Snf2 proteins in plants: gene silencing and beyond

Proteins belonging to the conserved and diversified Snf2 family provide the ATP-driven motor subunits for remodelling systems, which control the accessibility of chromatin DNA. The 41 proteins of this family encoded in the Arabidopsis genome fall into 19 distinct subfamilies. Although most of the plant Snf2 proteins studied so far retain the functional specialization of their yeast and animal homologues, some have been adapted for functions occurring only in plants. We present a comprehensive in silico characterization of the domain architecture of the complete set of Arabidopsis Snf2 proteins. In combination with recent data on the molecular mechanisms underlying the functions of some yeast and animal homologues, this offers an insight into the different roles of Snf2 proteins in plants.     

<Superscript>1</Superscript>H, <Superscript>13</Superscript>C and <Superscript>15</Superscript>N resonance assignments of a C-terminal domain of human CHD1

Chromatin remodelling proteins are an essential family of eukaryotic proteins. They harness the energy from ATP hydrolysis and apply it to alter chromatin structure in order to regulate all aspects of genome biology. Chromodomain helicase DNA-binding protein 1 (CHD1) is one such remodelling protein that has specialised nucleosome organising abilities and is conserved across eukaryotes. CHD1 possesses a pair of tandem chromodomains that directly precede the core catalytic Snf2 helicase-like domain, and a C-terminal SANT-SLIDE DNA-binding domain. We have identified an additional conserved domain in the C-terminal region of CHD1. Here, we report the backbone and side chain resonance assignments for this domain from human CHD1 at pH 6.5 and 25 °C (BMRB No. 25638).     

SLIDE, the Protein Interacting Domain of Imitation Switch Remodelers, Binds DDT-Domain Proteins of Different Subfamilies in Chromatin Remodeling Complexes

The Imitation Switch (ISWI) type adenosine triphosphate (ATP)-dependent chromatin remodeling factors are conserved proteins in eukaryotes, and some of them are known to form stable remodeling complexes...     

Structural Variations in Protein Superfamilies: Actin and Tubulin

Structures of homologous proteins are usually conserved during evolution, as are critical active site residues. This is the case for actin and tubulin, the two most important cytoskeleton proteins in eukaryotes. Actins and their related proteins (Arps) constitute a large superfamily whereas the tubulin family has fewer members. Unaligned sequences of these two protein families were analysed by searching for short groups of family-specific amino acid residues, that we call motifs, and by counting the number of residues from one motif to the next. For each sequence, the set of motif-to-motif residue counts forms a subfamily-specific pattern (landmark pattern) allowing actin and tubulin superfamily members to be identified and sorted into subfamilies. The differences between patterns of individual subfamilies are due to inserts and deletions (indels). Inserts appear to have arisen at an early stage in eukaryote evolution as suggested by the small but consistent kingdom-dependent differences found within many Arp subfamilies and in γ-tubulins. Inserts tend to be in surface loops where they can influence subfamily-specific function without disturbing the core structure of the protein. The relatively few indels found for tubulins have similar positions to established results, whereas we find many previously unreported indel positions and lengths for the metazoan Arps.     

The integrase family of tyrosine recombinases: evolution of a conserved active site domain.

The integrases are a diverse family of tyrosine recombinases which rearrange DNA duplexes by means of conservative site-specific recombination reactions. Members of this family, of which the well-studied lambda Int protein is the prototype, were previously found to share four strongly conserved residues, including an active site tyrosine directly involved in transesterification. However, few additional sequence similarities were found in the original group of 27 proteins. We have now identified a total of 81 members of the integrase family deposited in the databases. Alignment and comparisons of these sequences combined with an evolutionary analysis aided in identifying broader sequence similarities and clarifying the possible functions of these conserved residues. This analysis showed that members of the family aggregate into subfamilies which are consistent with their biological roles; these subfamilies have significant levels of sequence similarity beyond the four residues previously identified. It was also possible to map the location of conserved residues onto the available crystal structures; most of the conserved residues cluster in the predicted active site cleft. In addition, these results offer clues into an apparent discrepancy between the mechanisms of different subfamilies of integrases.     

DNA-binding properties of ARID family proteins

The ARID (A–T Rich Interaction Domain) is a helix–turn–helix motif-based DNA-binding domain, conserved in all eukaryotes and diagnostic of a family that includes 15 distinct human proteins with important roles in development, tissue-specific gene expression and proliferation control. The 15 human ARID family proteins can be divided into seven subfamilies based on the degree of sequence identity between individual members. Most ARID family members have not been characterized with respect to their DNA-binding behavior, but it is already apparent that not all ARIDs conform to the pattern of binding AT-rich sequences. To understand better the divergent characteristics of the ARID proteins, we undertook a survey of DNA-binding properties across the entire ARID family. The results indicate that the majority of ARID subfamilies (i.e. five out of seven) bind DNA without obvious sequence preference. DNA-binding affinity also varies somewhat between subfamilies. Site-specific mutagenesis does not support suggestions made from structure analysis that specific amino acids in Loop 2 or Helix 5 are the main determinants of sequence specificity. Most probably, this is determined by multiple interacting differences across the entire ARID structure.     

