Your search keyword '"Tompa, Peter"' showing total 104 results

1. Recurrent evolution of adhesive defence systems in amphibians by parallel shifts in gene expression.

Author

Zaman, Shabnam, Lengerer, Birgit, Van Lindt, Joris, Saenen, Indra, Russo, Giorgio, Bossaer, Laura, Carpentier, Sebastien, Tompa, Peter, Flammang, Patrick, and Roelants, Kim

Subjects

AMPHIBIANS, GENE expression, CHEMICAL templates, ADHESIVES, CHEMICAL models

Abstract

Natural selection can drive organisms to strikingly similar adaptive solutions, but the underlying molecular mechanisms often remain unknown. Several amphibians have independently evolved highly adhesive skin secretions (glues) that support a highly effective antipredator defence mechanism. Here we demonstrate that the glue of the Madagascan tomato frog, Dyscophus guineti, relies on two interacting proteins: a highly derived member of a widespread glycoprotein family and a galectin. Identification of homologous proteins in other amphibians reveals that these proteins attained a function in skin long before glues evolved. Yet, major elevations in their expression, besides structural changes in the glycoprotein (increasing its structural disorder and glycosylation), caused the independent rise of glues in at least two frog lineages. Besides providing a model for the chemical functioning of animal adhesive secretions, our findings highlight how recruiting ancient molecular templates may facilitate the recurrent evolution of functional innovations. Some amphibians defend themselves against predators by producing a highly adhesive skin secretion, effectively preventing their ingestion. This study shows how changes in the structure and expression of two proteins underlay the parallel evolution of these defence glues in different frog lineages. [ABSTRACT FROM AUTHOR]

Published

2024

2. Improved Expression of Aggregation-Prone Tau Proteins Using a Spidroin-Derived Solubility Tag.

Author

Muwonge, Kevin, Yaman, Bedri, Mészáros, Attila, Russo, Giorgio, Volkov, Alexander, and Tompa, Peter

Subjects

RECOMBINANT proteins, TAUOPATHIES, ESCHERICHIA coli, NUCLEAR magnetic resonance, CHIMERIC proteins, TAU proteins

Abstract

Tauopathies, a group of neurodegenerative disorders, are characterized by the abnormal aggregation of microtubule-associated Tau proteins in neurons and glial cells. The process of Tau proteins transitioning from soluble, intrinsically disordered monomers to disease-associated aggregates is still unclear. Investigating these molecular mechanisms requires the reconstitution of such processes in cellular and in vitro models using recombinant proteins at high purity and yield. However, the production of phase-separating or aggregation-prone recombinant proteins like Tau's hydrophobic-rich domains or disease mutation-carrying variants on a large scale is highly challenging due to their limited solubility. To overcome this challenge, we have developed an improved strategy for expressing and purifying recombinant Tau proteins using the major ampullate spidroin-derived solubility tag (MaSp-NT*). This approach involves using NT* as a fusion tag to enhance the solubility and stability of expressed proteins by forming micelle-like particles within the cytosol of E. coli cells. We found that fusion with the NT* tag significantly increased the solubility and yield of highly hydrophobic and/or aggregation-prone Tau constructs. Our purification method for NT* fusion proteins yielded up to twenty-fold higher amounts than proteins purified using our novel tandem-tag (6xHis-SUMO-Tau-Heparin) purification system. This enhanced expression and yield were demonstrated with full-length Tau (hT40/Tau441), its particularly aggregation-prone repeat domain (Tau-MTBR), and Frontotemporal dementia (FTD)-associated mutant (Tau-P301L). These advancements offer promising avenues for the production of large quantities of Tau proteins suitable for in vitro experimental techniques such as nuclear magnetic resonance (NMR) spectroscopy without the need for a boiling step, bringing us closer to effective treatments for tauopathies. [ABSTRACT FROM AUTHOR]

Published

2024

3. A cyclin D1 intrinsically disordered domain accesses modified histone motifs to govern gene transcription.

Author

Jiao, Xuanmao, Di Sante, Gabriele, Casimiro, Mathew C., Tantos, Agnes, Ashton, Anthony W., Li, Zhiping, Quach, Yen, Bhargava, Dharmendra, Di Rocco, Agnese, Pupo, Claudia, Crosariol, Marco, Lazar, Tamas, Tompa, Peter, Wang, Chenguang, Yu, Zuoren, Zhang, Zhao, Aldaaysi, Kawthar, Vadlamudi, Ratna, Mann, Monica, and Skordalakes, Emmanuel

Published

2024

4. PED in 2024: improving the community deposition of structural ensembles for intrinsically disordered proteins.

Author

Ghafouri, Hamidreza, Lazar, Tamas, Del Conte, Alessio, Tenorio Ku, Luiggi G, Consortium, PED, Tompa, Peter, Tosatto, Silvio C E, and Monzon, Alexander Miguel

Published

2024

5. Biophysical characterization of the Plasmodium falciparum circumsporozoite protein's N‐terminal domain.

Author

Geens, Rob, Stanisich, Jessica, Beyens, Olivier, D'Hondt, Stijn, Thiberge, Jean‐Michel, Ryckebosch, Amber, De Groot, Anke, Magez, Stefan, Vertommen, Didier, Amino, Rogerio, De Winter, Hans, Volkov, Alexander N., Tompa, Peter, and Sterckx, Yann G.‐J.

Abstract

The circumsporozoite protein (CSP) is the main surface antigen of the Plasmodium sporozoite (SPZ) and forms the basis of the currently only licensed anti‐malarial vaccine (RTS,S/AS01). CSP uniformly coats the SPZ and plays a pivotal role in its immunobiology, in both the insect and the vertebrate hosts. Although CSP's N‐terminal domain (CSPN) has been reported to play an important role in multiple CSP functions, a thorough biophysical and structural characterization of CSPN is currently lacking. Here, we present an alternative method for the recombinant production and purification of CSPN from Plasmodium falciparum (PfCSPN), which provides pure, high‐quality protein preparations with high yields. Through an interdisciplinary approach combining in‐solution experimental methods and in silico analyses, we provide strong evidence that PfCSPN is an intrinsically disordered region displaying some degree of compaction. [ABSTRACT FROM AUTHOR]

Published

2024

6. Quantification of Surface Tension Effects and Nucleation‐and‐Growth Rates during Self‐Assembly of Biological Condensates.

Author

Sárkány, Zsuzsa, Rocha, Fernando, Bratek‐Skicki, Anna, Tompa, Peter, Macedo‐Ribeiro, Sandra, and Martins, Pedro M.

