chromatin dynamics
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2022 ◽  
Vol 23 (2) ◽  
pp. 968
Author(s):  
Matthew W. Faber ◽  
Tommy V. Vo

As part of a complex network of genome control, long regulatory RNAs exert significant influences on chromatin dynamics. Understanding how this occurs could illuminate new avenues for disease treatment and lead to new hypotheses that would advance gene regulatory research. Recent studies using the model fission yeast Schizosaccharomyces pombe (S. pombe) and powerful parallel sequencing technologies have provided many insights in this area. This review will give an overview of key findings in S. pombe that relate long RNAs to multiple levels of chromatin regulation: histone modifications, gene neighborhood regulation in cis and higher-order chromosomal ordering. Moreover, we discuss parallels recently found in mammals to help bridge the knowledge gap between the study systems.


2022 ◽  
Vol 8 ◽  
Author(s):  
Rabia Laghmach ◽  
Michele Di Pierro ◽  
Davit Potoyan

The interior of the eukaryotic cell nucleus has a crowded and heterogeneous environment packed with chromatin polymers, regulatory proteins, and RNA molecules. Chromatin polymer, assisted by epigenetic modifications, protein and RNA binders, forms multi-scale compartments which help regulate genes in response to cellular signals. Furthermore, chromatin compartments are dynamic and tend to evolve in size and composition in ways that are not fully understood. The latest super-resolution imaging experiments have revealed a much more dynamic and stochastic nature of chromatin compartments than was appreciated before. An emerging mechanism explaining chromatin compartmentalization dynamics is the phase separation of protein and nucleic acids into membraneless liquid condensates. Consequently, concepts and ideas from soft matter and polymer systems have been rapidly entering the lexicon of cell biology. In this respect, the role of computational models is crucial for establishing a rigorous and quantitative foundation for the new concepts and disentangling the complex interplay of forces that contribute to the emergent patterns of chromatin dynamics and organization. Several multi-scale models have emerged to address various aspects of chromatin dynamics, ranging from equilibrium polymer simulations, hybrid non-equilibrium simulations coupling protein binding and chromatin folding, and mesoscopic field-theoretic models. Here, we review these emerging theoretical paradigms and computational models with a particular focus on chromatin’s phase separation and liquid-like properties as a basis for nuclear organization and dynamics.


Author(s):  
Shuting Lai ◽  
Jin Jia ◽  
Xiaoyu Cao ◽  
Ping-Kun Zhou ◽  
Shanshan Gao

Linker histone H1.2, which belongs to the linker histone family H1, plays a crucial role in the maintenance of the stable higher-order structures of chromatin and nucleosomes. As a critical part of chromatin structure, H1.2 has an important function in regulating chromatin dynamics and participates in multiple other cellular processes as well. Recent work has also shown that linker histone H1.2 regulates the transcription levels of certain target genes and affects different processes as well, such as cancer cell growth and migration, DNA duplication and DNA repair. The present work briefly summarizes the current knowledge of linker histone H1.2 modifications. Further, we also discuss the roles of linker histone H1.2 in the maintenance of genome stability, apoptosis, cell cycle regulation, and its association with disease.


2022 ◽  
Author(s):  
Daniel P Melters ◽  
Keir C Neuman ◽  
Tatini Rakshit ◽  
Yamini Dalal

Chromatin accessibility is modulated in a variety of ways, both to create open and closed chromatin states which are critical for eukaryotic gene regulation. At the mechanistic single molecule level, how accessibility is regulated remains a fundamental question in the field. Here, we use single molecule tracking by high-speed atomic force microscopy to investigate this question using chromatin arrays and extend our findings into the nucleus. By high-speed atomic force microscopy, we tracked chromatin dynamics in real time and observed that the essential kinetochore protein CENP-C reduces the diffusion constant of CENP-A nucleosomes and the linker H1.5 protein restricts H3 nucleosome mobility. We subsequently interrogated how CENP-C modulates CENP-A chromatin dynamics in vivo. Overexpressing CENP-C resulted in reduced centromeric transcription and impaired loading of new CENP-A molecules. These data suggest a model in which inner kinetochore proteins are critically involved in modulating chromatin accessibility and consequently, noncoding transcription at human centromeres.


2021 ◽  
Author(s):  
Chia-Yeh Lin ◽  
Yao-Ming Chang ◽  
Hsin-Yi Tseng ◽  
Yen-Ling Shih ◽  
Hsiao-Hui Yeh ◽  
...  

Congenital heart disease (CHD) is often rooted in aberrant gene expression during heart development. As cells commit to a specific lineage during development, chromatin dynamics and developmental plasticity generally become more limited. However, it remains unclear how differentiated cardiomyocytes (CMs) undergo morphological and functional adaptations to the postnatal environment during the process of CM maturation. We sought to investigate the regulatory mechanisms that control postnatal cardiac gene networks. A time-series transcriptomic analysis of postnatal hearts revealed an integrated, time-ordered transcriptional network that regulates CM maturation. Remarkably, depletion of histone H2B ubiquitin ligase RNF20 after formation of the four-chamber heart disrupted these highly coordinated gene networks. As such, its ablation caused early-onset cardiomyopathy, a phenotype reminiscent of CHD. Furthermore, the dynamic modulation of chromatin accessibility by RNF20 during CM maturation was necessary for the operative binding of cardiac transcription factors that drive transcriptional gene networks. Together, our results reveal how epigenetic-mediated chromatin state transitions modulate time-ordered gene expression for CM maturation.


2021 ◽  
Author(s):  
Robert L. Lalonde ◽  
Cassie L. Kemmler ◽  
Frederike W. Riemslagh ◽  
Andrew J. Aman ◽  
Jelena Kresoja-Rakic ◽  
...  

