Alexandra Lusser

Distinct activities of CHD1 and ACF in ATP-dependent chromatin assembly.

CHD1 is a chromodomain-containing protein in the SNF2-like family of ATPases. Here we show that CHD1 exists predominantly as a monomer and functions as an ATP-utilizing chromatin assembly factor. This reaction involves purified CHD1, NAP1 chaperone, core histones and relaxed DNA. CHD1 catalyzes the ATP-dependent transfer of histones from the NAP1 chaperone to the DNA by a processive mechanism that yields regularly spaced nucleosomes. The comparative analysis of CHD1 and ACF revealed that CHD1 assembles chromatin with a shorter nucleosome repeat length than ACF. In addition, ACF, but not CHD1, can assemble chromatin containing histone H1, which is involved in the formation of higher-order chromatin structure and transcriptional repression. These results suggest a role for CHD1 in the assembly of active chromatin and a function of ACF in the assembly of repressive chromatin.

CHD1 motor protein is required for deposition of histone variant H3.3 into chromatin in vivo.

The organization of chromatin affects all aspects of nuclear DNA metabolism in eukaryotes. H3.3 is an evolutionarily conserved histone variant and a key substrate for replication-independent chromatin assembly. Elimination of chromatin remodeling factor CHD1 in Drosophila embryos abolishes incorporation of H3.3 into the male pronucleus, renders the paternal genome unable to participate in zygotic mitoses, and leads to the development of haploid embryos. Furthermore, CHD1, but not ISWI, interacts with HIRA in cytoplasmic extracts. Our findings establish CHD1 as a major factor in replacement histone metabolism in the nucleus and reveal a critical role for CHD1 in the earliest developmental instances of genome-scale, replication-independent nucleosome assembly. Furthermore, our results point to the general requirement of adenosine triphosphate (ATP)–utilizing motor proteins for histone deposition in vivo.

Histone acetylation: lessons from the plant kingdom

Post-translational acetylation of core histones is an enigmatic process. The identification of histone acetyltransferases and deacetylases as co-regulators of transcription in yeast and vertebrates has advanced our understanding of the biological role of histone acetylation and also improved our general insight into the molecular network of gene regulation. Basic features of histone acetylation in plants resemble those of other eukaryotes but there are differences, which are reflected in novel classes of histone deacetylase. Investigating histone acetylation in higher plants might reveal regulatory pathways distinct from animals, yet of essential importance for gene expression in plants.

Strategies for the reconstitution of chromatin

In eukaryotes, chromatin is the natural form of DNA in the nucleus. For hundreds of millions of years, DNA-binding factors have evolved with chromatin. It is therefore more desirable to study the molecular mechanisms of DNA-directed processes with chromatin than with naked DNA templates. To this end, it is necessary to reconstitute DNA and histones into chromatin. Fortunately, there are a variety of methods by which a nonspecialist can prepare chromatin of high quality. Here, we describe strategies and techniques for the reconstitution of chromatin in vitro.

A maize histone deacetylase and retinoblastoma-related protein physically interact and cooperate in repressing gene transcription

In mammalian cells the product of the human retinoblastoma tumour suppressor gene (pRb) can recruit Rpd3-like histone deacetylases to repress transcription. In this study, we investigated whether this mechanism might also be relevant in plants and found both conserved and distinct features. The expression profiles of the Zea mays Rpd3-type histone deacetylase (ZmRpd3I) and the retinoblastoma-related (ZmRBR1) homologues were analysed during endosperm development. GST pull-down and immunoprecipitation experiments showed a physical interaction between ZmRBR1 and ZmRpd3I. Because ZmRpd3I lacks a LXCXE motif, conserved in several pRb-interacting proteins, we have mapped the amino acid domains involved in the ZmRBR1/ZmRpd3I interaction. Furthermore, we observed that ZmRbAp1, a maize member of the MSI/RbAp family, facilitated this protein interaction. Co-transformations of tobacco protoplasts with plasmids expressing ZmRBR1 and ZmRpd3I showed that the two proteins cooperate in repressing gene transcription. Our findings represent the first indication that in plants a regulator of important biological processes, ZmRBR1, can recruit a histone deacetylase, ZmRpd3I, to control gene transcription.

Long non-coding RNAs as targets for cytosine methylation.