Subjects

SURFACE tension, PHASE equilibrium, GAS condensate reservoirs, RATE of nucleation, PHASE separation, MOLECULAR self-assembly, SOLUBILITY, ANALYTICAL solutions

Abstract

Liquid‐solid and liquid‐liquid phase separation (PS) drives the formation of functional and disease‐associated biological assemblies. Principles of phase equilibrium are here employed to derive a general kinetic solution that predicts the evolution of the mass and size of biological assemblies. Thermodynamically, protein PS is determined by two measurable concentration limits: the saturation concentration and the critical solubility. Due to surface tension effects, the critical solubility can be higher than the saturation concentration for small, curved nuclei. Kinetically, PS is characterized by the primary nucleation rate constant and a combined rate constant accounting for growth and secondary nucleation. It is demonstrated that the formation of a limited number of large condensates is possible without active mechanisms of size control and in the absence of coalescence phenomena. The exact analytical solution can be used to interrogate how the elementary steps of PS are affected by candidate drugs. [ABSTRACT FROM AUTHOR]

Published

2023

7. A fish herpesvirus highlights functional diversities among Zα domains related to phase separation induction and A-to-Z conversion.

Author

Diallo, Mamadou Amadou, Pirotte, Sébastien, Hu, Yunlong, Morvan, Léa, Rakus, Krzysztof, Suárez, Nicolás M, PoTsang, Lee, Saneyoshi, Hisao, Xu, Yan, Davison, Andrew J, Tompa, Peter, Sussman, Joel L, and Vanderplasschen, Alain

Published

2023

8. Intrinsic protein disorder uncouples affinity from binding specificity.

Author

Lazar, Tamas, Tantos, Agnes, Tompa, Peter, and Schad, Eva

Abstract

Intrinsically disordered proteins (IDPs) and intrinsically disordered regions (IDRs) of proteins often function by molecular recognition, in which they undergo induced folding. Based on prior generalizations, the idea prevails in the IDP field that due to the entropic penalty of induced folding, the major functional advantage associated with this binding mode is "uncoupling" specificity from binding strength. Nevertheless, both weaker binding and high specificity of IDPs/IDRs rest on limited experimental observations, making these assumptions more speculations than evidence‐supported facts. The issue is also complicated by the rather vague concept of specificity that lacks an exact measure, such as the Kd for binding strength. We addressed these issues by creating and analyzing a comprehensive dataset of well‐characterized ID/globular protein complexes, for which both the atomic structure of the complex and free energy (ΔG, Kd) of interaction is known. Through this analysis, we provide evidence that the affinity distributions of IDP/globular and globular/globular complexes show different trends, whereas specificity does not connote to weaker binding strength of IDPs/IDRs. Furthermore, protein disorder extends the spectrum in the direction of very weak interactions, which may have important regulatory consequences and suggest that, in a biological sense, strict correlation of specificity and binding strength are uncoupled by structural disorder. [ABSTRACT FROM AUTHOR]

Published

2022

9. A Novel Tandem-Tag Purification Strategy for Challenging Disordered Proteins.

Author

Mészáros, Attila, Muwonge, Kevin, Janvier, Steven, Ahmed, Junaid, and Tompa, Peter

Subjects

PROTEOLYSIS, PROTEINS, PLANT-fungus relationships, PHYTOPATHOGENIC fungi, PROTEIN fractionation

Abstract

Intrinsically disordered proteins (IDPs) lack well-defined 3D structures and can only be described as ensembles of different conformations. This high degree of flexibility allows them to interact promiscuously and makes them capable of fulfilling unique and versatile regulatory roles in cellular processes. These functional benefits make IDPs widespread in nature, existing in every living organism from bacteria and fungi to plants and animals. Due to their open and exposed structural state, IDPs are much more prone to proteolytic degradation than their globular counterparts. Therefore, the purification of recombinant IDPs requires extra care and caution, such as maintaining low temperature throughout the purification, the use of protease inhibitor cocktails and fast workflow. Even so, in the case of long IDP targets, the appearance of truncated by-products often seems unavoidable. The separation of these unwanted proteins can be very challenging due to their similarity to the parent target protein. Here, we describe a tandem-tag purification method that offers a remedy to this problem. It contains only common affinity-chromatography steps (HisTrap and Heparin) to ensure low cost, easy access and scaling-up for possible industrial use. The effectiveness of the method is demonstrated with four examples, Tau-441 and two of its fragments and the transactivation domain (AF1) of androgen receptor. [ABSTRACT FROM AUTHOR]

Published

2022

10. Degron masking outlines degronons, co-degrading functional modules in the proteome.

Author

Guharoy, Mainak, Lazar, Tamas, Macossay-Castillo, Mauricio, and Tompa, Peter

Subjects

PROTEOLYSIS, BINDING site assay, UBIQUITIN ligases, PROTEIN-protein interactions, UBIQUITINATION

Abstract

Effective organization of proteins into functional modules (networks, pathways) requires systems-level coordination between transcription, translation and degradation. Whereas the cooperation between transcription and translation was extensively studied, the cooperative degradation regulation of protein complexes and pathways has not been systematically assessed. Here we comprehensively analyzed degron masking, a major mechanism by which cellular systems coordinate degron recognition and protein degradation. For over 200 substrates with characterized degrons (E3 ligase targeting motifs, ubiquitination sites and disordered proteasomal entry sequences), we demonstrate that degrons extensively overlap with protein-protein interaction sites. Analysis of binding site information and protein abundance comparisons show that regulatory partners effectively outcompete E3 ligases, masking degrons from the ubiquitination machinery. Protein abundance variations between normal and cancer cells highlight the dynamics of degron masking components. Finally, integrative analysis of gene co-expression, half-life correlations and functional relationships between interacting proteins point towards higher-order, co-regulated degradation modules ('degronons') in the proteome. Systematic bioinformatics analysis of cooperative degradation of protein complexes indicates that degrons extensively overlap with protein-protein interaction sites, hiding degrons from ubiquitination machinery and suggesting the existence of co-degrading functional modules in the proteome. [ABSTRACT FROM AUTHOR]

Published

2022

11. F/YGG-motif is an intrinsically disordered nucleic-acid binding motif.

Author

Van Lindt, Joris, Lazar, Tamas, Pakravan, Donya, Demulder, Manon, Meszaros, Attila, Van Den Bosch, Ludo, Maes, Dominique, and Tompa, Peter

Subjects

TRANSFER RNA, DNA-binding proteins, NUCLEOPROTEINS, HYDROPHOBIC interactions, PHASE separation, ELECTROSTATIC interaction

