Your search keyword '"Tompa, Peter"' showing total 12 results

1. Condensation of the N-terminal domain of human topoisomerase 1 is driven by electrostatic interactions and tuned by its charge distribution.

Author

Bianchi G, Mangiagalli M, Ami D, Ahmed J, Lombardi S, Longhi S, Natalello A, Tompa P, and Brocca S

Subjects

Humans, Static Electricity, DNA Topoisomerases, Type I genetics, RNA

Abstract

Liquid-liquid phase separation (LLPS) is pivotal in forming biomolecular condensates, which are crucial in several biological processes. Intrinsically disordered regions (IDRs) are typically responsible for driving LLPS due to their multivalency and high content of charged residues that enable the establishment of electrostatic interactions. In our study, we examined the role of charge distribution in the condensation of the disordered N-terminal domain of human topoisomerase I (hNTD). hNTD is densely charged with oppositely charged residues evenly distributed along the sequence. Its LLPS behavior was compared with that of charge permutants exhibiting varying degrees of charge segregation. At low salt concentrations, hNTD undergoes LLPS. However, LLPS is inhibited by high concentrations of salt and RNA, disrupting electrostatic interactions. Our findings show that, in hNTD, moderate charge segregation promotes the formation of liquid condensates that are sensitive to salt and RNA, whereas marked charge segregation results in the formation of aberrant condensates. Although our study is based on a limited set of protein variants, it supports the applicability of the "stickers-and-spacers" model to biomolecular condensates involving highly charged IDRs. These results may help generate reliable models of the overall LLPS behavior of supercharged polypeptides., Competing Interests: Declaration of competing interest The authors declare the following financial interests/personal relationships which may be considered as potential competing interests: Junaid Ahmed reports financial support was provided by Research Foundation Flanders., (Copyright © 2023. Published by Elsevier B.V.)

Published

2024

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

Author

Van Lindt J, Lazar T, Pakravan D, Demulder M, Meszaros A, Van Den Bosch L, Maes D, and Tompa P

Subjects

DNA, DNA-Binding Proteins metabolism, Humans, Heterogeneous-Nuclear Ribonucleoproteins, RNA genetics, RNA metabolism

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 acid-binding 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.

Published

2022

3. DNA-binding domain as the minimal region driving RNA-dependent liquid-liquid phase separation of androgen receptor.

Author

Ahmed J, Meszaros A, Lazar T, and Tompa P

Subjects

Humans, Protein Domains, DNA chemistry, RNA chemistry, Receptors, Androgen chemistry

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., (© 2021 The Protein Society.)

Published

2021

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

Author

Boeynaems S, Holehouse AS, Weinhardt V, Kovacs D, Van Lindt J, Larabell C, Van Den Bosch L, Das R, Tompa PS, Pappu RV, and Gitler AD

Subjects

Computational Biology, Molecular Dynamics Simulation, Organelles chemistry, Organelles metabolism, Intrinsically Disordered Proteins chemistry, Intrinsically Disordered Proteins metabolism, Intrinsically Disordered Proteins physiology, Phase Transition, RNA chemistry, RNA metabolism, RNA physiology

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., Competing Interests: Conflict of interest statement: R.V.P. is a member of the scientific advisory board of Dewpoint Therapeutics., (Copyright © 2019 the Author(s). Published by PNAS.)

Published

2019

5. Janus chaperones: assistance of both RNA- and protein-folding by ribosomal proteins.

Author

Kovacs D, Rakacs M, Agoston B, Lenkey K, Semrad K, Schroeder R, and Tompa P

Subjects

Escherichia coli Proteins chemistry, Hot Temperature, Molecular Chaperones chemistry, RNA chemistry, Ribosomal Proteins chemistry, Escherichia coli Proteins metabolism, Molecular Chaperones metabolism, Nucleic Acid Conformation, Protein Folding, RNA metabolism, Ribosomal Proteins metabolism

Abstract

Ribosomal proteins assist the assembly and increase the stability of ribosomal RNA, without requiring ATP for their action. Some ribosomal proteins are also known to have essential functions outside the ribosome, i.e. promiscuity of functions that appears to correlate with their structural disorder. Here we addressed if certain ribosomal proteins with RNA chaperone activity and with a significant level of disorder also have protein-chaperone activity in vitro. Four proteins of the large subunit of Escherichia coli ribosome, L15, L16, L18 and L19 have been tested in three chaperone assays, in which all of them exhibited potent chaperone activity, commensurable with that of heat shock protein 90 kDa. These observations highlight possible novel aspects of the promiscuous functions of ribosomal proteins outside of the ribosome.