Molecular phylogenetics of DNA 5mC-methyltransferases.

We have identified a total of 88 members of the DNA-(cytosine-5) methyltransferase (5mC MTase) family whose sequences have been deposited in the databases. The results of a comparison of these sequences is presented in the form of an alignment-based phylogenetic tree and sequence logos for 10 conserved motifs. Phylogenetic analysis showed that members of the family aggregate into subfamilies which are usually consistent with their target specificity. However, it was also shown that similar target specificity does not necessarily imply close homology of the catalytic domain of MTases, which strongly supports the hypothesis that target recognition evolved independently of catalytic properties. This analysis also indicate that the 5mC MTase was present in the cenancestor (last common ancestor) of eubacteria, archaebacteria, and eukaryotes. The phylogeny of the 5mC MTases catalytic domain provides the basis for establishing the patterns of evolutionary change that characterize this family of proteins with conserved structural core and variable and mobile modules not directly involved in formation of the active site.     

Nomenclature of the ARID family of DNA-binding proteins

The ARID is an ancient DNA-binding domain that is conserved throughout the evolution of higher eukaryotes. The ARID consensus sequence spans about 100 amino acid residues, and structural studies identify the major groove contact site as a modified helix-turn-helix motif. ARID-containing proteins exhibit a range of cellular functions, including participation in chromatin remodeling, and regulation of gene expression during cell growth, differentiation, and development. A subset of ARID family proteins binds DNA specifically at AT-rich sites; the remainder bind DNA nonspecifically. Orthologs to each of the seven distinct subfamilies of mammalian ARID-containing proteins are found in insect genomes, indicating the minimum age for the organization of these higher metazoan subfamilies. Many of these ancestral genes were duplicated and fixed over time to yield the 15 ARID-containing genes that are found in the human, mouse, and dog genomes. This paper describes a nomenclature, recommended by the Mouse Genomic Nomenclature Committee (MGNC) and accepted by the Human Genome Organization (HUGO) Gene Nomenclature Committee, for these mammalian ARID-containing genes that reflects this evolutionary history.     

Snf2-family proteins: chromatin remodellers for any occasion

Chromatin facilitates the housing of eukaryotic DNA within the nucleus and restricts access to the underlying sequences. Thus, the regulation of chromatin structure provides an excellent platform for regulating processes that require information stored within genomic DNA. Snf2 proteins are a family of helicase-like proteins that direct energy derived from ATP hydrolysis into the mechanical remodelling of chromatin structure. Here, we highlight some of the recent discoveries regarding this family of proteins and show Snf2 proteins have roles in many aspects of genetic metabolism. Recent developments include new insights into the mechanism for nucleosome spacing and histone dimer exchange; together with growing evidence for the involvement of Snf2 proteins in DNA repair.     

Structural and evolutionary relationships among the immunophilins: two ubiquitous families of peptidyl-prolyl cis-trans isomerases.

The immunophilins, protein receptors for the immunosuppressing drugs cyclosporin A and FK506 and related proteins from plants, fungi, and bacteria, have been analyzed structurally and evolutionarily. The cyclosporin A binding proteins (cyclophilins) represent one ubiquitous family of homologous proteins, and the FK506- and rapamycin-binding proteins (FKBPs) constitute a second, unrelated family. Multiple sequence alignments of members of each of these two protein families define the highly conserved residues that are likely to play important structural and functional roles, and mutations in representative members of these two families that abolish or alter function have been evaluated. FKBPs have undergone greater evolutionary divergence than the cyclophilins. Evolutionary trees were constructed using two distinct programs, and these trees establish the structural relationships that allow division of each of these families into subgroups. The results lead to the suggestion that several genes encoding isozymic forms of the FKBPs and possibly also of the cyclophilins existed in prokaryotes before the emergence of eukaryotes on earth and that representatives of these genes were transmitted to both kingdoms to give rise to current subfamilies of these proteins. By contrast, compartmentalization of both classes of immunophilins appears to have arisen independently in prokaryotes and eukaryotes, late in evolutionary history.     

Cloning and characterization of the murine Imitation Switch (ISWI) genes: differential expression patterns suggest distinct developmental roles for Snf2h and Snf2l

Here we report the cloning of two cDNAs, Snf2h and Snf2l, encoding the murine members of the Imitation Switch (ISWI) family of chromatin remodeling proteins. To gain insight into their function we examined the spatial and temporal expression patterns of Snf2h and Snf2l during development. In the brain, Snf2h is prevalent in proliferating cell populations whereas, Snf2l is predominantly expressed in terminally differentiated neurons after birth and in adult animals, concomitant with the expression of a neural specific isoform. Moreover, a similar proliferation/differentiation relationship of expression for these two genes was observed in the ovaries and testes of adult mice. These results are consistent with a role of Snf2h complexes in replication-associated nucleosome assembly and suggest that Snf2l complexes have distinct functions associated with cell maturation or differentiation.     