Abstract

Heterogeneous nuclear ribonucleoproteins (hnRNP) function in RNA processing, have RNA-recognition motifs (RRMs) and intrinsically disordered, low-complexity domains (LCDs). While RRMs are drivers of RNA binding, there is only limited knowledge about the RNA interaction by the LCD of some hnRNPs. Here, we show that the LCD of hnRNPA2 interacts with RNA via an embedded Tyr/Gly-rich region which is a disordered RNA-binding motif. RNA binding is maintained upon mutating tyrosine residues to phenylalanines, but abrogated by mutating to alanines, thus we term the RNA-binding region 'F/YGG motif'. The F/YGG motif can bind a broad range of structured (e.g. tRNA) and disordered (e.g. polyA) RNAs, but not rRNA. As the F/YGG otif can also interact with DNA, we consider it a general nucleic acidbinding motif. hnRNPA2 LCD can form dense droplets, by liquid-liquid phase separation (LLPS). Their formation is inhibited by RNA binding, which is mitigated by salt and 1,6-hexanediol, suggesting that both electrostatic and hydrophobic interactions feature in the F/YGG motif. The D290V mutant also binds RNA, which interferes with both LLPS and aggregation thereof. We found homologous regions in a broad range of RNA- and DNA-binding proteins in the human proteome, suggesting that the F/YGG motif is a general nucleic acid-interaction motif. [ABSTRACT FROM AUTHOR]

Published

2022

12. DNA‐binding domain as the minimal region driving RNA‐dependent liquid–liquid phase separation of androgen receptor.

Author

Ahmed, Junaid, Meszaros, Attila, Lazar, Tamas, and Tompa, Peter

Abstract

Androgen receptor (AR) is a nuclear hormone receptor that regulates the transcription of genes involved in the development of testis, prostate and the nervous system. Misregulation of AR is a major driver of prostate cancer (PC). The primary agonist of full‐length AR is testosterone, whereas its splice variants, for example, AR‐v7 implicated in cancer may lack a ligand‐binding domain and are thus devoid of proper hormonal control. Recently, it was demonstrated that full‐length AR, but not AR‐v7, can undergo liquid–liquid phase separation (LLPS) in a cellular model of PC. In a detailed bioinformatics and deletion analysis, we have analyzed which AR region is responsible for LLPS. We found that its DNA‐binding domain (DBD) can bind RNA and can undergo RNA‐dependent LLPS. RNA regulates its LLPS in a reentrant manner, that is, it has an inhibitory effect at higher concentrations. As RNA binds DBD more weakly than DNA, while both RNA and DNA localizes into AR droplets, its LLPS depends on the relative concentration of the two nucleic acids. The region immediately preceding DBD has no effect on the LLPS propensity of AR, whereas the functional part of its long N‐terminal disordered transactivation domain termed activation function 1 (AF1) inhibits AR‐v7 phase separation. We suggest that the resulting diminished LLPS tendency of AR‐v7 may contribute to the misregulation of the transcription function of AR in prostate cancer. [ABSTRACT FROM AUTHOR]

Published

2021

13. Exploring Curated Conformational Ensembles of Intrinsically Disordered Proteins in the Protein Ensemble Database.

Author

Quaglia, Federica, Lazar, Tamas, Hatos, András, Tompa, Peter, Piovesan, Damiano, and Tosatto, Silvio C. E.

Published

2021

14. A generic approach to study the kinetics of liquid–liquid phase separation under near-native conditions.

Author

Van Lindt, Joris, Bratek-Skicki, Anna, Nguyen, Phuong N., Pakravan, Donya, Durán-Armenta, Luis F., Tantos, Agnes, Pancsa, Rita, Van Den Bosch, Ludo, Maes, Dominique, and Tompa, Peter

Subjects

LIQUID phase epitaxy, THERMODYNAMICS, CYTOLOGY, CELL membranes, TISSUE engineering

Abstract

Understanding the kinetics, thermodynamics, and molecular mechanisms of liquid–liquid phase separation (LLPS) is of paramount importance in cell biology, requiring reproducible methods for studying often severely aggregation-prone proteins. Frequently applied approaches for inducing LLPS, such as dilution of the protein from an urea-containing solution or cleavage of its fused solubility tag, often lead to very different kinetic behaviors. Here we demonstrate that at carefully selected pH values proteins such as the low-complexity domain of hnRNPA2, TDP-43, and NUP98, or the stress protein ERD14, can be kept in solution and their LLPS can then be induced by a jump to native pH. This approach represents a generic method for studying the full kinetic trajectory of LLPS under near native conditions that can be easily controlled, providing a platform for the characterization of physiologically relevant phase-separation behavior of diverse proteins. Van Lindt, Bratek-Skicki et al. show that at carefully selected pH values, proteins can be kept in solution and their LLPS can then be induced by a jump to native pH. This presents a generic method to study the full kinetic trajectory of LLPS under near native conditions that can be easily controlled, providing a platform for the characterization of physiologically relevant phase-separation behaviour of diverse proteins. [ABSTRACT FROM AUTHOR]

Published

2021

15. A guide to regulation of the formation of biomolecular condensates.

Author

Bratek‐Skicki, Anna, Pancsa, Rita, Meszaros, Balint, Van Lindt, Joris, and Tompa, Peter

Subjects

PHASE separation, NUCLEOLUS, ORGANELLES, CANNING & preserving

Abstract

Cellular organelles that lack a surrounding lipid bilayer, such as the nucleolus and stress granule, represent a newly recognized, general paradigm of cellular organization. The formation of such biomolecular condensates that include 'membraneless organelles' (MLOs) by liquid–liquid phase separation (LLPS) has been in the focus of a surge of recent studies. Through a combination of in vitro and in vivo approaches, thousands of potential phase‐separating proteins have been identified, and it was found that different cellular MLOs share many common components. These perplexing observations raise the question of how cells regulate the timing and specificity of LLPS, and ensure that different MLOs form and disperse at the right moment and cellular location and can preserve their identity and physical separation. This guide gives an overview of basic regulatory mechanisms, which manifest through the action of intrinsic regulatory elements, alternative splicing, post‐translational modifications, and a broad range of phase‐separating partners. We also elaborate on the cellular integration of these different mechanisms and highlight how complex regulation can orchestrate the parallel functioning of a dozen or so different MLOs in the cell. [ABSTRACT FROM AUTHOR]

Published

2020

16. Interaction between the scaffold proteins CBP by IQGAP1 provides an interface between gene expression and cytoskeletal activity.

