in pathogenic bacteria and viruses. Further, functional eukaryotic SLiMs are often found in disordered regions. Although proteomes from pathogenic bacteria and viruses have less disorder than eukaryotic proteomes, their proteins can successfully mimic eukaryotic SLiMs and disrupt host cellular function. Identifying important SLiMs in pathogens is difficult but essential for understanding potential host-pathogen interactions. We performed a comparative analysis of structural features for experimentally verified SLiMs from the Eukaryotic Linear Motif (ELM) database across viruses, bacteria, and eukaryotes. Our results revealed that many viral SLiMs and specific motifs found across viruses and eukaryotes, such as some glycosylation motifs, have less disorder. Analyzing the disorder and coil properties of equivalent SLiMs from pathogens and eukaryotes revealed that some motifs are more structured in pathogens than their eukaryotic counterparts and vice versa. These results support a varying mechanism of interaction between pathogens and their eukaryotic hosts for some of the same motifs.

Published

2022

3. Dynamic, but Not Necessarily Disordered, Human-Virus Interactions Mediated through SLiMs in Viral Proteins

Author

Heidy Elkhaligy, Christian A. Balbin, Jessica L. Gonzalez, Teresa Liberatore, and Jessica Siltberg-Liberles

Subjects

short eukaryotic linear motifs, SLiMs, viral-host protein interaction, intrinsically disordered protein regions, the ELM database, Microbiology, QR1-502

Abstract

Most viruses have small genomes that encode proteins needed to perform essential enzymatic functions. Across virus families, primary enzyme functions are under functional constraint; however, secondary functions mediated by exposed protein surfaces that promote interactions with the host proteins may be less constrained. Viruses often form transient interactions with host proteins through conformationally flexible interfaces. Exposed flexible amino acid residues are known to evolve rapidly suggesting that secondary functions may generate diverse interaction potentials between viruses within the same viral family. One mechanism of interaction is viral mimicry through short linear motifs (SLiMs) that act as functional signatures in host proteins. Viral SLiMs display specific patterns of adjacent amino acids that resemble their host SLiMs and may occur by chance numerous times in viral proteins due to mutational and selective processes. Through mimicry of SLiMs in the host cell proteome, viruses can interfere with the protein interaction network of the host and utilize the host-cell machinery to their benefit. The overlap between rapidly evolving protein regions and the location of functionally critical SLiMs suggest that these motifs and their functional potential may be rapidly rewired causing variation in pathogenicity, infectivity, and virulence of related viruses. The following review provides an overview of known viral SLiMs with select examples of their role in the life cycle of a virus, and a discussion of the structural properties of experimentally validated SLiMs highlighting that a large portion of known viral SLiMs are devoid of predicted intrinsic disorder based on the viral SLiMs from the ELM database.

Published

2021

4. Functional Diversification after Gene Duplication: Paralog Specific Regions of Structural Disorder and Phosphorylation in p53, p63, and p73.

Author

Helena G Dos Santos, Janelle Nunez-Castilla, and Jessica Siltberg-Liberles

Subjects

Medicine, Science

Abstract

Conformational and functional flexibility promote protein evolvability. High evolvability allows related proteins to functionally diverge and perhaps to neostructuralize. p53 is a multifunctional protein frequently referred to as the Guardian of the Genome-a hub for e.g. incoming and outgoing signals in apoptosis and DNA repair. p53 has been found to be structurally disordered, an extreme form of conformational flexibility. Here, p53, and its paralogs p63 and p73, were studied for further insights into the evolutionary dynamics of structural disorder, secondary structure, and phosphorylation. This study is focused on the post gene duplication phase for the p53 family in vertebrates, but also visits the origin of the protein family and the early domain loss and gain events. Functional divergence, measured by rapid evolutionary dynamics of protein domains, structural properties, and phosphorylation propensity, is inferred across vertebrate p53 proteins, in p63 and p73 from fish, and between the three paralogs. In particular, structurally disordered regions are redistributed among paralogs, but within clades redistribution of structural disorder also appears to be an ongoing process. Despite its deemed importance as the Guardian of the Genome, p53 is indeed a protein with high evolvability as seen not only in rearranged structural disorder, but also in fluctuating domain sequence signatures among lineages.

