ABSTRACT
Codon usage bias, the preference for certain synonymous codons, is found in all genomes. Although synonymous mutations were previously thought to be silent, a large body of evidence has demonstrated that codon usage can play major roles in determining gene expression levels and protein structures. Codon usage influences translation elongation speed and regulates translation efficiency and accuracy. Adaptation of codon usage to tRNA expression determines the proteome landscape. In addition, codon usage biases result in nonuniform ribosome decoding rates on mRNAs, which in turn influence the cotranslational protein folding process that is critical for protein function in diverse biological processes. Conserved genome-wide correlations have also been found between codon usage and protein structures. Furthermore, codon usage is a major determinant of mRNA levels through translation-dependent effects on mRNA decay and translation-independent effects on transcriptional and posttranscriptional processes. Here, we discuss the multifaceted roles and mechanisms of codon usage in different gene regulatory processes.
Subject(s)
Codon Usage , Gene Expression , Protein Biosynthesis , Protein Folding , Animals , Eukaryota/genetics , Humans , RNA, Messenger/genetics , RNA, Messenger/metabolism , RNA, Transfer/genetics , RNA, Transfer/metabolism , Ribosomes/genetics , Ribosomes/metabolismABSTRACT
Elucidating the regulatory mechanisms of human brain evolution is essential to understanding human cognition and mental disorders. We generated multi-omics profiles and constructed a high-resolution map of 3D genome architecture of rhesus macaque during corticogenesis. By comparing the 3D genomes of human, macaque, and mouse brains, we identified many human-specific chromatin structure changes, including 499 topologically associating domains (TADs) and 1,266 chromatin loops. The human-specific loops are significantly enriched in enhancer-enhancer interactions, and the regulated genes show human-specific expression changes in the subplate, a transient zone of the developing brain critical for neural circuit formation and plasticity. Notably, many human-specific sequence changes are located in the human-specific TAD boundaries and loop anchors, which may generate new transcription factor binding sites and chromatin structures in human. Collectively, the presented data highlight the value of comparative 3D genome analyses in dissecting the regulatory mechanisms of brain development and evolution.
Subject(s)
Brain/embryology , Evolution, Molecular , Fetus/embryology , Genome , Organogenesis/genetics , Animals , Base Sequence , Chromatin/metabolism , DNA Transposable Elements/genetics , Enhancer Elements, Genetic/genetics , Gene Expression Regulation, Developmental , Humans , Macaca mulatta , Mice , Species Specificity , Synteny/genetics , Transcription Factors/metabolismABSTRACT
Both transcription and three-dimensional (3D) architecture of the mammalian genome play critical roles in neurodevelopment and its disorders. However, 3D genome structures of single brain cells have not been solved; little is known about the dynamics of single-cell transcriptome and 3D genome after birth. Here, we generated a transcriptome (3,517 cells) and 3D genome (3,646 cells) atlas of the developing mouse cortex and hippocampus by using our high-resolution multiple annealing and looping-based amplification cycles for digital transcriptomics (MALBAC-DT) and diploid chromatin conformation capture (Dip-C) methods and developing multi-omic analysis pipelines. In adults, 3D genome "structure types" delineate all major cell types, with high correlation between chromatin A/B compartments and gene expression. During development, both transcriptome and 3D genome are extensively transformed in the first post-natal month. In neurons, 3D genome is rewired across scales, correlated with gene expression modules, and independent of sensory experience. Finally, we examine allele-specific structure of imprinted genes, revealing local and chromosome (chr)-wide differences. These findings uncover an unknown dimension of neurodevelopment.