Published

2009

6. Molecular cloning and RNA expression of a novel Drosophila calpain, Calpain C.

Author

Spadoni C, Farkas A, Sinka R, Tompa P, and Friedrich P

Subjects

Amino Acid Sequence, Animals, Calcium metabolism, Calpain metabolism, Cloning, Molecular, DNA metabolism, DNA, Complementary metabolism, HeLa Cells, Humans, In Situ Hybridization, Models, Genetic, Molecular Sequence Data, Oligonucleotides chemistry, RNA, Messenger metabolism, Reverse Transcriptase Polymerase Chain Reaction, Sequence Homology, Amino Acid, Time Factors, Calpain biosynthesis, Calpain genetics, Drosophila Proteins biosynthesis, Drosophila Proteins genetics, Drosophila melanogaster metabolism, RNA metabolism

Abstract

The calpains are Ca(2+)-activated cysteine proteases whose biochemical properties have been extensively characterized in vitro. Less is known, however, about the physiological role of calpains. In this respect, Drosophila melanogaster is a useful experimental organism to study calpain activity and regulation in vivo. The sequencing of the fly genome has been recently completed and a novel calpain homologue has been identified in the CG3692 gene product. We embarked on the cloning and characterization of this putative novel calpain. We demonstrate that the actual calpain is different from the predicted protein and we provide experimental evidence for the correction of the genomic annotation. This novel protein, Calpain C, must be catalytically inactive, having mutated active site residues but is otherwise structurally similar to the other known fly calpains. Moreover, we analysed Calpain C RNA expression during Drosophila development by RT-PCR and RNA in situ hybridization, which revealed strong expression in the salivary glands.

Published

2003

7. 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, Aaron D

Subjects

Biochemistry and Cell Biology, Chemical Sciences, Biological Sciences, Computational Biology, Intrinsically Disordered Proteins, Molecular Dynamics Simulation, Organelles, Phase Transition, RNA, phase transitions, biomolecular condensates, complex coacervation, intrinsically disordered proteins

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.

Published

2019

8. Coding Regions of Intrinsic Disorder Accommodate Parallel Functions.

Author

Pancsa, Rita and Tompa, Peter

Subjects

*PROTEINS, *EUKARYOTES, *GENETIC mutation, *RNA, *DNA

Abstract

Numerous DNA- and RNA-level functions are embedded in protein-coding regions, which constrains their structure, function, and evolution. Accumulating evidence suggests that such additional, overlapping functions occur preferentially in the coding sequences of intrinsically disordered proteins/regions (IDPs/IDRs), especially in those that are newly incorporated and thus have reduced selective pressure. It is the lack of strict structural constraints that makes disordered proteins more tolerant to mutations and thus more permissive to the appearance of overlapping functions within their coding sequences than structured domains. Therefore, IDPs/IDRs are often mosaics of segments fulfilling protein functionalities and intervening regions primarily carrying nucleotide-level functions. The ensuing complexification of gene-regulatory circuits may have contributed to the evolutionary spread of structural disorder in complex eukaryotic organisms. [ABSTRACT FROM AUTHOR]

Published

2016

9. Diverse functional manifestations of intrinsic structural disorder in molecular chaperones.

Author

Kovacs, Denes and Tompa, Peter

Subjects

*MOLECULAR chaperones, *DISEASES, *PROTEIN research, *RNA, *BIOMOLECULES

Abstract

IDPs (intrinsically disordered proteins) represent a unique class of proteins which show diverse molecular mechanisms in key biological functions. The aim of the present mini-review is to summarize IDP chaperones that have increasingly been studied in the last few years, by focusing on the role of intrinsic disorder in their molecular mechanism. Disordered regions in both globular and disordered chaperones are often involved directly in chaperone action, either by modulating activity or through direct involvement in substrate identification and binding. They might also be responsible for the subcellular localization of the protein. In outlining the state of the art, we survey known IDP chaperones discussing the following points: (i) globular chaperones that have an experimentally proven functional disordered region(s), (ii) chaperones that are completely disordered along their entire length, and (iii) the possible mechanisms of action of disordered chaperones. Through all of these details, we chart out how far the field has progressed, only to emphasize the long road ahead before the chaperone function can be firmly established as part of the physiological mechanistic arsenal of the emerging group of IDPs. [ABSTRACT FROM AUTHOR]