Post-synthetic modifications of nucleic acids have long been known to affect their functional and structural properties. For instance, numerous different chemical modifications modulate the structural organization, stability or translation efficiency of tRNAs and rRNAs. In contrast, little is known about modifications of poly(A)RNAs. Here, we demonstrate for the first time that the two well-studied regulatory long non-coding RNAs HOTAIR and XIST are targets of site-specific cytosine methylation. In both XIST and HOTAIR, we found methylated cytosines located within or near functionally important regions that are known to mediate interaction with chromatin-associated protein complexes. We show that cytosine methylation in the XIST A structure strongly affects binding to the chromatin-modifying complex PRC2 in vitro. These results suggest that cytosine methylation may serve as a general strategy to regulate the function of long non-coding RNAs.

Comparative analysis of HD2 type histone deacetylases in higher plants

Abstract. Zea mays (L.) histone deacetylase HD2 was identified as a new type of histone deacetylase (HDAC) unrelated to the well-known Rpd3p and Hda1p families but with sequence homology to peptidyl-prolyl cis-trans isomerases (PPIases). Here we show that HD2 is a multigene family with highly related members in various plant species. Gene analysis revealed a similar exon/intron structure in Arabidopsis thaliana (L.) Heynh. and Z. mays, and most of the sequences analyzed were demonstrated to possess an intron of the very rare AT-AC type.

A COMPARATIVE STUDY OF HISTONE DEACETYLASES OF PLANT, FUNGAL AND VERTEBRATE CELLS

The enzymatic equilibrium of reversible core histone acetylation is maintained by two enzyme activities, histone acetyltransferase and histone deacetylase (HD). These enzyme activities exist as multiple enzyme forms. The present report describes methods to extract different HD-forms from three organisms, germinating maize embryos, the myxomycete Physarum polycephalum, and chicken red blood cells; it provides data on the chromatographic separation and partial purification of HD-forms. In germinating maize embryos three HDs (HD1-A, HD1-B, HD2) can be discriminated; HD1-A, HD1-B, and HD2 were characterized in terms of their dependence on pH, temperature and various ions, as well as kinetic parameters (Km for core histones) and inhibition by various compounds. The same parameters were investigated for the corresponding enzymes of Physarum polycephalum, and mature and immature chicken erythrocytes. Based on these results, optimum assay conditions were established for the different enzyme forms. The kinetic data revealed that the maize histone deacetylase HD1-B peak after partial purification by Q-Sepharose chromatography was heterogeneous and consisted of two histone binding sites that differed significantly in their affinity for purified core histones. Optimized affinity chromatography on poly-Lysine Agarose indeed showed that the former defined deacetylase HD1-B can be separated clearly into two individual HD enzyme forms. The high multiplicity of histone deacetylases underlines the importance of these enzymes for the complex regulation of core histone acetylation.

Acetylated, methylated, remodeled: chromatin states for gene regulation.

The activity state of a gene is determined not only by sequence-specific regulatory factors but also by a complex network of co-acting proteins. Many of these proteins directly or indirectly affect the structure of the chromatin environment into which the gene is embedded. Recent studies of histone and DNA modifications support and refine the concept of the chromatin environment being key to the establishment and maintenance of transcriptional activity or repression.

Distinct 5-methylcytosine profiles in poly(A) RNA from mouse embryonic stem cells and brain

BackgroundRecent work has identified and mapped a range of posttranscriptional modifications in mRNA, including methylation of the N6 and N1 positions in adenine, pseudouridylation, and methylation of carbon 5 in cytosine (m5C). However, knowledge about the prevalence and transcriptome-wide distribution of m5C is still extremely limited; thus, studies in different cell types, tissues, and organisms are needed to gain insight into possible functions of this modification and implications for other regulatory processes.ResultsWe have carried out an unbiased global analysis of m5C in total and nuclear poly(A) RNA of mouse embryonic stem cells and murine brain. We show that there are intriguing differences in these samples and cell compartments with respect to the degree of methylation, functional classification of methylated transcripts, and position bias within the transcript. Specifically, we observe a pronounced accumulation of m5C sites in the vicinity of the translational start codon, depletion in coding sequences, and mixed patterns of enrichment in the 3′ UTR. Degree and pattern of methylation distinguish transcripts modified in both embryonic stem cells and brain from those methylated in either one of the samples. We also analyze potential correlations between m5C and micro RNA target sites, binding sites of RNA binding proteins, and N6-methyladenosine.ConclusionOur study presents the first comprehensive picture of cytosine methylation in the epitranscriptome of pluripotent and differentiated stages in the mouse. These data provide an invaluable resource for future studies of function and biological significance of m5C in mRNA in mammals.