The COVID-19 pandemic is one of the most significant public health threats in recent history and has impacted the lives of almost everyone worldwide. Epigenetic mechanisms contribute to many aspects of the SARS-CoV-2 replication cycle, including expression levels of viral receptor ACE2, expression of cytokine genes as part of the host immune response, and the implication of various histone modifications in several aspects of COVID-19. SARS-CoV-2 proteins physically associate with many different host proteins over the course of infection, and notably there are several interactions between viral proteins and epigenetic enzymes such as HDACs and bromodomain-containing proteins as shown by correlation-based studies. The many contributions of epigenetic mechanisms to the viral life cycle and the host immune response to infection have resulted in epigenetic factors being identified as emerging biomarkers for COVID-19, and project epigenetic modifiers as promising therapeutic targets to combat COVID-19. This review article highlights the major epigenetic pathways at play during COVID-19 disease and discusses ongoing clinical trials that will hopefully contribute to slowing the spread of SARS-CoV-2.
The conserved and divergent roles of Prdm3 and Prdm16 in zebrafish and mouse craniofacial development
The formation of the craniofacial skeleton is a highly dynamic process that requires proper orchestration of various cellular processes in cranial neural crest cell (cNCC) development, including cell migration, proliferation, differentiation, polarity and cell death. Alterations that occur during cNCC development result in congenital birth defects and craniofacial abnormalities such as cleft lip with or without cleft palate. While the gene regulatory networks facilitating neural crest development have been extensively studied, the epigenetic mechanisms by which these pathways are activated or repressed in a temporal and spatially regulated manner remain largely unknown. Chromatin modifers can precisely modify gene expression through a variety of mechanisms including histone modifications such as methylation. Here, we investigated the role of two members of the PRDM (Positive regulatory domain) histone methyltransferase family, Prdm3 and Prdm16 in craniofacial development using genetic models in zebrafish and mice. Loss of prdm3 or prdm16 in zebrafish causes craniofacial defects including hypoplasia of the craniofacial cartilage elements, undefined posterior ceratobranchials, and decreased mineralization of the parasphenoid. In mice, while conditional loss of Prdm3 in the early embryo proper causes mid-gestation lethality, loss of Prdm16 caused craniofacial defects including anterior mandibular hypoplasia, clefting in the secondary palate and severe middle ear defects. In zebrafish, prdm3 and prdm16 compensate for each other as well as a third Prdm family member, prdm1a. Combinatorial loss of prdm1a, prdm3, and prdm16 alleles results in severe hypoplasia of the anterior cartilage elements, abnormal formation of the jaw joint, complete loss of the posterior ceratobranchials, and clefting of the ethmoid plate. We further determined that loss of prdm3 and prdm16 reduces methylation of histone 3 lysine 9 (repression) and histone 3 lysine 4 (activation) in zebrafish. In mice, loss of Prdm16 significantly decreased histone 3 lysine 9 methylation in the palatal shelves but surprisingly did not change histone 3 lysine 4 methylation. Taken together, Prdm3 and Prdm16 play an important role in craniofacial development by maintaining temporal and spatial regulation of gene regulatory networks necessary for proper cNCC development and these functions are both conserved and divergent across vertebrates.
NuA4 (nucleosome acetyltransferase of H4) promotes transcriptional initiation of TFIID (a complex of TBP and TBP-associated factors [TAFs])-dependent ribosomal protein genes involved in ribosome biogenesis. However, it is not clearly understood how NuA4 regulates the transcription of ribosomal protein genes. Here, we show that NuA4 is recruited to the promoters of ribosomal protein genes, such as RPS5, RPL2B, and RPS11B, for TFIID recruitment to initiate transcription, and the recruitment of NuA4 to these promoters is impaired in the absence of its Eaf1p component. Intriguingly, impaired NuA4 recruitment in a ⌬eaf1 strain depletes recruitment of TFIID (a TAF-dependent form of TBP) but not the TAF-independent form of TBP to the promoters of ribosomal protein genes. However, in the absence of NuA4, SAGA (Spt-Ada-Gcn5-acetyltransferase) is involved in targeting the TAF-independent form of TBP to the promoters of ribosomal protein genes for transcriptional initiation. Thus, NuA4 plays an important role in targeting TFIID to the promoters of ribosomal protein genes for transcriptional initiation in vivo. Such a function is mediated via its targeted histone acetyltransferase activity. In the absence of NuA4, ribosomal protein genes lose TFIID dependency and become SAGA dependent for transcriptional initiation. Collectively, these results provide significant insights into the regulation of ribosomal protein gene expression and, hence, ribosome biogenesis and functions.H istone H4 acetylation plays important roles in the regulation of eukaryotic transcription and other biological processes (1-3). In Saccharomyces cerevisiae, NuA4 (nucleosome acetyltransferase of H4) acetylates histone H4. In addition, NuA4 is involved in acetylation of histones H2A and H2A.Z (4-7). NuA4 is a multisubunit protein complex and is conserved from yeast to humans (Tip60 is the human homologue of yeast NuA4) (8). Like other histone lysine (K) acetyltransferases (KATs), NuA4 is involved in various cellular events, such as transcription, DNA repair, and cell cycle progression (9-27). In addition, NuA4 is proposed to regulate cellular aging and autophagy via acetylation of nonhistone proteins (28-30). Likewise, Tip60 has numerous nonhistone targets involved in various cellular activities (31, 32). In addition, Tip60 has been found to be involved in performing critical functions in DNA repair and stem cell regulation (33-36). Therefore, NuA4 and its human homologue are multifunctional in maintaining normal cellular functions.Esa1p is the catalytic subunit of NuA4 with KAT activity (37, 38). In addition, NuA4 has 12 other subunits (39, 40). These subunits include Tra1p (ATM-related factor), Epl1p (enhancer of polycomb homologue), Arp4p (actin-related protein), Yaf9p (leukemogenic factor ENL/AF9 homologue), Act1p, and 7 Esa1p-associated factors, Eaf1p to Eaf7p. Eaf2p and Eaf4p are also known as Swc4p and Yng2p, respectively. Although Esa1p is the catalytic subunit of NuA4, it cannot acetylate nucleosomal histones on its own but can acetylate naked/f...