Subject(s)
Brain/growth & development , Genome , Sensation/genetics , Transcription, Genetic , Alleles , Animals , Animals, Newborn , Cell Lineage/genetics , Chromatin/metabolism , Gene Expression Regulation, Developmental , Gene Ontology , Gene Regulatory Networks , Genetic Loci , Genomic Imprinting , Mice , Multigene Family , Neuroglia/metabolism , Neurons/metabolism , Transcriptome/genetics , Visual Cortex/metabolismABSTRACT
Non-coding genetic variation is a major driver of phenotypic diversity and allows the investigation of mechanisms that control gene expression. Here, we systematically investigated the effects of >50 million variations from five strains of mice on mRNA, nascent transcription, transcription start sites, and transcription factor binding in resting and activated macrophages. We observed substantial differences associated with distinct molecular pathways. Evaluating genetic variation provided evidence for roles of â¼100 TFs in shaping lineage-determining factor binding. Unexpectedly, a substantial fraction of strain-specific factor binding could not be explained by local mutations. Integration of genomic features with chromatin interaction data provided evidence for hundreds of connected cis-regulatory domains associated with differences in transcription factor binding and gene expression. This system and the >250 datasets establish a substantial new resource for investigation of how genetic variation affects cellular phenotypes.
Subject(s)
Genetic Variation , Macrophages/metabolism , Transcription Factors/metabolism , Animals , Binding Sites , Bone Marrow Cells/cytology , CCAAT-Enhancer-Binding Protein-beta/genetics , CCAAT-Enhancer-Binding Protein-beta/metabolism , Cluster Analysis , Enhancer Elements, Genetic/genetics , Female , Gene Expression Regulation/drug effects , Lipopolysaccharides/pharmacology , Macrophages/cytology , Macrophages/drug effects , Male , Mice , Mice, Inbred BALB C , Mice, Inbred C57BL , Mice, Inbred NOD , Promoter Regions, Genetic , Protein Binding , Proto-Oncogene Proteins/genetics , Proto-Oncogene Proteins/metabolism , Trans-Activators/genetics , Trans-Activators/metabolism , Transcription Factors/geneticsABSTRACT
High-order chromatin structure plays important roles in gene expression regulation. Knowledge of the dynamics of 3D chromatin structures during mammalian embryo development remains limited. We report the 3D chromatin architecture of mouse gametes and early embryos using an optimized Hi-C method with low-cell samples. We find that mature oocytes at the metaphase II stage do not have topologically associated domains (TADs). In sperm, extra-long-range interactions (>4 Mb) and interchromosomal interactions occur frequently. The high-order structures of both the paternal and maternal genomes in zygotes and two-cell embryos are obscure but are gradually re-established through development. The establishment of the TAD structure requires DNA replication but not zygotic genome activation. Furthermore, unmethylated CpGs are enriched in A compartment, and methylation levels are decreased to a greater extent in A compartment than in B compartment in embryos. In summary, the global reprogramming of chromatin architecture occurs during early mammalian development.
Subject(s)
Chromatin/metabolism , Embryo, Mammalian/metabolism , Embryonic Development , Animals , Chromatin/chemistry , CpG Islands , DNA Methylation , DNA Replication , Embryo, Mammalian/chemistry , Epigenesis, Genetic , Female , Germ Cells/metabolism , Male , Metaphase , Mice , Mice, Inbred C57BL , Mice, Inbred DBA , Oocytes/cytology , Spermatozoa/metabolism , Zygote/metabolismABSTRACT
Imprinted gene clusters are confined genomic regions containing genes with parent-of-origin-dependent transcriptional activity. In this issue of Genes & Development, Loftus and colleagues (pp. 829-843) made use of an insightful combination of descriptive approaches, genetic manipulations, and epigenome-editing approaches to show that differences in nuclear topology precede the onset of imprinted expression at the Peg13-Kcnk9 locus. Furthermore, the investigators provide data in line with a model suggesting that parent-of-origin-specific topological differences could be responsible for parent-of-origin-specific enhancer activity and thus imprinted expression.
