The box C/D snoRNP assembly factor Bcd1 interacts with the histone chaperone Rtt106 and controls its transcription dependent activity

Biogenesis of eukaryotic box C/D small nucleolar ribonucleoproteins initiates co-transcriptionally and requires the action of the assembly machinery including the Hsp90/R2TP complex, the Rsa1p:Hit1p heterodimer and the Bcd1 protein. We present genetic interactions between the Rsa1p-encoding gene and genes involved in chromatin organization including RTT106 that codes for the H3-H4 histone chaperone Rtt106p controlling H3K56ac deposition. We show that Bcd1p binds Rtt106p and controls its transcription-dependent recruitment by reducing its association with RNA polymerase II, modulating H3K56ac levels at gene body. We reveal the 3D structures of the free and Rtt106p-bound forms of Bcd1p using nuclear magnetic resonance and X-ray crystallography. The interaction is also studied by a combination of biophysical and proteomic techniques. Bcd1p interacts with a region that is distinct from the interaction interface between the histone chaperone and histone H3. Our results are evidence for a protein interaction interface for Rtt106p that controls its transcription-associated activity. Biogenesis of small nucleolar RNAs ribonucleoproteins (snoRNPs) requires dedicated assembly machinery. Here, the authors show that a subset of snoRNP assembly factors interacts, genetically or directly, with factors modulating chromatin architecture, suggesting a link between ribosome formation and chromatin functions.

Genomic targets and molecular partners of the chromatin regulator KAP1

Annamaria Kauzlaric

KAP1 is an enigmatic regulatory protein, first described some twenty years ago, shown to be involved in multiple and diverse cellular functions. Specifically, it mediates tasks critical to cell growth and differentiation, pluripotency, apoptosis, gene silencing, DNA repair and genomic integrity maintenance. In line with these findings, Kap1 deletion results in embryonic lethality, and its conditional ablation impairs crucial processes such as erythropoiesis, hepatic metabolism homeostasis and stress response. Initially named also TIF1ðœ, transcriptional intermediary factor 1ðœ, KAP1 was thought to mediate mostly chromatin-related functions. Accordingly, global maps of genomic recruitment of KAP1, generated with the advent of high-throughput technologies, display binding of this protein to thousands of loci in a multiplicity of cell types. Coupling such maps with data of transcriptional perturbations detected upon Kap1 depletion, and with the protein complexes associated with KAP1, proved to be a highly efficient approach to elucidate the molecular functions of KAP1. In particular, such studies unveiled the mechanisms of KAP1-mediated repression of different classes of transposable elements (TEs), and led to important evolutionary considerations on the strategies evolved by higher organisms to restrict the activity of these entities. Through its multiple functional domains, KAP1 interacts with a broad range of proteins, and our first goal was to establish the complete set of such potential cofactors. We found marked enrichment of KAP1 in the chromatin fraction of the nucleus, and accordingly, among its associated proteins, a strong preponderance of nucleic-acid contacting proteins. We revealed that KAP1 is part of a variety of relatively low molecular weight complexes, co-existing at comparable abundances. Study of the molecular functions of the hits suggested that KAP1 could partake in processes thus far unexplored in this context, such as DNA replication and active transcription. We then pursued with the thorough characterization of genome-wide KAP1 binding sites, and found significant fractions of RNA polymerase II (PolII)-dependent promoters and RNA polymerase III (PolIII)-transcribed elements, for the majority enriched with euchromatic marks, to be targeted by KAP1. Using high-throughput techniques, we uncovered that KAP1 variably affected the PolII pausing index of defined sets of genes, and downregulated transcription of tRNA genes. Our analyses of KAP1 genomic recruitments further led us to the discovery of novel genetic entities in the mouse genome, highly related to KRAB zinc finger protein (KZFP) genes. We described possible mechanisms underlying the evolution and amplification of these sequences and more broadly of the KZFP genes family. Furthermore, our data supported the existence of a KAP1-dependent regulatory circuit taming TE-contained enhancers located in the vicinity of these genetic units, thereby regulating their expression. We explored the proposed models of KAP1 functions in euchromatic regions of the genome, and with our results we provided the most complete analysis of the interactome of KAP1 thus far reported. Moreover, we annotated new potentially protein-coding transcripts belonging to the biggest single family of transcription factors encoded in the murine and human genomes. In sum, this work brings novel pieces of information that complement the current knowledge in the field, opening the way to further molecular studies clarifying the physiological roles of KAP1 in higher vertebrates.