FACT (facilitates chromatin transcription), an evolutionarily conserved histone chaperone involved in transcription and other DNA transactions, is upregulated in cancers, and its downregulation is associated with cellular death. However, it is not clearly understood how FACT is fine-tuned for normal cellular functions. Here, we show that the FACT subunit Spt16 is ubiquitylated by San1 (an E3 ubiquitin ligase) and degraded by the 26S proteasome. Enhanced abundance of Spt16 in the absence of San1 impairs transcriptional elongation. Likewise, decreased abundance of Spt16 also reduces transcription. Thus, an optimal level of Spt16 is required for efficient transcriptional elongation, which is maintained by San1 via ubiquitylation and proteasomal degradation. Consistently, San1 associates with the coding sequences of active genes to regulate Spt16's abundance. Further, we found that enhanced abundance of Spt16 in the absence of San1 impairs chromatin reassembly at the coding sequence, similarly to the results seen following inactivation of Spt16. Efficient chromatin reassembly enhances the fidelity of transcriptional elongation. Taken together, our results demonstrate for the first time a fine-tuning of FACT by a ubiquitin proteasome system in promoting chromatin reassembly in the wake of elongating RNA polymerase II and transcriptional elongation, thus revealing novel regulatory mechanisms of gene expression. In eukaryotes, DNA is packaged into nucleosomes to form chromatin. Each nucleosome within chromatin consists of ϳ147 bp of DNA wrapped around a histone octamer containing one histone H3-H4 tetramer and two histone H2A-H2B dimers (1). Thus, chromatin structure plays crucial functions in regulation of DNA transactions such as transcription, replication, and DNA repair (2-4). A variety of factors are involved in altering chromatin structure and, hence, DNA transactions. These factors are generally classified as ATP-independent histone modifying enzymes, ATP-dependent chromatin remodelers, and histone chaperones. Histone modifying enzymes function through addition or removal of specific chemical groups (e.g., acetyl, methyl, ubiquitin, phospho, and SUMO), while ATP-dependent chromatin remodelers alter DNA-histone interactions or the composition of the nucleosome in an ATP-dependent manner. On the other hand, histone chaperones function by binding with nucleosomes or histones to facilitate assembly and/or disassembly of nucleosomes in an ATP-independent fashion. The histone chaperone that was first found to alter chromatin structure during transcription is FACT (facilitates chromatin transcription), which is evolutionarily conserved among eukaryotes (5, 6). In budding yeast (Saccharomyces cerevisiae), FACT is composed of Spt16 (suppressor of Ty) and Pob3 and physically interacts with nucleosomes with the assistance of the HMG (high mobility group) protein Nhp6. Likewise, FACT is also a heterodimer of Spt16 and SSRP1 (structurespecific recognition protein 1) in humans. SSRP1 contains HMG domain, while HMG domain is p...
Background: Bre1p is required for H2B ubiquitylation that promotes RNA polymerase II association with active genes, and hence transcription. Results: The RING domain of Bre1p facilitates, but a non-RING domain represses, transcription and RNA polymerase II association with active genes. Conclusion: Bre1p has a dominant-negative role in addition to its well known stimulatory function in transcription. Significance: This study unravels a hidden role of Bre1p in transcriptional regulation.
