Identifying Evolutionarily Conserved Protein Complexes

Condensins are evolutionarily conserved protein complexes that are required for chromosome segregation during cell division and genome organization during interphase. In Caenorhabditis elegans, a specialized condensin, which forms the core of the dosage compensation complex (DCC), binds to and represses X chromosome transcription. Here, we analyzed DCC localization and the effect of DCC depletion on histone modifications, transcription factor binding, and gene expression using chromatin immunoprecipitation sequencing and mRNA sequencing. Across the X, the DCC accumulates at accessible gene regulatory sites in active chromatin and not heterochromatin. The DCC is required for reducing the levels of activating histone modifications, including H3K4me3 and H3K27ac, but not repressive modification H3K9me3. In X-to-autosome fusion chromosomes, DCC spreading into the autosomal sequences locally reduces gene expression, thus establishing a direct link between DCC binding and repression. Together, our results indicate that DCC-mediated transcription repression is associated with a reduction in the activity of X chromosomal gene regulatory elements.

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DrosophilaTorsin Protein Regulates Motor Control and Stress Sensitivity and Forms a Complex with Fragile-X Mental Retardation Protein

Neural Plasticity ◽

10.1155/2016/6762086 ◽

2016 ◽

Vol 2016 ◽

pp. 1-14 ◽

Cited By ~ 2

Author(s):

Phuong Nguyen ◽

Jong Bok Seo ◽

Hyo-Min Ahn ◽

Young Ho Koh

Keyword(s):

Mental Retardation ◽

Protein Complexes ◽

Fragile X ◽

Stress Sensitivity ◽

Altered Expression ◽

Fragile X Mental Retardation ◽

Evolutionarily Conserved ◽

Mental Retardation Protein ◽

Synaptic Boutons

We investigated unknownin vivofunctions of Torsin by usingDrosophilaas a model. Downregulation ofDrosophilaTorsin (DTor) by DTor-specific inhibitory double-stranded RNA (RNAi) induced abnormal locomotor behavior and increased susceptibility to H2O2. In addition, altered expression of DTor significantly increased the numbers of synaptic boutons. One important biochemical consequence of DTor-RNAi expression in fly brains was upregulation of alcohol dehydrogenase (ADH). Altered expression of ADH has also been reported inDrosophilaFragile-X mental retardation protein (DFMRP) mutant flies. Interestingly, expression of DFMRP was altered in DTor mutant flies, and DTor and DFMRP were present in the same protein complexes. In addition, DTor and DFMRP immunoreactivities were partially colocalized in several cellular organelles in larval muscles. Furthermore, there were no significant differences between synaptic morphologies ofdfmrpnull mutants anddfmrpmutants expressing DTor-RNAi. Taken together, our evidences suggested that DTor and DFMRP might be present in the same signaling pathway regulating synaptic plasticity. In addition, we also found that human Torsin1A and human FMRP were present in the same protein complexes, suggesting that this phenomenon is evolutionarily conserved.

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Allosteric deactivation of PIFs and EIN3 by microproteins in light control of plant development

Proceedings of the National Academy of Sciences ◽

10.1073/pnas.2002313117 ◽

2020 ◽

Vol 117 (31) ◽

pp. 18858-18868 ◽

Cited By ~ 1

Author(s):

Qingqing Wu ◽

Kunyan Kuang ◽

Mohan Lyu ◽

Yan Zhao ◽

Yue Li ◽

...

Keyword(s):