Published

2016

5. Dynamic, but Not Necessarily Disordered, Human-Virus Interactions Mediated through SLiMs in Viral Proteins

Author

Jessica L. Gonzalez, Teresa Liberatore, Christian A. Balbin, Jessica Siltberg-Liberles, and Heidy Elkhaligy

Subjects

Proteome, viruses, Amino Acid Motifs, viral-host protein interaction, Virulence, Computational biology, Review, Biology, Microbiology, Genome, Virus, Viral Proteins, Interaction network, Virology, Humans, Short linear motif, Protein Interaction Maps, Databases, Protein, Virus classification, intrinsically disordered protein regions, the ELM database, short eukaryotic linear motifs, QR1-502, SLiMs, Intrinsically Disordered Proteins, Infectious Diseases, Host-Pathogen Interactions, Viruses, Human Virus

Abstract

Most viruses have small genomes that encode proteins needed to perform essential enzymatic functions. Across virus families, primary enzyme functions are under functional constraint; however, secondary functions mediated by exposed protein surfaces that promote interactions with the host proteins may be less constrained. Viruses often form transient interactions with host proteins through conformationally flexible interfaces. Exposed flexible amino acid residues are known to evolve rapidly suggesting that secondary functions may generate diverse interaction potentials between viruses within the same viral family. One mechanism of interaction is viral mimicry through short linear motifs (SLiMs) that act as functional signatures in host proteins. Viral SLiMs display specific patterns of adjacent amino acids that resemble their host SLiMs and may occur by chance numerous times in viral proteins due to mutational and selective processes. Through mimicry of SLiMs in the host cell proteome, viruses can interfere with the protein interaction network of the host and utilize the host-cell machinery to their benefit. The overlap between rapidly evolving protein regions and the location of functionally critical SLiMs suggest that these motifs and their functional potential may be rapidly rewired causing variation in pathogenicity, infectivity, and virulence of related viruses. The following review provides an overview of known viral SLiMs with select examples of their role in the life cycle of a virus, and a discussion of the structural properties of experimentally validated SLiMs highlighting that a large portion of known viral SLiMs are devoid of predicted intrinsic disorder based on the viral SLiMs from the ELM database.

Published

2021

6. Interaction of Peptide Aptamers with Prion Protein Central Domain Promotes α-Cleavage of PrPC

Author

Erica Corda, Su Yeon Shim, Jessica Siltberg-Liberles, Sabine Gilch, Antonia N. Klein, and Xiaotang Du

Subjects

0301 basic medicine, Gene isoform, Peptide aptamer, In silico, media_common.quotation_subject, medicine.medical_treatment, animal diseases, Protein domain, Neuroscience (miscellaneous), Peptide Aptamers, Prion disease, Cleavage (embryo), Neurodegenerative disease, Article, 03 medical and health sciences, Cellular and Molecular Neuroscience, Mice, Thioredoxins, Protein Domains, Prion protein PrP, Cell Line, Tumor, medicine, Animals, Humans, Computer Simulation, PrPC Proteins, Amino Acid Sequence, Prion protein, Internalization, media_common, Protease, Binding Sites, Chemistry, 3. Good health, Cell biology, nervous system diseases, Treatment, 030104 developmental biology, Neurology, Amino Acid Substitution, PrP α-cleavage, Mutant Proteins, Aptamers, Peptide, Protein Binding