EPFL2017

Phase specific transcriptional regulation of circadian clock and metabolism in mouse liver

Jonathan Aryeh Sobel

The molecular clock has been conserved from cyanobacteria to mammals and is believed to align behavioral and biochemical processes with the diurnal cycle. This cellular mechanism has been an advantage to increase the fitness of organisms through the ability to anticipate food availability or predator presence. Accumulating evidence has revealed that the circadian clock is intimately interconnected with the metabolic cycle. But, the nature of these interconnections is yet not clear at the transcriptional level, and the contribution of cis-regulatory modules has not been elucidated. Accessible chromatin regions of the genome are implicated in diverse processes, such as gene regulation through enhancers and promoters, insulation of genomic domains or alternative splicing. They allow cell-type specific programs that are controlled by tissue-specific transcription factors and chromatin modifiers, although tissue-specific regulation of the circadian clock remains unclear. Therefore, we compared genome-wide BMAL1 binding and chromatin accessibility in the liver and in NIH3T3 fibroblasts. Moreover, for the first time, our study explores the dynamics of accessible regions, histone 3 lysine 27 acetylation (H3K27ac) and RNA polymerase II (Pol II) every 4 hours over one day in mouse liver. In this study, we show that a substantial fraction of these accessible sites are oscillating during a diurnal cycle with a circadian period. We observed that these accessible regions are enriched in the proximity of actively transcribed genes, and that they are dynamically affected by the binding of transcription factors such as BMAL1. We investigated wild-type (WT) and Bmal1-/- genotypes, in night restricted feeding regimen and in Light-Dark (LD) cycle, to study the circadian clock regulatory network underlying diurnal transcription. Therefore, we applied a penalized generalized linear model to infer the activity of transcription factor binding motifs in oscillating accessible sites using Pol II loadings at the transcription start sites of nearby genes. We were able to recapitulate the known regulatory elements of the circadian clock, notably E-box, D-Box, and ROR-responsive elements (RRE) in the WT genotype. On the other hand, we found that Forkhead box (FOX), glucocorticoids responsive elements (GRE), and C-AMP Response Element (CRE) were the main contributors of the regulation of oscillating genes in Bmal1-/-. Finally, using a mixture model to detect footprints with a base pair resolution, we studied the dynamics of the accessibility overlapping E-box. Our last analysis suggested that BMAL1/CLOCK is binding on double E-boxes with a spacer of 6 or 7 bp in a hetero-tetramer configuration. A 3D structure model further supported this binding mode. In Summary, we used DNase I-seq and ChIP-seq of Pol II and H3K27ac to study the circadian chromatin landscape in a 4h time-resolved experimental design. We uncovered the underlying circadian transcriptional regulatory network and, we dissected the chromatin accessibility around BMAL1 binding sites at a base pair resolution, which led to an unappreciated mode of binding of BMAL1/CLOCK in a hetero-tetramer conformation on double E-boxes. Lastly, we found tissue-specific factors that might contribute to tissue-specific binding of BMAL1/CLOCK.

EPFL2016

Computational identification and experimental characterization of preferred downstream positions in human core promoters

Philipp Bucher, René Dreos

Author summary Transcription of genes by the RNA polymerase II enzyme initiates at a genomic region termed the core promoter. The core promoter is a regulatory region that may contain diverse short DNA sequence motifs/elements that confer specific properties to it. Interestingly, core promoter motifs can be located both upstream and downstream of the transcription start site. Variable compositions of core promoter elements were identified. The initiator (Inr) motif and the downstream core promoter element (DPE) is a combination of elements that has been identified and extensively characterized in fruit flies. Although a few Inr+DPE -containing human promoters were identified, the presence of transcriptionally important downstream core promoter positions within human promoters has been a matter of controversy in the literature. Here, using a newly-designed motif discovery strategy, we discovered preferred downstream positions in human promoters that resemble fruit fly DPE. Clustering of the corresponding sequence motifs in eight additional species indicated that such promoters could be common to multicellular non-plant organisms. Importantly, functional characterization of the newly discovered preferred downstream positions supports the existence of Inr+DPE-containing promoters in human genes. Metazoan core promoters, which direct the initiation of transcription by RNA polymerase II (Pol II), may contain short sequence motifs termed core promoter elements/motifs (e.g. the TATA box, initiator (Inr) and downstream core promoter element (DPE)), which recruit Pol II via the general transcription machinery. The DPE was discovered and extensively characterized in Drosophila, where it is strictly dependent on both the presence of an Inr and the precise spacing from it. Since the Drosophila DPE is recognized by the human transcription machinery, it is most likely that some human promoters contain a downstream element that is similar, though not necessarily identical, to the Drosophila DPE. However, only a couple of human promoters were shown to contain a functional DPE, and attempts to computationally detect human DPE-containing promoters have mostly been unsuccessful. Using a newly-designed motif discovery strategy based on Expectation-Maximization probabilistic partitioning algorithms, we discovered preferred downstream positions (PDP) in human promoters that resemble the Drosophila DPE. Available chromatin accessibility footprints revealed that Drosophila and human Inr+DPE promoter classes are not only highly structured, but also similar to each other, particularly in the proximal downstream region. Clustering of the corresponding sequence motifs using a neighbor-joining algorithm strongly suggests that canonical Inr+DPE promoters could be common to metazoan species. Using reporter assays we demonstrate the contribution of the identified downstream positions to the function of multiple human promoters. Furthermore, we show that alteration of the spacing between the Inr and PDP by two nucleotides results in reduced promoter activity, suggesting a spacing dependency of the newly discovered human PDP on the Inr. Taken together, our strategy identified novel functional downstream positions within human core promoters, supporting the existence of DPE-like motifs in human promoters.

PUBLIC LIBRARY SCIENCE2021