Author

Kosol, Simone, Contreras-Martos, Sara, Piai, Alessandro, Varadi, Mihaly, Lazar, Tamas, Bekesi, Angela, Lebrun, Pierre, Felli, Isabella C., Pierattelli, Roberta, and Tompa, Peter

Subjects

SCAFFOLD proteins, GENE expression, BIOLOGICAL crosstalk, HISTONE acetyltransferase, CYTOSKELETON

Abstract

Crosstalk between cellular pathways is often mediated through scaffold proteins that function as platforms for the assembly of signaling complexes. Based on yeast two-hybrid analysis, we report here the interaction between two complex scaffold proteins, CREB-binding protein (CBP) and the Ras GTPase-activating-like protein 1 (IQGAP1). Dissection of the interaction between the two proteins reveals that the central, thus far uncharacterized, region of IQGAP1 interacts with the HAT domain and the C-terminal intrinsically disordered region of CBP (termed ID5). Structural analysis of ID5 by solution NMR spectroscopy and SAXS reveals the presence of two regions with pronounced helical propensity. The ID5 region(s) involved in the interaction of nanomolar affinity were delineated by solution NMR titrations and pull-down assays. Moreover, we found that IQGAP1 acts as an inhibitor of the histone acetyltransferase (HAT) activity of CBP. In in vitro assays, the CBP-binding region of IQGAP1 positively and negatively regulates the function of HAT proteins of different families including CBP, KAT5 and PCAF. As many signaling pathways converge on CBP and IQGAP1, their interaction provides an interface between transcription regulation and the coordination of cytoskeleton. Disruption or alteration of the interaction between these scaffold proteins may lead to cancer development or metastatic processes, highlighting the importance of this interaction. [ABSTRACT FROM AUTHOR]

Published

2020

17. Reply to "Intrinsic protein disorder uncouples affinity from binding specificity".

Author

Lázár, Tamás, Tantos, Agnes, Tompa, Peter, and Schad, Eva

Published

2023

18. Spontaneous driving forces give rise to protein-RNA condensates with coexisting phases and complex material properties.

Author

Boeynaems, Steven, Holehouse, Alex S., Weinhardt, Venera, Kovacs, Denes, Van Lindt, Joris, Larabell, Carolyn, Van Den Bosch, Ludo, Das, Rhiju, Tompa, Peter S., Pappu, Rohit V., and Gitler AEM-agitler@stanford.edu, Aaron D.

Subjects

RNA-protein interactions, ORGANELLE formation, COACERVATION, PHASE separation, COMPUTER simulation

Abstract

Phase separation of multivalent protein and RNA molecules underlies the biogenesis of biomolecular condensates such as membraneless organelles. In vivo, these condensates encompass hundreds of distinct types of molecules that typically organize into multilayered structures supporting the differential partitioning of molecules into distinct regions with distinct material properties. The interplay between driven (active) versus spontaneous (passive) processes that are required for enabling the formation of condensates with coexisting layers of distinct material properties remains unclear. Here, we deploy systematic experiments and simulations based on coarse-grained models to show that the collective interactions among the simplest, biologically relevant proteins and archetypal RNA molecules are sufficient for driving the spontaneous emergence of multilayered condensates with distinct material properties. These studies yield a set of rules regarding homotypic and heterotypic interactions that are likely to be relevant for understanding the interplay between active and passive processes that control the formation of functional biomolecular condensates. [ABSTRACT FROM AUTHOR]

Published

2019

19. Chemical shift assignments of the partially deuterated Fyn SH2-SH3 domain.

Author

Kieken, Fabien, Loth, Karine, van Nuland, Nico, Tompa, Peter, and Lenaerts, Tom

Abstract

Src Homology 2 and 3 (SH2 and SH3) are two key protein interaction modules involved in regulating the activity of many proteins such as tyrosine kinases and phosphatases by respective recognition of phosphotyrosine and proline-rich regions. In the Src family kinases, the inactive state of the protein is the direct result of the interaction of the SH2 and the SH3 domain with intra-molecular regions, leading to a closed structure incompetent with substrate modification. Here, we report the 1H, 15N and 13C backbone- and side-chain chemical shift assignments of the partially deuterated Fyn SH3-SH2 domain and structural differences between tandem and single domains. The BMRB accession number is 27165. [ABSTRACT FROM AUTHOR]

Published

2018

20. A comprehensive assessment of long intrinsic protein disorder from the DisProt database.

Author

Necci, Marco, Piovesan, Damiano, Dosztányi, Zsuzsanna, Tompa, Peter, and Tosatto, Silvio C E

Subjects

PROTEIN folding, PROTEIN structure, MOLECULAR conformation, GENETIC databases, X-rays

Abstract

Motivation: Intrinsic disorder (ID), i.e. the lack of a unique folded conformation at physiological conditions, is a common feature for many proteins, which requires specialized biochemical experiments that are not high-throughput. Missing X-ray residues from the PDB have been widely used as a proxy for ID when developing computational methods. This may lead to a systematic bias, where predictors deviate from biologically relevant ID. Large benchmarking sets on experimentally validated ID are scarce. Recently, the DisProt database has been renewed and expanded to include manually curated ID annotations for several hundred new proteins. This provides a large benchmark set which has not yet been used for training ID predictors. Results: Here, we describe the first systematic benchmarking of ID predictors on the new DisProt dataset. In contrast to previous assessments based onmissing X-ray data, this dataset contains mostly long ID regions and a significant amount of fully ID proteins. The benchmarking shows that ID predictors work quite well on the new dataset, especially for long ID segments. However, a large fraction of ID still goes virtually undetected and the ranking of methods is different than for PDB data. In particular, many predictors appear to confound ID and regions outside X-ray structures. This suggests that the ID prediction methods capture different flavors of disorder and can benefit from highly accurate curated examples. Availability and implementation: The raw data used for the evaluation are available from URL: http://www.disprot.org/assessment/. [ABSTRACT FROM AUTHOR]

Published

2018

21. Phasing in on the cell cycle.

Author

Boeynaems, Steven, Tompa, Peter, and Van Den Bosch, Ludo

Subjects

CELL cycle, ORIGIN of life, NEURODEGENERATION, BIOINFORMATICS, MASS spectrometry

Abstract

Just like all matter, proteins can also switch between gas, liquid and solid phases. Protein phase transition has claimed the spotlight in recent years as a novel way of how cells compartmentalize and regulate biochemical reactions. Moreover, this discovery has provided a new framework for the study of membrane-less organelle biogenesis and protein aggregation in neurodegenerative disorders. We now argue that this framework could be useful in the study of cell cycle regulation and cancer. Based on our work on phase transitions of arginine-rich proteins in neurodegeneration, via combining mass spectroscopy with bioinformatics analyses, we found that also numerous proteins involved in the regulation of the cell cycle can undergo protein phase separation. Indeed, several proteins whose function affects the cell cycle or are associated with cancer, have been recently found to phase separate from the test tube to cells. Investigating the role of this process for cell cycle proteins and understanding its molecular underpinnings will provide pivotal insights into the biology of cell cycle progression and cancer. [ABSTRACT FROM AUTHOR]