Transcription Factors ◽

Transcriptional Activity ◽

Environmental Changes ◽

Protein Complexes ◽

Binding Capacity ◽

Negative Control ◽

Light Responses ◽

Developmental Transitions ◽

Evolutionarily Conserved ◽

Target Molecules

Buried seedlings undergo dramatic developmental transitions when they emerge from soil into sunlight. As central transcription factors suppressing light responses, PHYTOCHROME-INTERACTING FACTORs (PIFs) and ETHYLENE-INSENSITIVE 3 (EIN3) actively function in darkness and must be promptly repressed upon light to initiate deetiolation. Microproteins are evolutionarily conserved small single-domain proteins that act as posttranslational regulators in eukaryotes. Although hundreds to thousands of microproteins are predicted to exist in plants, their target molecules, biological roles, and mechanisms of action remain largely unknown. Here, we show that two microproteins, miP1a and miP1b (miP1a/b), are robustly stimulated in the dark-to-light transition.miP1a/bare primarily expressed in cotyledons and hypocotyl, exhibiting tissue-specific patterns similar to those ofPIFs andEIN3. We demonstrate that PIFs and EIN3 assemble functional oligomers by self-interaction, while miP1a/b directly interact with and disrupt the oligomerization of PIFs and EIN3 by forming nonfunctional protein complexes. As a result, the DNA binding capacity and transcriptional activity of PIFs and EIN3 are predominantly suppressed. These biochemical findings are further supported by genetic evidence. miP1a/b positively regulate photomorphogenic development, and constitutively expressingmiP1a/brescues the delayed apical hook unfolding and cotyledon development of plants overexpressingPIFs andEIN3. Our study reveals that microproteins provide a temporal and negative control of the master transcription factors' oligomerization to achieve timely developmental transitions upon environmental changes.

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Formation of a Bazooka–Stardust complex is essential for plasma membrane polarity in epithelia

The Journal of Cell Biology ◽

10.1083/jcb.201006029 ◽

2010 ◽

Vol 190 (5) ◽

pp. 751-760 ◽

Cited By ~ 65

Author(s):

Michael P. Krahn ◽

Johanna Bückers ◽

Lars Kastrup ◽

Andreas Wodarz

Keyword(s):

Plasma Membrane ◽

Protein Complexes ◽

Pdz Domain ◽

Phosphorylation Site ◽

Direct Interaction ◽

Epithelial Polarity ◽

Kinase C ◽

Discs Large ◽

Evolutionarily Conserved ◽

Functional Hierarchy

Apical–basal polarity in Drosophila melanogaster epithelia depends on several evolutionarily conserved proteins that have been assigned to two distinct protein complexes: the Bazooka (Baz)–PAR-6 (partitioning defective 6)–atypical protein kinase C (aPKC) complex and the Crumbs (Crb)–Stardust (Sdt) complex. These proteins operate in a functional hierarchy, in which Baz is required for the proper subcellular localization of all other proteins. We investigated how these proteins interact and how this interaction is regulated. We show that Baz recruits Sdt to the plasma membrane by direct interaction between the Postsynaptic density 95/Discs large/Zonula occludens 1 (PDZ) domain of Sdt and a region of Baz that contains a phosphorylation site for aPKC. Phosphorylation of Baz causes the dissociation of the Baz–Sdt complex. Overexpression of a nonphosphorylatable version of Baz blocks the dissociation of Sdt from Baz, causing phenotypes very similar to those of crb and sdt mutations. Our findings provide a molecular mechanism for the phosphorylation-dependent interaction between the Baz–PAR-3 and Crb complexes during the establishment of epithelial polarity.

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SMC proteins and chromosome mechanics: from bacteria to humans

Philosophical Transactions of the Royal Society B Biological Sciences ◽

10.1098/rstb.2004.1606 ◽

2005 ◽

Vol 360 (1455) ◽

pp. 507-514 ◽

Cited By ~ 92

Author(s):

Tatsuya Hirano

Keyword(s):

Protein Interactions ◽

Protein Complexes ◽

Related Protein ◽

Protein Protein Interactions ◽

The Core ◽

Archaeal Species ◽

Evolutionarily Conserved ◽

Structural Maintenance Of Chromosomes ◽

Mitosis And Meiosis ◽

Smc Proteins

Chromosome cohesion and condensation are essential prerequisites of proper segregation of genomes during mitosis and meiosis, and are supported by two structurally related protein complexes, cohesin and condensin, respectively. At the core of the two complexes lie members of the structural maintenance of chromosomes (SMC) family of ATPases. SMC proteins are also found in most bacterial and archaeal species, implicating the existence of an evolutionarily conserved theme of higher-order chromosome organization and dynamics. SMC dimers adopt a two-armed structure with an ATP-binding cassette (ABC)-like domain at the distal end of each arm. This article reviews recent work on the bacterial and eukaryotic SMC protein complexes, and discusses current understanding of how these uniquely designed protein machines may work at a mechanistic level. It seems most likely that the action of SMC proteins is highly dynamic and plastic, possibly involving a diverse array of intramolecular and intermolecular protein–protein interactions.