Abstract

Prion diseases are infectious and fatal neurodegenerative diseases affecting humans and animals. Transmission is possible within and between species with zoonotic potential. Currently, no prophylaxis or treatment exists. Prions are composed of the misfolded isoform PrPSc of the cellular prion protein PrPC. Expression of PrPC is a prerequisite for prion infection, and conformational conversion of PrPC is induced upon its direct interaction with PrPSc. Inhibition of this interaction can abrogate prion propagation, and we have previously established peptide aptamers (PAs) binding to PrPC as new anti-prion compounds. Here, we mapped the interaction site of PA8 in PrP and modeled the complex in silico to design targeted mutations in PA8 which presumably enhance binding properties. Using these PA8 variants, we could improve PA-mediated inhibition of PrPSc replication and de novo infection of neuronal cells. Furthermore, we demonstrate that binding of PA8 and its variants increases PrPC α-cleavage and interferes with its internalization. This gives rise to high levels of the membrane-anchored PrP-C1 fragment, a transdominant negative inhibitor of prion replication. PA8 and its variants interact with PrPC at its central and most highly conserved domain, a region which is crucial for prion conversion and facilitates toxic signaling of Aβ oligomers characteristic for Alzheimer’s disease. Our strategy allows for the first time to induce α-cleavage, which occurs within this central domain, independent of targeting the responsible protease. Therefore, interaction of PAs with PrPC and enhancement of α-cleavage represent mechanisms that can be beneficial for the treatment of prion and other neurodegenerative diseases. Electronic supplementary material The online version of this article (10.1007/s12035-018-0944-9) contains supplementary material, which is available to authorized users.

Published

2018

7. Large-Scale Analyses of Site-Specific Evolutionary Rates across Eukaryote Proteomes Reveal Confounding Interactions between Intrinsic Disorder, Secondary Structure, and Functional Domains

Author

Joseph B. Ahrens, Jordon Rahaman, and Jessica Siltberg-Liberles

Subjects

0301 basic medicine, evolutionary rates, Saccharomycetes, biology, lcsh:QH426-470, Eukaryotes, intrinsic disorder, biology.organism_classification, Alveolate, Article, 03 medical and health sciences, lcsh:Genetics, protein sequence, 030104 developmental biology, Protein sequencing, Evolutionary biology, Proteome, Genetics, Nucleic acid, Eukaryote, Protein secondary structure, Genetics (clinical), Sequence (medicine), structural prediction

Abstract

Various structural and functional constraints govern the evolution of protein sequences. As a result, the relative rates of amino acid replacement among sites within a protein can vary significantly. Previous large-scale work on Metazoan (Animal) protein sequence alignments indicated that amino acid replacement rates are partially driven by a complex interaction among three factors: intrinsic disorder propensity, secondary structure, and functional domain involvement. Here, we use sequence-based predictors to evaluate the effects of these factors on site-specific sequence evolutionary rates within four eukaryotic lineages: Metazoans, Plants, Saccharomycete Fungi, and Alveolate Protists. Our results show broad, consistent trends across all four Eukaryote groups. In all four lineages, there is a significant increase in amino acid replacement rates when comparing: (i) disordered vs. ordered sites, (ii) random coil sites vs. sites in secondary structures, and (iii) inter-domain linker sites vs. sites in functional domains. Additionally, within Metazoans, Plants, and Saccharomycetes, there is a strong confounding interaction between intrinsic disorder and secondary structure&mdash, alignment sites exhibiting both high disorder propensity and involvement in secondary structures have very low average rates of sequence evolution. Analysis of gene ontology (GO) terms revealed that in all four lineages, a high fraction of sequences containing these conserved, disordered-structured sites are involved in nucleic acid binding. We also observe notable differences in the statistical trends of Alveolates, where intrinsically disordered sites are more variable than in other Eukaryotes and the statistical interactions between disorder and other factors are less pronounced.