Subject(s)
DNA Methylation , Genomic ImprintingABSTRACT
Differences in chromatin state inherited from the parental gametes influence the regulation of maternal and paternal alleles in offspring. This phenomenon, known as genomic imprinting, results in genes preferentially transcribed from one parental allele. While local epigenetic factors such as DNA methylation are known to be important for the establishment of imprinted gene expression, less is known about the mechanisms by which differentially methylated regions (DMRs) lead to differences in allelic expression across broad stretches of chromatin. Allele-specific higher-order chromatin structure has been observed at multiple imprinted loci, consistent with the observation of allelic binding of the chromatin-organizing factor CTCF at multiple DMRs. However, whether allelic chromatin structure impacts allelic gene expression is not known for most imprinted loci. Here we characterize the mechanisms underlying brain-specific imprinted expression of the Peg13-Kcnk9 locus, an imprinted region associated with intellectual disability. We performed region capture Hi-C on mouse brains from reciprocal hybrid crosses and found imprinted higher-order chromatin structure caused by the allelic binding of CTCF to the Peg13 DMR. Using an in vitro neuron differentiation system, we showed that imprinted chromatin structure precedes imprinted expression at the locus. Additionally, activation of a distal enhancer induced imprinted expression of Kcnk9 in an allelic chromatin structure-dependent manner. This work provides a high-resolution map of imprinted chromatin structure and demonstrates that chromatin state established in early development can promote imprinted expression upon differentiation.
Subject(s)
DNA Methylation , Genomic Imprinting , Animals , Mice , Alleles , DNA Methylation/genetics , Genomic Imprinting/genetics , Chromatin , Neurogenesis/geneticsABSTRACT
The transcriptional repressor ZEB2 regulates development of many cell fates among somatic, neural, and hematopoietic lineages, but the basis for its requirement in these diverse lineages is unclear. Here, we identified a 400-basepair (bp) region located 165 kilobases (kb) upstream of the Zeb2 transcriptional start site (TSS) that binds the E proteins at several E-box motifs and was active in hematopoietic lineages. Germline deletion of this 400-bp region (Zeb2Δ-165mice) specifically prevented Zeb2 expression in hematopoietic stem cell (HSC)-derived lineages. Zeb2Δ-165 mice lacked development of plasmacytoid dendritic cells (pDCs), monocytes, and B cells. All macrophages in Zeb2Δ-165 mice were exclusively of embryonic origin. Using single-cell chromatin profiling, we identified a second Zeb2 enhancer located at +164-kb that was selectively active in embryonically derived lineages, but not HSC-derived ones. Thus, Zeb2 expression in adult, but not embryonic, hematopoiesis is selectively controlled by the -165-kb Zeb2 enhancer.
Subject(s)
Enhancer Elements, Genetic/genetics , Hematopoiesis/genetics , Transcription, Genetic/genetics , Zinc Finger E-box Binding Homeobox 2/genetics , Animals , Cell Differentiation/genetics , Cell Lineage/genetics , Chromatin/genetics , Dendritic Cells/physiology , Female , Humans , Male , Mice , Mice, Inbred C57BL , Monocytes/physiologyABSTRACT
The repeating structural unit of metazoan chromatin is the chromatosome, a nucleosome bound to a linker histone, H1. There are 11 human H1 isoforms with diverse cellular functions, but how they interact with the nucleosome remains elusive. Here, we determined the cryoelectron microscopy (cryo-EM) structures of chromatosomes containing 197 bp DNA and three different human H1 isoforms, respectively. The globular domains of all three H1 isoforms bound to the nucleosome dyad. However, the flanking/linker DNAs displayed substantial distinct dynamic conformations. Nuclear magnetic resonance (NMR) and H1 tail-swapping cryo-EM experiments revealed that the C-terminal tails of the H1 isoforms mainly controlled the flanking DNA orientations. We also observed partial ordering of the core histone H2A C-terminal and H3 N-terminal tails in the chromatosomes. Our results provide insights into the structures and dynamics of the chromatosomes and have implications for the structure and function of chromatin.