NuA4 histone lysine (K) acetyltransferase (KAT) promotes transcriptional initiation of TATA-binding protein (TBP)-associated factor (TAF)-dependent ribosomal protein genes. TAFs have also been recently found to enhance antisense transcription from the 3= end of the GAL10 coding sequence. However, it remains unknown whether, like sense transcription of the ribosomal protein genes, TAF-dependent antisense transcription of GAL10 also requires NuA4 KAT. Here, we show that NuA4 KAT associates with the GAL10 antisense transcription initiation site at the 3= end of the coding sequence. Such association of NuA4 KAT depends on the Reb1p-binding site that recruits Reb1p activator to the GAL10 antisense transcription initiation site. Targeted recruitment of NuA4 KAT to the GAL10 antisense transcription initiation site promotes GAL10 antisense transcription. Like NuA4 KAT, histone H3 K4/36 methyltransferases and histone H2B ubiquitin conjugase facilitate GAL10 antisense transcription, while the Swi/Snf and SAGA chromatin remodeling/modification factors are dispensable for antisense, but not sense, transcription of GAL10. Taken together, our results demonstrate for the first time the roles of NuA4 KAT and other chromatin regulatory factors in controlling antisense transcription, thus illuminating chromatin regulation of antisense transcription. Noncoding RNAs have been implicated in various cellular processes such as X-chromosome inactivation, genomic imprinting, dosage compensation, heterochromatin formation, metabolism, development, and differentiation (1-5). There are several classes of noncoding RNAs, which include microRNAs, small nuclear RNAs, small interfering RNAs, Piwi-interacting RNAs, and natural antisense transcripts (6). About 72% of genes in human and mouse are associated with antisense transcription (7,8). Antisense transcripts arise from the strand opposite to the sense strand and play regulatory functions in interfering with the stability of sense transcripts, and hence gene expression. Therefore, a number of studies have been focused on the use of antisense oligonucleotides in regulation of gene expression and treatment of diseases without permanently altering the genes. In fact, antisense oligonucleotides are in various clinical trials for treatment of diseases such as cancers, hypertension, respiratory illness, and HIV infection (9-13).Despite great potentials of antisense transcripts/transcription in disease pathogenesis and treatment, it is not clearly understood how antisense transcription is initiated. Recently, we have demonstrated that, like in sense transcription, RNA polymerase II is targeted to the 3= end of the GAL10 coding sequence by an activator Reb1p or Reb1p-binding site and general transcription factors (GTFs) such as transcription factor IID (TFIID) (which is composed of TATA-binding protein [TBP] and a set of TBP-associated factors [TAFs]), TFIIB, and Mediator to initiate antisense transcription (14). Further, we have shown that the Gal4p activator and proteasome that facilitate GAL10 s...
Cranial neural crest cells undergo cellular growth, patterning, and differentiation within the branchial arches to form cartilage and bone, resulting in a precise pattern of skeletal elements forming the craniofacial skeleton. However, it is unclear how cranial neural crest cells are regulated to give rise to the different shapes and sizes of the bone and cartilage. Epigenetic regulators are good candidates to be involved in this regulation, since they can exert both broad as well as precise control on pattern formation. Here, we investigated the role of the histone acetyltransferases Kat2a and Kat2b in craniofacial development using TALEN/CRISPR/Cas9 mutagenesis in zebrafish and the Kat2ahat/hat (also called Gcn5) allele in mice. kat2a and kat2b are broadly expressed during embryogenesis within the central nervous system and craniofacial region. Single and double kat2a and kat2b zebrafish mutants have an overall shortening and hypoplastic nature of the cartilage elements and disruption of the posterior ceratobranchial cartilages, likely due to smaller domains of expression of both cartilage- and bone-specific markers, including sox9a and col2a1, and runx2a and runx2b, respectively. Similarly, in mice we observe defects in the craniofacial skeleton, including hypoplastic bone and cartilage and altered expression of Runx2 and cartilage markers (Sox9, Col2a1). In addition, we determined that following the loss of Kat2a activity, overall histone 3 lysine 9 (H3K9) acetylation, the main epigenetic target of Kat2a/Kat2b, was decreased. These results suggest that Kat2a and Kat2b are required for growth and differentiation of craniofacial cartilage and bone in both zebrafish and mice by regulating H3K9 acetylation.
Sus1p is a common component of transcriptional co-activator, SAGA (Spt-Ada-Gcn5-Acetyltransferase), and mRNA export complex, TREX-2 (Transcription-export 2), and is involved in promoting transcription as well as mRNA export. However, it is not clearly understood how Sus1p promotes transcription. Here, we show that Sus1p is predominantly recruited to the upstream activating sequence of a SAGA-dependent gene, GAL1, under transcriptionally active conditions as a component of SAGA to promote the formation of pre-initiation complex (PIC) at the core promoter, and consequently, transcriptional initiation. Likewise, Sus1p promotes the PIC formation at other SAGA-dependent genes, and hence transcriptional initiation. Such function of Sus1p in promoting PIC formation and transcriptional initiation is not mediated via its role in regulation of SAGA’s histone H2B de-ubiquitylation activity. However, Sus1p’s function in regulation of histone H2B ubiquitylation is associated with transcriptional elongation, DNA repair and replication. Collectively, our results support that Sus1p promotes PIC formation (and hence transcriptional initiation) at the SAGA-regulated genes independently of histone H2B de-ubiquitylation, and further controls transcriptional elongation, DNA repair and replication via orchestration of histone H2B ubiquitylation, thus providing distinct functional insights of Sus1p in regulation of DNA transacting processes.
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