Published

2012

10. The role of structural disorder in the function of RNA and protein chaperones.

Author

Tompa, Peter and Csermely, Peter

Subjects

*RNA, *MOLECULAR chaperones, *PROTEINS, *MOLECULES, *RIBOSE

Abstract

Chaperones are highly sophisticated protein machines that assist the folding of RNA molecules or other proteins. Their function is generally thought to require a fine-tuned and highly conserved structure: despite the recent recognition of the widespread occurrence of structural disorder in the proteome, this structural trait has never been generally considered in molecular chaperones. In this review we give evidence for the prevalence of functional regions without a well-defined 3-D structure in RNA and protein chaperones. By considering a variety of individual examples, we suggest that the structurally disordered chaperone regions either function as molecular recognition elements that act as solubilizers or locally loosen the structure of the kinetically trapped folding intermediate via transient binding to facilitate its conformational search. The importance of structural disorder is underlined by a predictor of natural disordered regions, which shows an extremely high proportion of such regions, unparalleled in any other protein class, within RNA chaperones: 54.2% of their residues fall into disordered regions and 40% fall within disordered regions longer than 30 consecutive residues. Structural disorder also prevails in protein chaperones, for which frequency values are 36.7% and 15%, respectively. In keeping with these and other details, a novel "entropy transfer" model is presented to account for the mechanistic role of structural disorder in chaperone function. [ABSTRACT FROM AUTHOR]

Published

2004

11. Protein Phase Separation: A New Phase in Cell Biology.

Author

Boeynaems, Steven, Alberti, Simon, Fawzi, Nicolas L., Mittag, Tanja, Polymenidou, Magdalini, Rousseau, Frederic, Schymkowitz, Joost, Shorter, James, Wolozin, Benjamin, Van Den Bosch, Ludo, Tompa, Peter, and Fuxreiter, Monika

Subjects

*PROTEINS, *PHASE separation, *CYTOLOGY, *ORGANELLES, *RNA

Abstract

Cellular compartments and organelles organize biological matter. Most well-known organelles are separated by a membrane boundary from their surrounding milieu. There are also many so-called membraneless organelles and recent studies suggest that these organelles, which are supramolecular assemblies of proteins and RNA molecules, form via protein phase separation. Recent discoveries have shed light on the molecular properties, formation, regulation, and function of membraneless organelles. A combination of techniques from cell biology, biophysics, physical chemistry, structural biology, and bioinformatics are starting to help establish the molecular principles of an emerging field, thus paving the way for exciting discoveries, including novel therapeutic approaches for the treatment of age-related disorders. [ABSTRACT FROM AUTHOR]

Published

2018

12. Structural Flexibility Allows the Functional Diversity of Potyvirus Genome-Linked Protein VPg.

Author

Rantalainen, Kimmo I., Eskelin, Katri, Tompa, Peter, and Mäkinen, Kristiina

Subjects

*POTYVIRUSES, *PLANT viruses, *RNA, *AMINO acids, *HYDROPHOBIC surfaces, *GENOMES

Abstract

Several viral genome-linked proteins (VPgs) of plant viruses are intrinsically disordered and undergo folding transitions in the presence of partners. This property has been postulated to be one of the factors that enable the functional diversity of the protein. We created a homology model of Potato virus A VPg and positioned the known functions and structural properties of potyviral VPgs on the novel structural model. The model suggests an elongated structure with a hydrophobic core composed of antiparallel β-sheets surrounded by helices and a positively charged contact surface where most of the known activities are localized. The model most probably represents the fold induced immediately after binding of VPg to a negatively charged lipid surface or to SDS. When the charge of the positive surface was lowered by lysine mutations, the efficiencies of in vitro NTP binding, uridylylation reaction, and unspecific RNA binding were reduced and in vivo the infectivity was debilitated. The most likely uridylylation site, Tyr63, locates to the positively charged surface. Surprisingly, a Tyr63Ala mutation did not prevent replication completely but blocked spreading of the virus. Based on the localization of Tyr119 in the model, it was hypothesized to serve as an alternative uridylylation site. Evidence to support the role of Tyr119 in replication was obtained which gives a positive example of the prediction power of the model. Taken together, our experimental data support the features presented in the model and the idea that the functional diversity is attributable to structural flexibility. [ABSTRACT FROM AUTHOR]

Published

2011