Subject(s)
DNA/chemistry , Histones/chemistry , Nucleosomes/chemistry , Cryoelectron Microscopy , DNA/ultrastructure , Humans , Nucleosomes/ultrastructure , Protein Isoforms/chemistryABSTRACT
Enhancers generate bidirectional noncoding enhancer RNAs (eRNAs) that may regulate gene expression. At present, the eRNA function remains enigmatic. Here, we report a 5' capped antisense eRNA PEARL (Pcdh eRNA associated with R-loop formation) that is transcribed from the protocadherin (Pcdh) α HS5-1 enhancer region. Through loss- and gain-of-function experiments with CRISPR/Cas9 DNA fragment editing, CRISPRi, and CRISPRa, as well as locked nucleic acid strategies, in conjunction with ChIRP, MeDIP, DRIP, QHR-4C, and HiChIP experiments, we found that PEARL regulates Pcdhα gene expression by forming local RNA-DNA duplexes (R-loops) in situ within the HS5-1 enhancer region to promote long-distance chromatin interactions between distal enhancers and target promoters. In particular, increased levels of eRNA PEARL via perturbing transcription elongation factor SPT6 lead to strengthened local three-dimensional chromatin organization within the Pcdh superTAD. These findings have important implications regarding molecular mechanisms by which the HS5-1 enhancer regulates stochastic Pcdhα promoter choice in single cells in the brain.
Subject(s)
Enhancer Elements, Genetic , Protocadherins , Chromatin , Enhancer Elements, Genetic/genetics , Gene Expression Regulation , Promoter Regions, Genetic/genetics , RNA , Transcription, GeneticABSTRACT
Telomere repeat binding factor 2 (TRF2) is an essential component of the telomeres and also plays an important role in a number of other non-telomeric processes. Detailed knowledge of the binding and interaction of TRF2 with telomeric nucleosomes is limited. Here, we study the binding of TRF2 to in vitro-reconstituted kilobasepair-long human telomeric chromatin fibres using electron microscopy, single-molecule force spectroscopy and analytical ultracentrifugation sedimentation velocity. Our electron microscopy results revealed that full-length and N-terminally truncated TRF2 promote the formation of a columnar structure of the fibres with an average width and compaction larger than that induced by the addition of Mg2+, in agreement with the in vivo observations. Single-molecule force spectroscopy showed that TRF2 increases the mechanical and thermodynamic stability of the telomeric fibres when stretched with magnetic tweezers. This was in contrast to the result for fibres reconstituted on the 'Widom 601' high-affinity nucleosome positioning sequence, where minor effects on fibre stability were observed. Overall, TRF2 binding induces and stabilises columnar fibres, which may play an important role in telomere maintenance.
Subject(s)
Chromatin , Shelterin Complex , Telomeric Repeat Binding Protein 2 , Humans , Nucleosomes , Telomere/metabolism , Telomere-Binding Proteins/genetics , Telomere-Binding Proteins/metabolism , Telomeric Repeat Binding Protein 2/geneticsABSTRACT
The histone chaperone FACT and histone H2B ubiquitination (H2Bub) facilitate RNA polymerase II (Pol II) passage through chromatin, yet it is not clear how they cooperate mechanistically. We used genomics, genetic, biochemical, and microscopic approaches to dissect their interplay in Schizosaccharomyces pombe. We show that FACT and H2Bub globally repress antisense transcripts near the 5' end of genes and inside gene bodies, respectively. The accumulation of these transcripts is accompanied by changes at genic nucleosomes and Pol II redistribution. H2Bub is required for FACT activity in genic regions. In the H2Bub mutant, FACT binding to chromatin is altered and its association with histones is stabilized, which leads to the reduction of genic nucleosomes. Interestingly, FACT depletion globally restores nucleosomes in the H2Bub mutant. Moreover, in the absence of Pob3, the FACT Spt16 subunit controls the 3' end of genes. Furthermore, FACT maintains nucleosomes in subtelomeric regions, which is crucial for their compaction.
