A capped Tudor domain within a core subunit of the Sin3L/Rpd3L histone deacetylase complex binds to nucleic acid G-quadruplexes.

Chromatin-modifying complexes containing histone deacetylase (HDAC) activities play critical roles in the regulation of gene transcription in eukaryotes. These complexes are thought to lack intrinsic DNA-binding activity, but according to a well-established paradigm, they are recruited via protein-protein interactions by gene-specific transcription factors and posttranslational histone modifications to their sites of action on the genome. The mammalian Sin3L/Rpd3L complex, comprising more than a dozen different polypeptides, is an ancient HDAC complex found in diverse eukaryotes. The subunits of this complex harbor conserved domains and motifs of unknown structure and function. Here, we show that Sds3, a constitutively-associated subunit critical for the proper functioning of the Sin3L/Rpd3L complex, harbors a type of Tudor domain that we designate the capped Tudor domain. Unlike canonical Tudor domains that bind modified histones, the Sds3 capped Tudor domain binds to nucleic acids that can form higher-order structures such as G-quadruplexes and shares similarities with the knotted Tudor domain of the Esa1 histone acetyltransferase that was previously shown to bind single-stranded RNA. Our findings expand the range of macromolecules capable of recruiting the Sin3L/Rpd3L complex and draw attention to potentially new biological roles for this HDAC complex.

Structure and Function of Chromatin Remodelers.

Chromatin remodelers act to regulate multiple cellular processes, such as transcription and DNA repair, by controlling access to genomic DNA. Four families of chromatin remodelers have been identified in yeast, each with non-redundant roles within the cell. There has been a recent surge in structural models of chromatin remodelers in complex with their nucleosomal substrate. These structural studies provide new insight into the mechanism of action for individual chromatin remodelers. In this review, we summarize available data for the structure and mechanism of action of the four chromatin remodeling complex families.

Structural Insights into the Evolutionarily Conserved BAF Chromatin Remodeling Complex.

The switch/sucrose nonfermentable (SWI/SNF) family of proteins acts to regulate chromatin accessibility and plays an essential role in multiple cellular processes. A high frequency of mutations has been found in SWI/SNF family subunits by exome sequencing in human cancer, and multiple studies support its role in tumor suppression. Recent structural studies of yeast SWI/SNF and its human homolog, BAF (BRG1/BRM associated factor), have provided a model for their complex assembly and their interaction with nucleosomal substrates, revealing the molecular function of individual subunits as well as the potential impact of cancer-associated mutations on the remodeling function. Here we review the structural conservation between yeast SWI/SNF and BAF and examine the role of highly mutated subunits within the BAF complex.

The neuronal transcription factor Myt1L interacts via a conserved motif with the PAH1 domain of Sin3 to recruit the Sin3L/Rpd3L histone deacetylase complex.

The Sin3L/Rpd3L histone deacetylase (HDAC) complex is one of six major HDAC complexes in the nucleus, and its recruitment by promoter-bound transcription factors is an important step in many gene transcription regulatory pathways. Here, we investigate how the Myt1L zinc finger transcription factor, important for neuronal differentiation and the maintenance of neuronal identity, recruits this complex at the molecular level. We show that Myt1L, through a highly conserved segment shared with its paralogs, interacts directly and specifically with the Sin3 PAH1 domain, binding principally to the canonical hydrophobic cleft found in paired amphipathic helix domain (PAH) domains. Our findings are relevant not only for other members of the Myt family but also for enhancing our understanding of the rules of protein-protein interactions involving Sin3 PAH domains.

Inositol phosphates and core subunits of the Sin3L/Rpd3L histone deacetylase (HDAC) complex up-regulate deacetylase activity.