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Distinct RNA-unwinding mechanisms of DEAD-box and DEAH-box RNA helicase proteins in remodeling structured RNAs and RNPs

Biochemical Society Transactions ◽

10.1042/bst20170095 ◽

2017 ◽

Vol 45 (6) ◽

pp. 1313-1321 ◽

Cited By ~ 27

Author(s):

Benjamin Gilman ◽

Pilar Tijerina ◽

Rick Russell

Keyword(s):

Conformational Changes ◽

Protein Complexes ◽

Rna Helicase ◽

Conformational Transitions ◽

Messenger Rnas ◽

Base Pairs ◽

Dead Box ◽

Evolutionarily Conserved ◽

Partially Unfolded ◽

Rna Protein Complexes

Structured RNAs and RNA–protein complexes (RNPs) fold through complex pathways that are replete with misfolded traps, and many RNAs and RNPs undergo extensive conformational changes during their functional cycles. These folding steps and conformational transitions are frequently promoted by RNA chaperone proteins, notably by superfamily 2 (SF2) RNA helicase proteins. The two largest families of SF2 helicases, DEAD-box and DEAH-box proteins, share evolutionarily conserved helicase cores, but unwind RNA helices through distinct mechanisms. Recent studies have advanced our understanding of how their distinct mechanisms enable DEAD-box proteins to disrupt RNA base pairs on the surfaces of structured RNAs and RNPs, while some DEAH-box proteins are adept at disrupting base pairs in the interior of RNPs. Proteins from these families use these mechanisms to chaperone folding and promote rearrangements of structured RNAs and RNPs, including the spliceosome, and may use related mechanisms to maintain cellular messenger RNAs in unfolded or partially unfolded conformations.

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NuA4 and SWR1-C: two chromatin-modifying complexes with overlapping functions and componentsThis paper is one of a selection of papers published in this Special Issue, entitled 30th Annual International Asilomar Chromatin and Chromosomes Conference, and has undergone the Journal's usual peer review process.

Biochemistry and Cell Biology ◽

10.1139/o09-062 ◽

2009 ◽

Vol 87 (5) ◽

pp. 799-815 ◽

Cited By ~ 60

Author(s):

Phoebe Y.T. Lu ◽

Nancy Lévesque ◽

Michael S. Kobor

Keyword(s):

Chromatin Structure ◽

Protein Complexes ◽

Peer Review Process ◽

Histone Variant ◽

Chromatin Remodelling ◽

Cellular Processes ◽

Evolutionarily Conserved ◽

And Function ◽

Histone Deposition ◽

Chemical Groups

Chromatin structure is important for the compaction of eukaryotic genomes, thus chromatin modifications play a fundamental role in regulating many cellular processes. The coordinated activities of various chromatin-remodelling and -modifying complexes are crucial in maintaining distinct chromatin neighbourhoods, which in turn ensure appropriate gene expression, as well as DNA replication, repair, and recombination. SWR1-C is an ATP-dependent histone deposition complex for the histone variant H2A.Z, whereas NuA4 is a histone acetyltransferase for histones H4, H2A, and H2A.Z. Together the NuA4 and SWR1-C chromatin-modifying complexes alter the chromatin structure through 3 distinct modifications in yeast: post-translational addition of chemical groups, ATP-dependent chromatin remodelling, and histone variant incorporation. These 2 multi-protein complexes share 4 subunits and function together to regulate the circuitry of H2A.Z biology. The components and functions of both multi-protein complexes are evolutionarily conserved and play important roles in multi-cellular development and cellular differentiation in higher eukaryotes. This review will summarize recent findings about NuA4 and SWR1-C and will focus on the connection between these complexes by investigating their physical and functional interactions through eukaryotic evolution.