Published

2018

22. AmyPro: a database of proteins with validated amyloidogenic regions.

Author

Varadi, Mihaly, De Baets, Greet, Vranken, Wim F, Tompa, Peter, and Pancsa, Rita

Published

2018

23. Fructose-1,6-bisphosphate couples glycolytic flux to activation of Ras.

Author

Peeters, Ken, Van Leemputte, Frederik, Fischer, Baptiste, Bonini, Beatriz M., Quezada, Hector, Tsytlonok, Maksym, Haesen, Dorien, Vanthienen, Ward, Bernardes, Nuno, Bravo Gonzalez-Blas, Carmen, Janssens, Veerle, Tompa, Peter, Versées, Wim, and Thevelein, Johan M.

Abstract

Yeast and cancer cells share the unusual characteristic of favoring fermentation of sugar over respiration. We now reveal an evolutionary conserved mechanism linking fermentation to activation of Ras, a major regulator of cell proliferation in yeast and mammalian cells, and prime proto-oncogene product. A yeast mutant (tps1Δ) with overactive influx of glucose into glycolysis and hyperaccumulation of Fru1,6bisP, shows hyperactivation of Ras, which causes its glucose growth defect by triggering apoptosis. Fru1,6bisP is a potent activator of Ras in permeabilized yeast cells, likely acting through Cdc25. As in yeast, glucose triggers activation of Ras and its downstream targets MEK and ERK in mammalian cells. Biolayer interferometry measurements show that physiological concentrations of Fru1,6bisP stimulate dissociation of the pure Sos1/H-Ras complex. Thermal shift assay confirms direct binding to Sos1, the mammalian ortholog of Cdc25. Our results suggest that the Warburg effect creates a vicious cycle through Fru1,6bisP activation of Ras, by which enhanced fermentation stimulates oncogenic potency. [ABSTRACT FROM AUTHOR]

Published

2017

24. H, N, C resonance assignment of plant dehydrin early response to dehydration 10 (ERD10).

Author

Cedeño, Cesyen, Żerko, Szymon, Tompa, Peter, and Koźmiński, Wiktor

Abstract

Early response to dehydration 10 protein (ERD10) is an intrinsically disordered protein from Arabidopsis thaliana. The protein is upregulated during stress however its mechanism of action at atomic level is not well understood. In the present work multidimensional NMR methodologies are used in order to facilitate the process of chemical shift assignment. The information provided here supports further NMR spectroscopy experiments aimed at elucidation of ERD10 behaviour during molecular recognition events with other proteins. [ABSTRACT FROM AUTHOR]

Published

2017

25. To be disordered or not to be disordered: is that still a question for proteins in the cell?

Author

Pauwels, Kris, Lebrun, Pierre, and Tompa, Peter

Subjects

PROTEINS, PROTEOMICS, MOLECULAR biology, BIOSYNTHESIS, BIOMOLECULES

Abstract

There is ample evidence that many proteins or regions of proteins lack a well-defined folded structure under native-like conditions. These are called intrinsically disordered proteins (IDPs) or intrinsically disordered regions (IDRs). Whether this intrinsic disorder is also their main structural characteristic in living cells has been a matter of intense debate. The structural analysis of IDPs became an important challenge also because of their involvement in a plethora of human diseases, which made IDPs attractive targets for therapeutic development. Therefore, biophysical approaches are increasingly being employed to probe the structural and dynamical state of proteins, not only in isolation in a test tube, but also in a complex biological environment and even within intact cells. Here, we survey direct and indirect evidence that structural disorder is in fact the physiological state of many proteins in the proteome. The paradigmatic case of α-synuclein is used to illustrate the controversial nature of this topic. [ABSTRACT FROM AUTHOR]

Published

2017

26. Protein Delivery into Plant Cells: Toward In vivo Structural Biology.

Author

Cedeño, Cesyen, Pauwels, Kris, and Tompa, Peter

Subjects

PLANT cells & tissues, CYTOLOGY, NUCLEAR magnetic resonance

Abstract

Understanding the biologically relevant structural and functional behavior of proteins inside living plant cells is only possible through the combination of structural biology and cell biology. The state-of-the-art structural biology techniques are typically applied to molecules that are isolated from their native context. Although most experimental conditions can be easily controlled while dealing with an isolated, purified protein, a serious shortcoming of such in vitro work is that we cannot mimic the extremely complex intracellular environment in which the protein exists and functions. Therefore, it is highly desirable to investigate proteins in their natural habitat, i.e., within live cells. This is the major ambition of in-cell NMR, which aims to approach structure-function relationship under true in vivo conditions following delivery of labeled proteins into cells under physiological conditions. With a multidisciplinary approach that includes recombinant protein production, confocal fluorescence microscopy, nuclear magnetic resonance (NMR) spectroscopy and different intracellular protein delivery strategies, we explore the possibility to develop in-cell NMR studies in living plant cells. While we provide a comprehensive framework to set-up in-cell NMR, we identified the efficient intracellular introduction of isotope-labeled proteins as the major bottleneck. Based on experiments with the paradigmatic intrinsically disordered proteins (IDPs) Early Response to Dehydration protein 10 and 14, we also established the subcellular localization of ERD14 under abiotic stress. [ABSTRACT FROM AUTHOR]

Published

2017

27. Affinity purification of human m-calpain through an intrinsically disordered inhibitor, calpastatin.

Author

Nguyen, Hung Huy, Varadi, Mihaly, Tompa, Peter, and Pauwels, Kris

Subjects

CALPASTATIN, AFFINITY chromatography, CALPAIN, CHELATING agents, BIOPHYSICS

Abstract

Calpains are calcium-activated proteases that have biomedical and biotechnological potential. Their activity is tightly regulated by their endogenous inhibitor, calpastatin that binds to the enzyme only in the presence of calcium. Conventional approaches to purify calpain comprise multiple chromatographic steps, and are labor-intensive, leading to low yields. Here we report a new purification procedure for the human m-calpain based on its reversible calcium-mediated interaction with the intrinsically disordered calpastatin. We exploit the specific binding properties of human calpastatin domain 1 (hCSD1) to physically capture human m-calpain from a complex biological mixture. The dissociation of the complex is mediated by chelating calcium, upon which heterodimeric calpain elutes while hCSD1 remains immobilized onto the stationary phase. This novel affinity-based purification was compared to the conventional multistep purification strategy and we find that it is robust, it yields a homogeneous preparation, it can be scaled up easily and it rests on a non-disruptive step that maintains close to physiological conditions that allow further biophysical and functional studies. [ABSTRACT FROM AUTHOR]