The most-common strategy for zebrafish Cre/lox-mediated lineage labeling experiments combines ubiquitously expressed, lox-based Switch reporter transgenes with tissue-specific Cre or 4-OH-Tamoxifen-inducible CreERT2 driver lines. Although numerous Cre driver lines have been produced, only a few broadly expressed Switch reporters exist in zebrafish and their generation by random transgene integration has been challenging due to position-effect sensitivity of the lox-flanked recombination cassettes. Here, we compare commonly used Switch reporter lines for their recombination efficiency and reporter expression pattern during zebrafish development. Using different experimental setups, we show that ubi:Switch and hsp70l:Switch outperform current generations of two additional Switch reporters due to favorable transgene integration sites. Our comparisons also document preferential Cre-dependent recombination of ubi:Switch and hsp70l:Switch in distinct zebrafish tissues at early developmental stages. To investigate what genomic features may influence Cre accessibility and lox recombination efficiency in highly functional Switch lines, we mapped these transgenes and charted chromatin dynamics at their integration sites. Our data documents the heterogeneity among lox-based Switch transgenes towards informing suitable transgene selection for lineage labeling experiments. Our work further proposes that ubi:Switch and hsp70l:Switch define genomic integration sites suitable for universal transgene or switch reporter knock-in in zebrafish.


2021 ◽  
Author(s):  
Anoumid Vaziri ◽  
Daniel Wilinski ◽  
Peter Freddolino ◽  
Carrie Ferrario ◽  
MONICA DUS

Diet composition has a profound influence on brain physiology and behavior, but the mechanisms through which nutrient information is transmuted into neural changes remain elusive. Here we uncover how the metabolic enzyme O-GlcNAc Transferase (OGT) transforms information about the dietary environment into taste adaptations. We show that in the fly D. melanogaster, OGT decorates the chromatin of the sweet taste neurons and provides the nutrient context to drive changes in chromatin accessibility in response to high dietary sugar. Specifically, we found that OGT cooperates with the epigenetic silencer Polycomb Repressive Complex 2.1 (PRC2.1) to promote nutrient-sensitive variations in chromatin openness; these chromatin dynamics result in changes in gene expression and taste plasticity that are dependent on the catalytic activity of OGT. Parallel nutrigenomic signatures were also observed in the lingual epithelium of rats exposed to high dietary sugar, suggesting that this conserved metabolic-epigenetic pathway may also underlie diet-dependent taste changes in mammals. Together our findings reveal a novel role for nutriepigenetic signaling in the brain: amplifying nutrient perturbations into robust changes in chromatin accessibility and transcriptional output that shape neural and behavioral plasticity.


Genes ◽  
2021 ◽  
Vol 12 (12) ◽  
pp. 1998
Author(s):  
Yulong Li ◽  
Alexander J. Hartemink ◽  
David M. MacAlpine

Origins of DNA replication are specified by the ordered recruitment of replication factors in a cell-cycle—dependent manner. The assembly of the pre-replicative complex in G1 and the pre-initiation complex prior to activation in S phase are well characterized; however, the interplay between the assembly of these complexes and the local chromatin environment is less well understood. To investigate the dynamic changes in chromatin organization at and surrounding replication origins, we used micrococcal nuclease (MNase) to generate genome-wide chromatin occupancy profiles of nucleosomes, transcription factors, and replication proteins through consecutive cell cycles in Saccharomyces cerevisiae. During each G1 phase of two consecutive cell cycles, we observed the downstream repositioning of the origin-proximal +1 nucleosome and an increase in protected DNA fragments spanning the ARS consensus sequence (ACS) indicative of pre-RC assembly. We also found that the strongest correlation between chromatin occupancy at the ACS and origin efficiency occurred in early S phase, consistent with the rate-limiting formation of the Cdc45–Mcm2-7–GINS (CMG) complex being a determinant of origin activity. Finally, we observed nucleosome disruption and disorganization emanating from replication origins and traveling with the elongating replication forks across the genome in S phase, likely reflecting the disassembly and assembly of chromatin ahead of and behind the replication fork, respectively. These results provide insights into cell-cycle–regulated chromatin dynamics and how they relate to the regulation of origin activity.


2021 ◽  
Vol 177 ◽  
pp. S57
Author(s):  
Rengasamy Palanivel ◽  
Vinesh Vinayachandran ◽  
Shyam Biswal ◽  
Sanjay Rajagopalan

2021 ◽  
Author(s):  
Florian Mayrhofer ◽  
Angela M. Hanson ◽  
Carmen Falcone ◽  
Yang K. Xiang ◽  
Manuel F. Navedo ◽  
...  

Nuclear and ribosomal components define cell identity and function by regulating chromatin dynamics, gene expression, and protein turnover. Here we report that in the mouse central nervous system (CNS) under normal conditions, neurons accumulate nuclear and ribosomal material of oligodendrocyte (OL) origin. We show that neuronal accumulation of OL-derived nuclear and ribosomal material is brain area-specific, and in the cortex and hippocampal dentate gyrus gradually propagates during postnatal brain maturation. We further demonstrate that OL-to-neuron material transfer persists throughout adulthood and responds to neuroinflammation. We found that satellite OL of the gray matter form internuclear contacts with receiving neurons in the mouse brain. Similar close internuclear associations between satellite OL and neurons are present in the adult human cortex. Our findings provide the first evidence of wide-spread dynamic and selective OL-to-neuron nuclear and ribosomal material transfer in the mouse CNS and indicate that satellite OL serve as powerful mediators of neuronal function. Equivalent processes may occur in the human CNS and cause neurological disorders when dysregulated.


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