The constitutively nuclear histone deacetylases (HDACs) 1, 2, and 3 erase acetyl marks on acetyllysine residues, alter the landscape of histone modifications, and modulate chromatin structure and dynamics and thereby crucially regulate gene transcription in higher eukaryotes. Nuclear HDACs exist as at least six giant multiprotein complexes whose nonenzymatic subunits confer genome targeting specificity for these enzymes. The deacetylase activity of HDACs has been shown previously to be enhanced by inositol phosphates, which also bridge the catalytic domain in protein-protein interactions with SANT (Swi3, Ada2, N-Cor, and TFIIIB) domains in all HDAC complexes except those that contain the Sin3 transcriptional corepressors. Here, using purified recombinant proteins, coimmunoprecipitation and HDAC assays, and pulldown and NMR experiments, we show that HDAC1/2 deacetylase activity in one of the most ancient and evolutionarily conserved Sin3L/Rpd3L complexes is inducibly up-regulated by inositol phosphates but involves interactions with a zinc finger motif in the Sin3-associated protein 30 (SAP30) subunit that is structurally unrelated to SANT domains, indicating convergent evolution at the functional level. This implies that this mode of regulation has evolved independently multiple times and provides an evolutionary advantage. We also found that constitutive association with another core subunit, Rb-binding protein 4 chromatin-binding factor (RBBP4), further enhances deacetylase activity, implying both inducible and constitutive regulatory mechanisms within the same HDAC complex. Our results indicate that inositol phosphates stimulate HDAC activity and that the SAP30 zinc finger motif performs roles similar to that of the unrelated SANT domain in promoting the SAP30-HDAC1 interaction and enhancing HDAC activity.

Cell-free protein synthesis from genomically recoded bacteria enables multisite incorporation of noncanonical amino acids.

Cell-free protein synthesis has emerged as a powerful approach for expanding the range of genetically encoded chemistry into proteins. Unfortunately, efforts to site-specifically incorporate multiple non-canonical amino acids into proteins using crude extract-based cell-free systems have been limited by release factor 1 competition. Here we address this limitation by establishing a bacterial cell-free protein synthesis platform based on genomically recoded Escherichia coli lacking release factor 1. This platform was developed by exploiting multiplex genome engineering to enhance extract performance by functionally inactivating negative effectors. Our most productive cell extracts enabled synthesis of 1,780 ± 30 mg/L superfolder green fluorescent protein. Using an optimized platform, we demonstrated the ability to introduce 40 identical p-acetyl-L-phenylalanine residues site specifically into an elastin-like polypeptide with high accuracy of incorporation ( ≥ 98%) and yield (96 ± 3 mg/L). We expect this cell-free platform to facilitate fundamental understanding and enable manufacturing paradigms for proteins with new and diverse chemistries.

Molecular Basis for the Mechanism of Constitutive CBP/p300 Coactivator Recruitment by CRTC1-MAML2 and Its Implications in cAMP Signaling.

The cyclic AMP response element-binding protein (CREB) is a signal-dependent transcription factor that exerts its positive effects on gene transcription of a broad range of genes by recruiting coactivators, including CREB-binding protein (CBP), its paralog, p300, and the family of CRTC (CREB-regulated transcriptional coactivators) proteins. Whereas recruitment of CBP/p300 is dependent on CREB phosphorylation at Ser133, recruitment of CRTCs is not. Here we describe how both mechanisms could concurrently drive transcription of CREB targets in a subset of head and neck cancers featuring chromosomal translocations that fuse portions of CRTC1 and CRTC3 genes with that of the Mastermind-like transcriptional coactivator MAML2. We show that a peptide derived from transactivation domain 1 (TAD1) of MAML2 binds to the CBP KIX domain with micromolar affinity. An ∼20-residue segment within this peptide, conserved in MAML2 orthologs and paralogs, binds directly to a KIX surface previously shown to bind to MLL1. The 20-residue MAML2 segment shares sequence similarity with MLL1, especially at those positions in direct contact with KIX, and like MLL1, the segment is characterized by the presence of an ∼10-residue helix. Because CRTC1/3-MAML2 fusion proteins are constitutively nuclear, like CREB, our results suggest constitutive recruitment of CBP/p300 to CREB targets that could be further enhanced by signals that cause CREB Ser133 phosphorylation.

Structural insights into the assembly of the histone deacetylase-associated Sin3L/Rpd3L corepressor complex.