Published

2017

28. Phosphorylation of MAP65-1 by Arabidopsis Aurora Kinases Is Required for Efficient Cell Cycle Progression.

Author

Boruc, Joanna, Weimer, Annika K., Stoppin-Mellet, Virginie, Mylle, Evelien, Kosetsu, Ken, Cedeño, Cesyen, Jaquinod, Michel, Njo, Maria, De Milde, Liesbeth, Tompa, Peter, Gonzalez, Nathalie, Inzé, Dirk, Beeckman, Tom, Vantard, Marylin, and Van Damme, Daniël

Published

2017

29. The Protein Ensemble Database.

Author

Varadi, Mihaly and Tompa, Peter

Published

2015

30. Towards Understanding Protein Disorder In-Cell.

Author

Cedeño, Cesyen, Raveh-Hamit, Hadas, Dinnyés, András, and Tompa, Peter

Published

2015

31. Bioinformatics Approaches for Predicting Disordered Protein Motifs.

Author

Bhowmick, Pallab, Guharoy, Mainak, and Tompa, Peter

Published

2015

32. Essential functions linked with structural disorder in organisms of minimal genome.

Author

Pancsa, Rita, Tompa, Peter, Gromiha, Michael, Gaspari, Zoltan, and Pongor, Sandor

Subjects

PATHOGENIC bacteria, BACTERIAL proteins, BACTERIAL genomes, ENDOSYMBIOSIS, DNA metabolism

Abstract

Intrinsically disordered regions (IDRs) of proteins fulfill important regulatory roles in most organisms. However, the proteins of certain endosymbiont and intracellular pathogenic bacteria with extremely reduced genomes contain disproportionately small amounts of IDRs, consisting almost entirely of folded domains. As their genomes co-evolving with their hosts have been reduced in unrelated lineages, the proteomes of these bacteria represent independently evolved minimal protein sets. We systematically analyzed structural disorder in a representative set of such minimal organisms to see which types of functionally relevant longer IDRs are invariably retained in them. We found that a few characteristic functions are consistently linked with conformational disorder: ribosomal proteins, key components of the protein production machinery, a central coordinator of DNA metabolism and certain housekeeping chaperones seem to strictly rely on structural disorder even in genome-reduced organisms. We propose that these functions correspond to the most essential and probably also the most ancient ones fulfilled by structural disorder in cellular organisms. [ABSTRACT FROM AUTHOR]

Published

2016

33. A Novel Method for Assessing the Chaperone Activity of Proteins.

Author

Hristozova, Nevena, Tompa, Peter, and Kovacs, Denes

Subjects

MOLECULAR chaperones, PROTEIN analysis, HOMEOSTASIS, ORGANISMS, PLETHORA (Pathology), CHAIN folding (Chemistry)

Abstract

Protein chaperones are molecular machines which function both during homeostasis and stress conditions in all living organisms. Depending on their specific function, molecular chaperones are involved in a plethora of cellular processes by playing key roles in nascent protein chain folding, transport and quality control. Among stress protein families–molecules expressed during adverse conditions, infection, and diseases–chaperones are highly abundant. Their molecular functions range from stabilizing stress-susceptible molecules and membranes to assisting the refolding of stress-damaged proteins, thereby acting as protective barriers against cellular damage. Here we propose a novel technique to test and measure the capability for protective activity of known and putative chaperones in a semi-high throughput manner on a plate reader. The current state of the art does not allow the in vitro measurements of chaperone activity in a highly parallel manner with high accuracy or high reproducibility, thus we believe that the method we report will be of significant benefit in this direction. The use of this method may lead to a considerable increase in the number of experimentally verified proteins with such functions, and may also allow the dissection of their molecular mechanism for a better understanding of their function. [ABSTRACT FROM AUTHOR]

Published

2016

34. The principle of conformational signaling.

Author

Tompa, Peter

Subjects

CELLULAR signal transduction, BIOENERGETICS, PHYSIOLOGICAL control systems, PROTEINS, BIOMOLECULES

Abstract

Signal transduction is the primary process by which cells respond to changes in their physical and chemical environments. Cellular response is initiated through a signaling protein (a receptor), which interacts with the “signal”, most often a novel molecule outside or inside the cell. The mechanism of activation of the receptor is a conformational change and/or covalent modification, which then sets in motion a signaling pathway, i.e. a cascade of modification and binding events that relay and amplify the message to eventually alter the state of the cell. In reflection of this general perception, concepts such as the “second messenger” and the “phosphorylation cascade” dominate our views of signal transduction. The idea I advocate here is that the non-covalent change in protein conformation itself might serve as the initial or intermittent “signal” in the cascade, and it is often the primary event being recognized and interpreted by downstream receptor(s). This signaling principle is intertwined with many other cellular regulatory concepts, such as (pathway) allostery, conformational spread, induced folding/unfolding, conformational memory, the hierarchical assembly of complexes, and the action of regulatory chaperones and prions. By elaborating on many examples and also recent advances in experimental methodology, I show that conformational signaling, although thus far underappreciated, is a general and robust signaling principle that most of the time operates in close interplay with covalent signals in the cell. [ABSTRACT FROM AUTHOR]

Published

2016

35. Numerous proteins with unique characteristics are degraded by the 26S proteasome following monoubiquitination.

Author

Braten, Ori, Livneh, Ido, Ziv, Tamar, Admon, Arie, Kehat, Izhak, Caspi, Lilac H., Gonen, Hedva, Bercovich, Beatrice, Godzik, Adam, Jahandideh, Samad, Jaroszewski, Lukasz, Sommer, Thomas, Kwon, Yong Tae, Guharoy, Mainak, Tompa, Peter, and Ciechanover, Aaron

Subjects

PROTEOLYSIS, PROTEASOMES, UBIQUITINATION, UBIQUITIN, PROTEOMICS

Abstract

The "canonical" proteasomal degradation signal is a substrateanchored polyubiquitin chain. However, a handful of proteins were shown to be targeted following monoubiquitination. In this study, we established-in both human and yeast cells-a systematic approach for the identification of monoubiquitination-dependent proteasomal substrates. The cellular wild-type polymerizable ubiquitin was replacedwith ubiquitin that cannot formchains. Using proteomic analysis, we screened for substrates that are nevertheless degraded under these conditions compared with those that are stabilized, and therefore require polyubiquitination for their degradation. For randomly sampled representative substrates, we confirmed that their cellular stability is in agreement with our screening prediction. Importantly, the two groups display unique features: monoubiquitinated substrates are smaller than the polyubiquitinated ones, are enriched in specific pathways, and, in humans, are structurally less disordered. We suggest that monoubiquitination-dependent degradation is more widespread than assumed previously, and plays key roles in various cellular processes. [ABSTRACT FROM AUTHOR]

