Your search keyword '"low-complexity sequences"' showing total 5 results

1. Molecular Mechanisms Defining the Structural Basis for Self-Association of the FUS Low-Complexity Domain

Author

Kato, Masato and Kurokawa, Riki, editor

Published

2023

2. SWI/SNF senses carbon starvation with a pH-sensitive low-complexity sequence

Author

J Ignacio Gutierrez, Gregory P Brittingham, Yonca Karadeniz, Kathleen D Tran, Arnob Dutta, Alex S Holehouse, Craig L Peterson, and Liam J Holt

Subjects

transcription, chromatin, pH, low-complexity sequences, polyglutamine, Medicine, Science, Biology (General), QH301-705.5

Abstract

It is increasingly appreciated that intracellular pH changes are important biological signals. This motivates the elucidation of molecular mechanisms of pH sensing. We determined that a nucleocytoplasmic pH oscillation was required for the transcriptional response to carbon starvation in Saccharomyces cerevisiae. The SWI/SNF chromatin remodeling complex is a key mediator of this transcriptional response. A glutamine-rich low-complexity domain (QLC) in the SNF5 subunit of this complex, and histidines within this sequence, was required for efficient transcriptional reprogramming. Furthermore, the SNF5 QLC mediated pH-dependent recruitment of SWI/SNF to an acidic transcription factor in a reconstituted nucleosome remodeling assay. Simulations showed that protonation of histidines within the SNF5 QLC leads to conformational expansion, providing a potential biophysical mechanism for regulation of these interactions. Together, our results indicate that pH changes are a second messenger for transcriptional reprogramming during carbon starvation and that the SNF5 QLC acts as a pH sensor.

Published

2022

3. Protein domains of low sequence complexity-dark matter of the proteome.

Author

McKnight SL

Subjects

Protein Domains, Proteome chemistry, Proteome metabolism, Amino Acids metabolism

Abstract

This perspective begins with a speculative consideration of the properties of the earliest proteins to appear during evolution. What did these primitive proteins look like, and how were they of benefit to early forms of life? I proceed to hypothesize that primitive proteins have been preserved through evolution and now serve diverse functions important to the dynamics of cell morphology and biological regulation. The primitive nature of these modern proteins is easy to spot. They are composed of a limited subset of the 20 amino acids used by traditionally evolved proteins and thus are of low sequence complexity. This chemical simplicity limits protein domains of low sequence complexity to forming only a crude and labile type of protein structure currently hidden from the computational powers of machine learning. I conclude by hypothesizing that this structural weakness represents the underlying virtue of proteins that, at least for the moment, constitute the dark matter of the proteome., (© 2024 McKnight; Published by Cold Spring Harbor Laboratory Press.)

Published

2024

4. SWI/SNF senses carbon starvation with a pH-sensitive low-complexity sequence.

Author

Gutierrez JI, Brittingham GP, Karadeniz Y, Tran KD, Dutta A, Holehouse AS, Peterson CL, and Holt LJ

Subjects

Carbon, Chromatin Assembly and Disassembly, Hydrogen-Ion Concentration, Saccharomyces cerevisiae genetics, Saccharomyces cerevisiae metabolism, Transcription Factors metabolism, Chromosomal Proteins, Non-Histone metabolism, Saccharomyces cerevisiae Proteins metabolism

Abstract

It is increasingly appreciated that intracellular pH changes are important biological signals. This motivates the elucidation of molecular mechanisms of pH sensing. We determined that a nucleocytoplasmic pH oscillation was required for the transcriptional response to carbon starvation in Saccharomyces cerevisiae . The SWI/SNF chromatin remodeling complex is a key mediator of this transcriptional response. A glutamine-rich low-complexity domain (QLC) in the SNF5 subunit of this complex, and histidines within this sequence, was required for efficient transcriptional reprogramming. Furthermore, the SNF5 QLC mediated pH-dependent recruitment of SWI/SNF to an acidic transcription factor in a reconstituted nucleosome remodeling assay. Simulations showed that protonation of histidines within the SNF5 QLC leads to conformational expansion, providing a potential biophysical mechanism for regulation of these interactions. Together, our results indicate that pH changes are a second messenger for transcriptional reprogramming during carbon starvation and that the SNF5 QLC acts as a pH sensor., Competing Interests: JG, GB, YK, KT, AD, AH, CP, LH No competing interests declared, (© 2022, Gutierrez et al.)

Published

2022

5. How do protein domains of low sequence complexity work?

Author

Kato M, Zhou X, and McKnight SL

Subjects

Biomolecular Condensates metabolism, Eukaryota, Eukaryotic Cells metabolism, Hydrogels chemistry, Hydrogels metabolism, Hydrogen Bonding, Methionine chemistry, Methionine metabolism, Origin of Life, Protein Conformation, beta-Strand, Protein Domains, Proteins metabolism, RNA metabolism, Solutions, Water chemistry, Water metabolism, Biomolecular Condensates chemistry, Eukaryotic Cells chemistry, Glycols chemistry, Isoxazoles chemistry, Proteins chemistry, RNA chemistry

Abstract

This review covers research findings reported over the past decade concerning the ability of low complexity (LC) domains to self-associate in a manner leading to their phase separation from aqueous solution. We focus our message upon the reductionist use of two forms of phase separation as biochemical assays to study how LC domains might function in living cells. Cells and their varied compartments represent extreme examples of material condensates. Over the past half century, biochemists, structural biologists, and molecular biologists have resolved the mechanisms driving innumerable forms of macromolecular condensation. In contrast, we remain largely ignorant as to how 10%-20% of our proteins actually work to assist in cell organization. This enigmatic 10%-20% of the proteome corresponds to gibberish-like LC sequences. We contend that many of these LC sequences move in and out of a structurally ordered, self-associated state as a means of offering a combination of organizational specificity and dynamic pliability to living cells. Finally, we speculate that ancient proteins may have behaved similarly, helping to condense, organize, and protect RNA early during evolution., (© 2022 Kato et al.; Published by Cold Spring Harbor Laboratory Press for the RNA Society.)

Published

2022