Subject(s)
DNA-Binding Proteins/metabolism , High Mobility Group Proteins/metabolism , Histones/metabolism , Saccharomyces cerevisiae Proteins/metabolism , Schizosaccharomyces/metabolism , Transcriptional Elongation Factors/metabolism , Chromatin/metabolism , DNA-Binding Proteins/genetics , High Mobility Group Proteins/genetics , Histones/genetics , Molecular Chaperones/genetics , Molecular Chaperones/metabolism , Nucleosomes/metabolism , Protein Binding , RNA Polymerase II/metabolism , Saccharomyces cerevisiae/genetics , Saccharomyces cerevisiae Proteins/genetics , Schizosaccharomyces/genetics , Schizosaccharomyces pombe Proteins/genetics , Schizosaccharomyces pombe Proteins/metabolism , Transcription Factors/metabolism , Transcriptional Elongation Factors/genetics , UbiquitinationABSTRACT
Pioneer transcription factors (pTFs) bind to target sites within compact chromatin, initiating chromatin remodeling and controlling the recruitment of downstream factors. The mechanisms by which pTFs overcome the chromatin barrier are not well understood. Here, we reveal, using single-molecule fluorescence, how the yeast transcription factor Rap1 invades and remodels chromatin. Using a reconstituted chromatin system replicating yeast promoter architecture, we demonstrate that Rap1 can bind nucleosomal DNA within a chromatin fiber but with shortened dwell times compared to naked DNA. Moreover, we show that Rap1 binding opens chromatin fiber structure by inhibiting inter-nucleosome contacts. Finally, we reveal that Rap1 collaborates with the chromatin remodeler RSC to displace promoter nucleosomes, paving the way for long-lived bound states on newly exposed DNA. Together, our results provide a mechanistic view of how Rap1 gains access and opens chromatin, thereby establishing an active promoter architecture and controlling gene expression.
Subject(s)
Chromatin/metabolism , Nucleosomes/genetics , Saccharomyces cerevisiae Proteins/metabolism , Telomere-Binding Proteins/metabolism , Transcription Factors/metabolism , Chromatin/genetics , Chromatin Assembly and Disassembly , DNA/metabolism , DNA-Binding Proteins/metabolism , Gene Expression Regulation/genetics , Nucleosomes/metabolism , Nucleosomes/physiology , Promoter Regions, Genetic/genetics , Saccharomyces cerevisiae/genetics , Saccharomyces cerevisiae Proteins/genetics , Shelterin Complex , Telomere-Binding Proteins/genetics , Transcription Factors/geneticsABSTRACT
Somatic cell nuclear transfer (SCNT) can reprogram a somatic nucleus to a totipotent state. However, the re-organization of 3D chromatin structure in this process remains poorly understood. Using low-input Hi-C, we revealed that, during SCNT, the transferred nucleus first enters a mitotic-like state (premature chromatin condensation). Unlike fertilized embryos, SCNT embryos show stronger topologically associating domains (TADs) at the 1-cell stage. TADs become weaker at the 2-cell stage, followed by gradual consolidation. Compartments A/B are markedly weak in 1-cell SCNT embryos and become increasingly strengthened afterward. By the 8-cell stage, somatic chromatin architecture is largely reset to embryonic patterns. Unexpectedly, we found cohesin represses minor zygotic genome activation (ZGA) genes (2-cell-specific genes) in pluripotent and differentiated cells, and pre-depleting cohesin in donor cells facilitates minor ZGA and SCNT. These data reveal multi-step reprogramming of 3D chromatin architecture during SCNT and support dual roles of cohesin in TAD formation and minor ZGA repression.
Subject(s)
Cell Cycle Proteins/physiology , Chromatin/physiology , Chromosomal Proteins, Non-Histone/physiology , Nuclear Transfer Techniques , Zygote/physiology , Animals , Cell Line , Cell Nucleus , Chromatin Assembly and Disassembly , Computational Biology/methods , Datasets as Topic , Embryonic Development , Female , Male , Mice , Mice, Inbred C57BL , CohesinsABSTRACT
The emergence of aerobic respiration created unprecedented bioenergetic advantages, while imposing the need to protect critical genetic information from reactive byproducts of oxidative metabolism (i.e., reactive oxygen species, ROS). The evolution of histone proteins fulfilled the need to shield DNA from these potentially damaging toxins, while providing the means to compact and structure massive eukaryotic genomes. To date, several metabolism-linked histone post-translational modifications (PTMs) have been shown to regulate chromatin structure and gene expression. However, whether and how PTMs enacted by metabolically produced ROS regulate adaptive chromatin remodeling remain relatively unexplored. Here, we review novel mechanistic insights into the interactions of ROS with histones and their consequences for the control of gene expression regulation, cellular plasticity, and behavior.