Published

2016

36. Intrinsic protein disorder in histone lysine methylation.

Author

Lazar, Tamas, Schad, Eva, Szabo, Beata, Horvath, Tamas, Meszaros, Attila, Tompa, Peter, and Tantos, Agnes

Subjects

HISTONE methyltransferases, HISTONE methylation, PROTEIN binding, BINDING sites, LYSINE

Abstract

Histone lysine methyltransferases (HKMTs), catalyze mono-, di- and trimethylation of lysine residues, resulting in a regulatory pattern that controls gene expression. Their involvement in many different cellular processes and diseases makes HKMTs an intensively studied protein group, but scientific interest so far has been concentrated mostly on their catalytic domains. In this work we set out to analyze the structural heterogeneity of human HKMTs and found that many contain long intrinsically disordered regions (IDRs) that are conserved through vertebrate species. Our predictions show that these IDRs contain several linear motifs and conserved putative binding sites that harbor cancer-related SNPs. Although there are only limited data available in the literature, some of the predicted binding regions overlap with interacting segments identified experimentally. The importance of a disordered binding site is illustrated through the example of the ternary complex between MLL1, menin and LEDGF/p75. Our suggestion is that intrinsic protein disorder plays an as yet unrecognized role in epigenetic regulation, which needs to be further elucidated through structural and functional studies aimed specifically at the disordered regions of HKMTs. [ABSTRACT FROM AUTHOR]

Published

2016

37. Three reasons protein disorder analysis makes more sense in the light of collagen.

Author

Smithers, Ben, Oates, Matt E., Tompa, Peter, and Gough, Julian

Abstract

We have identified that the collagen helix has the potential to be disruptive to analyses of intrinsically disordered proteins. The collagen helix is an extended fibrous structure that is both promiscuous and repetitive. Whilst its sequence is predicted to be disordered, this type of protein structure is not typically considered as intrinsic disorder. Here, we show that collagen-encoding proteins skew the distribution of exon lengths in genes. We find that previous results, demonstrating that exons encoding disordered regions are more likely to be symmetric, are due to the abundance of the collagen helix. Other related results, showing increased levels of alternative splicing in disorder-encoding exons, still hold after considering collagen-containing proteins. Aside from analyses of exons, we find that the set of proteins that contain collagen significantly alters the amino acid composition of regions predicted as disordered. We conclude that research in this area should be conducted in the light of the collagen helix. [ABSTRACT FROM AUTHOR]

Published

2016

38. Start2Fold: a database of hydrogen/deuterium exchange data on protein folding and stability.

Author

Pancsa, Rita, Varadi, Mihaly, Tompa, Peter, and Vranken, Wim F.

Published

2016

39. Polymer physics of intracellular phase transitions.

Author

Brangwynne, Clifford P., Tompa, Peter, and Pappu, Rohit V.

Subjects

PHASE transitions, ORGANELLES, CELL membranes, PHASE separation, PROTEINS, LIQUID-liquid transformations, AMINO acid sequence

Abstract

Intracellular organelles are either membrane-bound vesicles or membrane-less compartments that are made up of proteins and RNA. These organelles play key biological roles, by compartmentalizing the cell to enable spatiotemporal control of biological reactions. Recent studies suggest that membrane-less intracellular compartments are multicomponent viscous liquid droplets that form via phase separation. Proteins that have an intrinsic tendency for being conformationally heterogeneous seem to be the main drivers of liquid-liquid phase separation in the cell. These findings highlight the relevance of classical concepts from the physics of polymeric phase transitions for understanding the assembly of intracellular membrane-less compartments. However, applying these concepts is challenging, given the heteropolymeric nature of protein sequences, the complex intracellular environment, and non-equilibrium features intrinsic to cells. This provides new opportunities for adapting established theories and for the emergence of new physics. [ABSTRACT FROM AUTHOR]

Published

2015

40. Functional Advantages of Conserved Intrinsic Disorder in RNA-Binding Proteins.

Author

Varadi, Mihaly, Zsolyomi, Fruzsina, Guharoy, Mainak, and Tompa, Peter

Subjects

RNA-protein interactions, MACROMOLECULES, CONFORMATIONAL analysis, EVOLUTIONARY theories, CHEMICAL stability

Abstract

Proteins form large macromolecular assemblies with RNA that govern essential molecular processes. RNA-binding proteins have often been associated with conformational flexibility, yet the extent and functional implications of their intrinsic disorder have never been fully assessed. Here, through large-scale analysis of comprehensive protein sequence and structure datasets we demonstrate the prevalence of intrinsic structural disorder in RNA-binding proteins and domains. We addressed their functionality through a quantitative description of the evolutionary conservation of disordered segments involved in binding, and investigated the structural implications of flexibility in terms of conformational stability and interface formation. We conclude that the functional role of intrinsically disordered protein segments in RNA-binding is two-fold: first, these regions establish extended, conserved electrostatic interfaces with RNAs via induced fit. Second, conformational flexibility enables them to target different RNA partners, providing multi-functionality, while also ensuring specificity. These findings emphasize the functional importance of intrinsically disordered regions in RNA-binding proteins. [ABSTRACT FROM AUTHOR]

Published

2015

41. The role of structural disorder in cell cycle regulation, related clinical proteomics, disease development and drug targeting.