Published

2018

8. Functional Diversification after Gene Duplication: Paralog Specific Regions of Structural Disorder and Phosphorylation in p53, p63, and p73

Author

Janelle Nunez-Castilla, Helena G. Dos Santos, and Jessica Siltberg-Liberles

Subjects

0301 basic medicine, lcsh:Medicine, Protein Structure Prediction, Biochemistry, Protein Structure, Secondary, Database and Informatics Methods, Protein structure, Gene Duplication, Gene duplication, Macromolecular Structure Analysis, Post-Translational Modification, Phosphorylation, lcsh:Science, Genetics, Multidisciplinary, Nuclear Proteins, Phylogenetic Analysis, Protein structure prediction, DNA-Binding Proteins, Vertebrates, Sequence Analysis, Research Article, Multiple Alignment Calculation, Protein Structure, Protein family, Protein domain, Sequence Databases, Sequence alignment, Biology, Research and Analysis Methods, 03 medical and health sciences, Protein Domains, Computational Techniques, Animals, Molecular Biology Techniques, Sequencing Techniques, Molecular Biology, Molecular Biology Assays and Analysis Techniques, Tumor Suppressor Proteins, lcsh:R, Organisms, Biology and Life Sciences, Proteins, Tumor Protein p73, Split-Decomposition Method, Protein Structure, Tertiary, Evolvability, 030104 developmental biology, Biological Databases, Evolutionary biology, lcsh:Q, Tumor Suppressor Protein p53, Sequence Alignment, Functional divergence

Abstract

Conformational and functional flexibility promote protein evolvability. High evolvability allows related proteins to functionally diverge and perhaps to neostructuralize. p53 is a multifunctional protein frequently referred to as the Guardian of the Genome–a hub for e.g. incoming and outgoing signals in apoptosis and DNA repair. p53 has been found to be structurally disordered, an extreme form of conformational flexibility. Here, p53, and its paralogs p63 and p73, were studied for further insights into the evolutionary dynamics of structural disorder, secondary structure, and phosphorylation. This study is focused on the post gene duplication phase for the p53 family in vertebrates, but also visits the origin of the protein family and the early domain loss and gain events. Functional divergence, measured by rapid evolutionary dynamics of protein domains, structural properties, and phosphorylation propensity, is inferred across vertebrate p53 proteins, in p63 and p73 from fish, and between the three paralogs. In particular, structurally disordered regions are redistributed among paralogs, but within clades redistribution of structural disorder also appears to be an ongoing process. Despite its deemed importance as the Guardian of the Genome, p53 is indeed a protein with high evolvability as seen not only in rearranged structural disorder, but also in fluctuating domain sequence signatures among lineages.

Published

2016

9. The Evolution of Protein Structures and Structural Ensembles Under Functional Constraint

Author

Johan A. Grahnen, Jessica Siltberg-Liberles, and David A. Liberles

Subjects

lcsh:QH426-470, Fitness landscape, Protein Data Bank (RCSB PDB), Computational biology, Review, Biology, 03 medical and health sciences, Protein sequencing, Protein structure, Genetics, conformational ensemble, Conformational ensembles, Genetics (clinical), 030304 developmental biology, Sequence (medicine), 0303 health sciences, 030302 biochemistry & molecular biology, computer.file_format, Protein Data Bank, multiscale modeling, lcsh:Genetics, sequence-structure-function-evolution relationships, structural disorder, computer, Function (biology)

Abstract

Protein sequence, structure, and function are inherently linked through evolution and population genetics. Our knowledge of protein structure comes from solved structures in the Protein Data Bank (PDB), our knowledge of sequence through sequences found in the NCBI sequence databases (http://www.ncbi.nlm.nih.gov/), and our knowledge of function through a limited set of in-vitro biochemical studies. How these intersect through evolution is described in the first part of the review. In the second part, our understanding of a series of questions is addressed. This includes how sequences evolve within structures, how evolutionary processes enable structural transitions, how the folding process can change through evolution and what the fitness impacts of this might be. Moving beyond static structures, the evolution of protein kinetics (including normal modes) is discussed, as is the evolution of conformational ensembles and structurally disordered proteins. This ties back to a question of the role of neostructuralization and how it relates to selection on sequences for functions. The relationship between metastability, the fitness landscape, sequence divergence, and organismal effective population size is explored. Lastly, a brief discussion of modeling the evolution of sequences of ordered and disordered proteins is entertained.

Published

2011