Subject(s)
Gene Expression Regulation , Histones , Oxidation-Reduction , Protein Processing, Post-Translational , Reactive Oxygen Species , Histones/metabolism , Histones/genetics , Protein Processing, Post-Translational/genetics , Gene Expression Regulation/genetics , Humans , Reactive Oxygen Species/metabolism , Animals , Chromatin Assembly and Disassembly/genetics , Chromatin/genetics , Chromatin/metabolismABSTRACT
Chromatin organization undergoes drastic reconfiguration during gametogenesis. However, the molecular reprogramming of three-dimensional chromatin structure in this process remains poorly understood for mammals, including primates. Here, we examined three-dimensional chromatin architecture during spermatogenesis in rhesus monkey using low-input Hi-C. Interestingly, we found that topologically associating domains (TADs) undergo dissolution and reestablishment in spermatogenesis. Strikingly, pachytene spermatocytes, where synapsis occurs, are strongly depleted for TADs despite their active transcription state but uniquely show highly refined local compartments that alternate between transcribing and non-transcribing regions (refined-A/B). Importantly, such chromatin organization is conserved in mouse, where it remains largely intact upon transcription inhibition. Instead, it is attenuated in mutant spermatocytes, where the synaptonemal complex failed to be established. Intriguingly, this is accompanied by the restoration of TADs, suggesting that the synaptonemal complex may restrict TADs and promote local compartments. Thus, these data revealed extensive reprogramming of higher-order meiotic chromatin architecture during mammalian gametogenesis.
Subject(s)
Cellular Reprogramming , Chromatin Assembly and Disassembly , Chromatin/metabolism , Meiosis , Spermatogenesis , Spermatozoa/metabolism , Animals , Chromatin/chemistry , Chromatin/genetics , Gene Expression Regulation, Developmental , HCT116 Cells , Humans , Macaca mulatta , Male , Mice, Inbred C57BL , Mice, Knockout , Nucleic Acid Conformation , Pachytene Stage , Protein Conformation , Structure-Activity Relationship , Time Factors , Transcription, Genetic , X Chromosome InactivationABSTRACT
CSL proteins [named after the homologs CBF1 (RBP-Jκ in mice), Suppressor of Hairless and LAG-1] are conserved transcription factors found in animals and fungi. In the fission yeast Schizosaccharomyces pombe, they regulate various cellular processes, including cell cycle progression, lipid metabolism and cell adhesion. CSL proteins bind to DNA through their N-terminal Rel-like domain and central ß-trefoil domain. Here, we investigated the importance of DNA binding for CSL protein functions in fission yeast. We created CSL protein mutants with disrupted DNA binding and found that the vast majority of CSL protein functions depend on intact DNA binding. Specifically, DNA binding is crucial for the regulation of cell adhesion, lipid metabolism, cell cycle progression, long non-coding RNA expression and genome integrity maintenance. Interestingly, perturbed lipid metabolism leads to chromatin structure changes, potentially linking lipid metabolism to the diverse phenotypes associated with CSL protein functions. Our study highlights the critical role of DNA binding for CSL protein functions in fission yeast.