Author

Tantos, Agnes, Kalmar, Lajos, and Tompa, Peter

Abstract

Understanding the molecular mechanisms of the regulation of cell cycle is a central issue in molecular cell biology, due to its fundamental role in the existence of cells. The regulatory circuits that make decisions on when a cell should divide are very complex and particularly subtly balanced in eukaryotes, in which the harmony of many different cells in an organism is essential for life. Several hundred proteins are involved in these processes, and a great deal of studies attests that most of them have functionally relevant intrinsic structural disorder. Structural disorder imparts many functional advantages on these proteins, and we discuss it in detail that it is involved in all key steps from signaling through the cell membrane to regulating transcription of proteins that execute timely responses to an ever-changing environment. [ABSTRACT FROM AUTHOR]

Published

2015

42. DisCons: a novel tool to quantify and classify evolutionary conservation of intrinsic protein disorder.

Author

Varadi, Mihaly, Guharoy, Mainak, Zsolyomi, Fruzsina, and Tompa, Peter

Subjects

BIOSYNTHESIS, PROTEIN-protein interactions, PROTEIN-ligand interactions, HOMOLOGY theory, PROTEIN binding

Abstract

Background: Analyzing the amino acid sequence of an intrinsically disordered protein (IDP) in an evolutionary context can yield novel insights on the functional role of disordered regions and sequence element(s). However, in the case of many IDPs, the lack of evolutionary conservation of the primary sequence can hamper the study of functionality, because the conservation of their disorder profile and ensuing function(s) may not appear in a traditional analysis of the evolutionary history of the protein. Results: Here we present DisCons (Disorder Conservation), a novel pipelined tool that combines the quantification of sequence- and disorder conservation to classify disordered residue positions. According to this scheme, the most interesting categories (for functional purposes) are constrained disordered residues and flexible disordered residues. The former residues show conservation of both the sequence and the property of disorder and are associated mainly with specific binding functionalities (e.g., short, linear motifs, SLiMs), whereas the latter class correspond to segments where disorder as a feature is important for function as opposed to the identity of the underlying sequence (e.g., entropic chains and linkers). DisCons therefore helps with elucidating the function(s) arising from the disordered state by analyzing individual proteins as well as large-scale proteomics datasets. Conclusions: DisCons is an openly accessible sequence analysis tool that identifies and highlights structurally disordered segments of proteins where the conformational flexibility is conserved across homologs, and therefore potentially functional. The tool is freely available both as a web application and as stand-alone source code hosted at http://pedb.vib.be/discons. [ABSTRACT FROM AUTHOR]

Published

2015

43. Fuzzy Complexes: A More Stochastic View of Protein Function.

Author

Fuxreiter, Monika and Tompa, Peter

Published

2012

44. Identification of Intrinsically Disordered Proteins by a Special 2D Electrophoresis.

Author

Tantos, Agnes and Tompa, Peter

Published

2012

45. Proteomic Methods for the Identification of Intrinsically Disordered Proteins.

Author

Tantos, Agnes and Tompa, Peter

Published

2012

46. Structural Disorder and Its Connection with Misfolding Diseases.

Author

Csizmók, Veronika and Tompa, Peter

Abstract

Intrinsically disordered proteins or regions of proteins lack a well-defined structure, yet they carry out important functions often associated with the regulation of cell cycle and transcription. Due to these central roles in key cellular processes, their mutations are frequently involved in neurodegenerative diseases. These diseases are usually caused by the structural transition of disordered proteins to insoluble, highly ordered deposits termed amyloids, such a fate has been described in the case of Aβ peptide and tau protein in Alzheimer΄s disease, α-synuclein in Parkinson΄s disease or the polyglutamin stretch of huntingtin in Huntington΄s disease and the prion protein in prion diseases. Due to the involvement of critical conformational change, these diseases are often denoted as ˵protein misfolding″ diseases. Here we provide a brief overview of the rapidly expanding field of protein disorder to provide a conceptual background for the discussion of the essence of molecular mechanisms of these diseases. We will provide a brief overview of the field in general, directing focus on the tendency of disordered proteins for aggregation in vitro and also in vivo. We will provide some details on neurodegenerative diseases and the proteins involved. It will be shown that the underlying phenomenon of ˵misfolding″ may also result in altering the normal function of proteins (physiological prions). We will wrap up the story by showing that the conformational transition occurs via partially ordered intermediates, which lead to a highly structured cross-β state in amyloids. [ABSTRACT FROM AUTHOR]

Published

2009

47. Bioinformatics Approaches to the Structure and Function of Intrinsically Disordered Proteins.

Author

Tompa, Peter

Abstract

Intrinsically disordered proteins (IDPs) exist and function without well defined structures, which demands the structure-function paradigm be reassessed. Evidence is mounting that they carry out important functions in signal transduction and regulation of transcription, primarily in eukaryotes. By a battery of biophysical techniques, the structural disorder of about 500 proteins has been demonstrated, and functional studies have provided the basis of classifying their functions into various schemes. Indirect evidence suggests that the occurrence of disorder is widespread, and several thousand proteins with significant disorder exist in the human proteome alone. To narrow the wide gap between known and anticipated IDPs, a range of bioinformatics algorithms have been developed, which can reliably predict the disordered state from amino acid sequence. Attempts have also been made to predict IDP functions, although with much less success. Due to their fast evolution, and reliance on short motifs for function, sequence clues for recognizing IDP functions are rather limited. In this chapter we give a brief survey of the IDP field, with particular focus on their functions and bioinformatics approaches developed for predicting their structure and function. Potential future directions of research are also suggested and discussed. [ABSTRACT FROM AUTHOR]

Published

2009

48. Prediction of Protein Disorder.

Author

Dosztányi, Zsuzsanna and Tompa, Peter

Published

2008

49. Synonymous Constraint Elements Show a Tendency to Encode Intrinsically Disordered Protein Segments.

Author

Macossay-Castillo, Mauricio, Kosol, Simone, Tompa, Peter, and Pancsa, Rita

Subjects

GENETIC code, GENETIC mutation, EXONS (Genetics), PROTEIN structure, COMPUTATIONAL biology

Abstract

Synonymous constraint elements (SCEs) are protein-coding genomic regions with very low synonymous mutation rates believed to carry additional, overlapping functions. Thousands of such potentially multi-functional elements were recently discovered by analyzing the levels and patterns of evolutionary conservation in human coding exons. These elements provide a good opportunity to improve our understanding of how the redundant nature of the genetic code is exploited in the cell. Our premise is that the protein segments encoded by such elements might better comply with the increased functional demands if they are structurally less constrained (i.e. intrinsically disordered). To test this idea, we investigated the protein segments encoded by SCEs with computational tools to describe the underlying structural properties. In addition to SCEs, we examined the level of disorder, secondary structure, and sequence complexity of protein regions overlapping with experimentally validated splice regulatory sites. We show that multi-functional gene regions translate into protein segments that are significantly enriched in structural disorder and compositional bias, while they are depleted in secondary structure and domain annotations compared to reference segments of similar lengths. This tendency suggests that relaxed protein structural constraints provide an advantage when accommodating multiple overlapping functions in coding regions. [ABSTRACT FROM AUTHOR]

Published

2014

50. Intrinsic Structural Disorder in Cytoskeletal Proteins.

Author

Guharoy, Mainak, Szabo, Beata, Martos, Sara Contreras, Kosol, Simone, and Tompa, Peter

Published

2013