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Structural and dynamical aspects of evolutionarily conserved protein–protein complexes

Protein Interactions ◽

10.1142/9789811211874_0001 ◽

2020 ◽

pp. 3-31

Author(s):

Himani Tandon ◽

Sneha Vishwanath ◽

Narayanaswamy Srinivasan

Keyword(s):

Protein Complexes ◽

Evolutionarily Conserved

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Post-translational modifications of Hsp90 and translating the chaperone code

Journal of Biological Chemistry ◽

10.1074/jbc.rev120.011833 ◽

2020 ◽

Vol 295 (32) ◽

pp. 11099-11117 ◽

Cited By ~ 2

Author(s):

Sarah J. Backe ◽

Rebecca A. Sager ◽

Mark R. Woodford ◽

Alan M. Makedon ◽

Mehdi Mollapour

Keyword(s):

Protein Complexes ◽

Cell Cycle Control ◽

Heat Shock Protein 90 ◽

Post Translational Modifications ◽

Cellular Processes ◽

Chaperone Function ◽

Short Period ◽

Evolutionarily Conserved ◽

Hsp90 Chaperone ◽

The Stability

Cells have a remarkable ability to synthesize large amounts of protein in a very short period of time. Under these conditions, many hydrophobic surfaces on proteins may be transiently exposed, and the likelihood of deleterious interactions is quite high. To counter this threat to cell viability, molecular chaperones have evolved to help nascent polypeptides fold correctly and multimeric protein complexes assemble productively, while minimizing the danger of protein aggregation. Heat shock protein 90 (Hsp90) is an evolutionarily conserved molecular chaperone that is involved in the stability and activation of at least 300 proteins, also known as clients, under normal cellular conditions. The Hsp90 clients participate in the full breadth of cellular processes, including cell growth and cell cycle control, signal transduction, DNA repair, transcription, and many others. Hsp90 chaperone function is coupled to its ability to bind and hydrolyze ATP, which is tightly regulated both by co-chaperone proteins and post-translational modifications (PTMs). Many reported PTMs of Hsp90 alter chaperone function and consequently affect myriad cellular processes. Here, we review the contributions of PTMs, such as phosphorylation, acetylation, SUMOylation, methylation, O-GlcNAcylation, ubiquitination, and others, toward regulation of Hsp90 function. We also discuss how the Hsp90 modification state affects cellular sensitivity to Hsp90-targeted therapeutics that specifically bind and inhibit its chaperone activity. The ultimate challenge is to decipher the comprehensive and combinatorial array of PTMs that modulate Hsp90 chaperone function, a phenomenon termed the “chaperone code.”

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Structural modularity of the XIST ribonucleoprotein complex

10.1101/837229 ◽

2019 ◽

Cited By ~ 6

Author(s):

Zhipeng Lu ◽

Jimmy K. Guo ◽

Yuning Wei ◽

Diana R. Dou ◽

Brian Zarnegar ◽

...

Keyword(s):

Protein Complex ◽

Protein Complexes ◽

Effector Proteins ◽

General Strategy ◽

Sequence Motifs ◽

Modular Architecture ◽

Chimeric Rnas ◽

Xist Rna ◽

Evolutionarily Conserved ◽

Associated Proteins

SUMMARYLong noncoding RNAs are thought to regulate gene expression by organizing protein complexes through unclear mechanisms. XIST controls the inactivation of an entire X chromosome in female placental mammals. Here we develop and integrate several orthogonal structure-interaction methods to demonstrate that XIST RNA-protein complex folds into an evolutionarily conserved modular architecture. Chimeric RNAs and clustered protein binding in fRIP and eCLIP experiments align with long-range RNA secondary structure, revealing discrete XIST domains that interact with distinct sets of effector proteins. CRISPR-Cas9-mediated permutation of the Xist A-repeat location shows that A-repeat serves as a nucleation center for multiple Xist-associated proteins and m6A modification. Thus modular architecture plays an essential role, in addition to sequence motifs, in determining the specificity of RBP binding and m6A modification. Together, this work builds a comprehensive structure-function model for the XIST RNA-protein complex, and suggests a general strategy for mechanistic studies of large ribonucleoprotein assemblies.

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