Complex evolutionary history and diverse domain organization of SET proteins suggest divergent regulatory interactions

? Plants and animals possess very different developmental processes, yet share conserved epigenetic regulatory mechanisms, such as histone modifications. One of the most important forms of histone modification is methylation on lysine residues of the tails, carried out by members of the SET protein family, which are widespread in eukaryotes. ? We analyzed molecular evolution by comparative genomics and phylogenetics of the SET genes from plant and animal genomes, grouping SET genes into several subfamilies and uncovering numerous gene duplications, particularly in the Suv, Ash, Trx and E(z) subfamilies. ? Domain organizations differ between different subfamilies and between plant and animal SET proteins in some subfamilies, and support the grouping of SET genes into seven main subfamilies, suggesting that SET proteins have acquired distinctive regulatory interactions during evolution. We detected evidence for independent evolution of domain organization in different lineages, including recruitment of new domains following some duplications. ? More recent duplications in both vertebrates and land plants are probably the result of whole-genome or segmental duplications. The evolution of the SET gene family shows that gene duplications caused by segmental duplications and other mechanisms have probably contributed to the complexity of epigenetic regulation, providing insights into the evolution of the regulation of chromatin structure.     

Mitochondrial Porin Por1 and Its Homolog Por2 Contribute to the Positive Control of Snf1 Protein Kinase in Saccharomyces cerevisiae

Saccharomyces cerevisiae Snf1 is a member of the conserved Snf1/AMP-activated protein kinase (Snf1/AMPK) family involved in regulating responses to energy limitation, which is detected by mechanisms that include sensing adenine nucleotides. Mitochondrial voltage-dependent anion channel (VDAC) proteins, also known as mitochondrial porins, are conserved in eukaryotes from yeast to humans and play key roles in mediating mitochondrial outer membrane permeability to small metabolites, including ATP, ADP, and AMP. We previously recovered the yeast mitochondrial porin Por1 (yVDAC1) from a two-hybrid screen for Snf1-interacting proteins. Here, we present evidence that Snf1 interacts with Por1 and its homolog Por2 (yVDAC2). Cells lacking Por1 and Por2, but not respiratory-deficient rho⁰ cells lacking the mitochondrial genome, exhibit reduced Snf1 activation loop phosphorylation in response to glucose limitation. Thus, Por1 and Por2 contribute to the positive control of Snf1 protein kinase. Physical proximity to the VDAC proteins and mitochondrial surface could facilitate Snf1''s ability to sense energy limitation.     

Mismatch repair proteins, meiosis, and mice: understanding the complexities of mammalian meiosis

Mammalian meiosis differs from that seen in lower eukaryotes in several respects, not least of which is the added complexity of dealing with chromosomal interactions across a much larger genome (12 MB over 16 chromosome pairs in Saccharomyces cerevisiae compared to 2500 MB over 19 autosome pairs in Mus musculus). Thus, the recombination machinery, while being highly conserved through eukaryotes, has evolved to accommodate such issues to preserve genome integrity and to ensure propagation of the species. One group of highly conserved meiotic regulators is the DNA mismatch repair protein family that, as their name implies, were first identified as proteins that act to repair DNA mismatches that arise primarily during DNA replication. Their function in ensuring chromosomal integrity has also translated into a critical role for this family in meiotic recombination in most sexually reproducing organisms. In mice, targeted deletion of certain family members results in severe consequences for meiotic progression and infertility. This review will focus on the studies involving these mutant mouse models, with occasional comparison to the function of these proteins in other organisms.     

The TIGRFAMs database of protein families

TIGRFAMs is a collection of manually curated protein families consisting of hidden Markov models (HMMs), multiple sequence alignments, commentary, Gene Ontology (GO) assignments, literature references and pointers to related TIGRFAMs, Pfam and InterPro models. These models are designed to support both automated and manually curated annotation of genomes. TIGRFAMs contains models of full-length proteins and shorter regions at the levels of superfamilies, subfamilies and equivalogs, where equivalogs are sets of homologous proteins conserved with respect to function since their last common ancestor. The scope of each model is set by raising or lowering cutoff scores and choosing members of the seed alignment to group proteins sharing specific function (equivalog) or more general properties. The overall goal is to provide information with maximum utility for the annotation process. TIGRFAMs is thus complementary to Pfam, whose models typically achieve broad coverage across distant homologs but end at the boundaries of conserved structural domains. The database currently contains over 1600 protein families. TIGRFAMs is available for searching or downloading at www.tigr.org/TIGRFAMs.