Acetylation is correlated with chromatin decondensation and transcriptional activation, but its regulation by histone deacetylase (HDAC)-bearing corepressor complexes is poorly understood. Here, we describe the mechanism of assembly of the mammalian Sin3L/Rpd3L complex facilitated by Sds3, a conserved subunit deemed critical for proper assembly. Sds3 engages a globular, helical region of the HDAC interaction domain (HID) of the scaffolding protein Sin3A through a bipartite motif comprising a helix and an adjacent extended segment. Sds3 dimerizes through not only one of the predicted coiled-coil motifs but also, the segment preceding it, forming an ∼ 150-Å-long antiparallel dimer. Contrary to previous findings in yeast, Sin3A rather than Sds3 functions in recruiting HDAC1 into the complex by engaging the latter through a highly conserved segment adjacent to the helical HID subdomain. In the resulting model for the ternary complex, the two copies of the HDACs are situated distally and dynamically because of a natively unstructured linker connecting the dimerization domain and the Sin3A interaction domain of Sds3; these features contrast with the static organization described previously for the NuRD (nucleosome remodeling and deacetylase) complex. The Sds3 linker features several conserved basic residues that could potentially maintain the complex on chromatin by nonspecific interactions with DNA after initial recruitment by sequence-specific DNA-binding repressors.

Activation and trafficking of peritoneal B1a B-cells in response to amphibole asbestos.

B1a B-cells are concentrated in peritoneal and pleural cavities, are producers of 'natural auto-antibodies', and have been implicated in autoimmune responses. Their numbers are increased in humans and mice with systemic autoimmune diseases, but their role in the immune pathology is not known. Asbestos causes pulmonary, pleural, and peritoneal pathologies by accessing these tissues after inhalation. Amphibole asbestos has been shown to elicit immune dysfunction, including chronic inflammation, fibrosis, and autoantibody production. This study tested the hypothesis that asbestos affects immune dysfunction by activating B1a B-cells to traffic to secondary lymphatic tissue. C57Bl/6 mice were exposed to amphibole asbestos (Libby 6-Mix) either endotracheally or intraperitoneally, and the B1a B-cells in pleural or peritoneal compartments were tested by multi-parameter flow cytometry. Adoptive transfer of peritoneal lymphocytes from CD45.1 transgenic to wild-type mice was used to track the migration. The percentage and numbers of B1a B-cells in pleural and peritoneal cavities decreased 3-6 days following exposure. During that time, asbestos exposure led to a decrease in cells expressing alpha-4 (α4) integrin and MHC II antigen. Peritoneal cells treated in vitro showed decreased α4 integrin with no change in CD5, IgM, or MHC II antigen. Therefore, B1a cells (IgM(+), CD5(+), MHC II(+)) traffic from the peritoneal cavity following loss of α4 integrin expression. Following adoptive transfer into the peritoneum of asbestos-exposed mice, CD45.1(+) B1a cells were detected in the spleen and mesenteric lymph nodes after 3 days, peaking at 6 days. Interestingly, the percentage of splenic suppressor B-cells (IgM(+), CD5(+), CD11b(+), CD1d(+)) decreased following amphibole exposure, demonstrating that the B1a cells did not contribute to an increased pool of suppressive B-cells. These results show that B1a B-cells respond to asbestos exposure by trafficking to secondary lymphatic tissue where they may affect ultimate immune dysfunction.

Effects of Batrachochytrium dendrobatidis infection on ion concentrations in the boreal toad Anaxyrus (Bufo) boreas boreas.

Batrachochytrium dendrobatidis causes mortality in various amphibian species including the boreal toad Anaxyrus (Bufo) boreas boreas. The purpose of this study was to determine the physiological effects of this pathogen on experimentally infected boreal toads. Plasma osmolality, sodium, and potassium concentrations were analyzed to evaluate the differences between diseased and non-exposed animals. Infected animals with clinical signs of chytridiomycosis had significantly lower plasma osmolality, sodium, and potassium levels than non-infected animals (p < 0.06). On average, clinically infected animals housed in an aquatic environment had sodium and potassium levels of 60.1 (SE = 9.7) and 2.06 (SE = 0.32) mmol l(-1), respectively. These ion levels were significantly lower than the negative controls (sodium = 115.0 mmol l(-1), potassium = 3.7 mmol l(-1)) and consistent with the clinical signs observed in affected animals. We propose that infection with B. dendrobatidis results in an electrolyte disorder in boreal toads.