Subject(s)
Cell Cycle Proteins , Schizosaccharomyces pombe Proteins , Schizosaccharomyces , Transcription Factors , Schizosaccharomyces/metabolism , Schizosaccharomyces/genetics , Schizosaccharomyces pombe Proteins/metabolism , Schizosaccharomyces pombe Proteins/genetics , Protein Binding , Lipid Metabolism/genetics , DNA-Binding Proteins/metabolism , DNA-Binding Proteins/genetics , Cell Cycle/genetics , Gene Expression Regulation, Fungal , DNA, Fungal/metabolism , DNA, Fungal/geneticsABSTRACT
In somatic nuclei of female therian mammals, the two X chromosomes display very different chromatin states: One X is typically euchromatic and transcriptionally active, and the other is mostly silent and forms a cytologically detectable heterochromatic structure termed the Barr body. These differences, which arise during female development as a result of X-chromosome inactivation (XCI), have been the focus of research for many decades. Initial approaches to define the structure of the inactive X chromosome (Xi) and its relationship to gene expression mainly involved microscopy-based approaches. More recently, with the advent of genomic techniques such as chromosome conformation capture, molecular details of the structure and expression of the Xi have been revealed. Here, we review our current knowledge of the 3D organization of the mammalian X-chromosome chromatin and discuss its relationship with gene activity in light of the initiation, spreading, and maintenance of XCI, as well as escape from gene silencing.
Subject(s)
Chromatin/genetics , Gene Expression Regulation/genetics , X Chromosome Inactivation/genetics , X Chromosome/genetics , Animals , Female , Gene Silencing , Humans , Mammals , RNA, Long Noncoding/geneticsABSTRACT
Spt6 is a conserved factor that controls transcription and chromatin structure across the genome. Although Spt6 is viewed as an elongation factor, spt6 mutations in Saccharomyces cerevisiae allow elevated levels of transcripts from within coding regions, suggesting that Spt6 also controls initiation. To address the requirements for Spt6 in transcription and chromatin structure, we have combined four genome-wide approaches. Our results demonstrate that Spt6 represses transcription initiation at thousands of intragenic promoters. We characterize these intragenic promoters and find sequence features conserved with genic promoters. Finally, we show that Spt6 also regulates transcription initiation at most genic promoters and propose a model of initiation site competition to account for this. Together, our results demonstrate that Spt6 controls the fidelity of transcription initiation throughout the genome.
Subject(s)
Histone Chaperones/genetics , Histone Chaperones/physiology , Saccharomyces cerevisiae Proteins/genetics , Saccharomyces cerevisiae Proteins/physiology , Transcription Initiation, Genetic/physiology , Transcriptional Elongation Factors/genetics , Transcriptional Elongation Factors/physiology , Chromatin/physiology , Gene Expression Regulation, Fungal/genetics , Histone Chaperones/metabolism , Histones/physiology , Nuclear Proteins , Nucleosomes , Peptide Elongation Factors/physiology , Promoter Regions, Genetic/genetics , RNA Polymerase II , Saccharomyces cerevisiae/metabolism , Saccharomyces cerevisiae Proteins/metabolism , Schizosaccharomyces pombe Proteins/genetics , Schizosaccharomyces pombe Proteins/metabolism , Schizosaccharomyces pombe Proteins/physiology , Transcription Factors/physiology , Transcription Initiation Site/physiology , Transcription, Genetic/genetics , Transcriptional Elongation Factors/metabolismABSTRACT
The replacement of replication-coupled histones with non-canonical histone variants provides chromatin with additional properties and contributes to the plasticity of the epigenome. MacroH2A histone variants are counterparts of the replication-coupled histone H2A. They are characterized by a unique tripartite structure, consisting of a histone fold, an unstructured linker, and a globular macrodomain. MacroH2A1.1 and macroH2A1.2 are the result of alternative splicing of the MACROH2A1 gene and can have opposing biological functions. Here, we discuss the structural differences between the macrodomains of the two isoforms, resulting in differential ligand binding. We further discuss how this modulates gene regulation by the two isoforms, in cases resulting in opposing role of macroH2A1.1 and macroH2A1.2 in development and differentiation. Finally, we share recent insight in the evolution of macroH2As. Taken together, in this review, we aim to discuss in unprecedented detail distinct properties and functions of the fascinating macroH2A1 splice isoforms.