First open reading frame protein (ORF1p) of the Blattella germanica R1 retroposon and phylogenetically close GAG-like proteins of insects and fungi contain RRM domains

The rDNA locus of insects and other arthropods contains non-LTR retrotransposons (retroposons) that are specifically inserted into 28S rRNA genes. The most frequent retroposons are R1 and R2, but the mechanism of insertion and the functions of these mobile elements have not been studied in detail. A clone containing a full-length R1 retroposon copy was islated from the cosmid library of Blattella germanica genes and sequenced. The amino acid sequences encoded by ORF1 of the R1 retroposon were subjected to bioinformatic analysis. It was found that ORF1 of this mobile element encodes a protein (ORF1p) belonging to the superfamily of zinc finger (CCHC) retroviral nucleocapsid proteins and contains two conserved RRM domains (RNA-recognizing motifs) identified on the basis of analysis of the secondary structure of this protein. The discovery of RRM domains in ORF1p of R1 retroposons can contribute to the understanding of the mechanisms of their retrotransposition. We revealed a coiled-coil motif in the N-terminal region of R1 ORF1p, which is similar to the coiled-coil domain involved in homo- or heteromultimerization of proteins and in protein-protein interactions. The domain organization of homologous Gag-like proteins of retroposons in some insects and fungi was found to be similar to the structure established by us for R1 ORF1p of B. germanica.     

Domain organization of the ORF2 C-terminal region of the German cockroach retroposon R1

Using cosmid vector, a gene library of German cockroach Blattella germanica was constructed. From this library, clones containing full-length copies of two subfamilies of R1 retroposons were selected. Retroposons R1 of German cockroach belonging to different subfamilies were shown to be different in domain organization of the ORF2 C-terminal region. For the first time, retroposons transmembrane domains were identified in the sequences of R1. It was demonstrated that two retroposon R1 subfamilies of German cockroach arose as a result of intragenomic divergence rather than via horizontal transfer of alien mobile element into cockroach genome. The differences in domain organization appeared not as a result of saltatory recombination processes, but as a consequence of gradual mutation accumulation, which led to either degeneration, or to domain formation.     

<Superscript>1</Superscript>H, <Superscript>15</Superscript>N and <Superscript>13</Superscript>C backbone and side chain resonance assignments of the RRM domain from human RBM24

Tissue development requires the expression of a regulated subset of genes, and it is becoming clear that the process of alternative splicing also plays an important role in the production of necessary tissue-specific isoforms. However, only a few of these tissue-specific splicing factors in mammals have so far been discovered. One of these factors is the RNA-binding protein RBM24 which has been recently identified as a major regulator of alternative splicing in cardiac and skeletal muscle development. The RBM24 protein contains an RNA recognition motif (RRM) domain that presumably mediates the binding to target pre-mRNA required for regulation of the splicing patterns. Here we report ¹H, ¹⁵N and ¹³C chemical shift assignments of the backbone and sidechain atoms for the RRM domain from human RBM24. Secondary chemical shift analysis and relaxation measurement confirm the canonical architecture of the RRM domain. The data will allow for atomic level studies aimed at understanding splicing regulation of target genes in heart and muscle development and investigation into a separate role of RBM24 in modulating mRNA stability of genes involved in the p53 tumor suppressor pathway.     

Apo raver1 structure reveals distinct RRM domain orientations

Raver1 is a multifunctional protein that modulates both alternative splicing and focal adhesion assembly by binding to the nucleoplasmic splicing repressor polypyrimidine tract protein (PTB) or to the cytoskeletal proteins vinculin and α‐actinin. The amino‐terminal region of raver1 has three RNA recognition motif (RRM1, RRM2, and RRM3) domains, and RRM1 interacts with the vinculin tail (Vt) domain and vinculin mRNA. We previously determined the crystal structure of the raver1 RRM1–3 domains in complex with Vt at 2.75 Å resolution. Here, we report crystal structure of the unbound raver1 RRM1–3 domains at 2 Å resolution. The apo structure reveals that a bound sulfate ion disrupts an electrostatic interaction between the RRM1 and RRM2 domains, triggering a large relative domain movement of over 30°. Superposition with other RNA‐bound RRM structures places the sulfate ion near the superposed RNA phosphate group suggesting that this is the raver1 RNA binding site. While several single and some tandem RRM domain structures have been described, to the best of our knowledge, this is the second report of a three‐tandem RRM domain structure.     

Activities of the Sex-lethal protein in RNA binding and protein:protein interactions.

The Drosophila sex determination gene Sex-lethal (Sxl) controls its own expression, and the expression of downstream target genes such as transformer , by regulating pre-mRNA splicing and mRNA translation. Sxl codes an RNA-binding protein that consists of an N-terminus of approximately 100 amino acids, two 90 amino acid RRM domains, R1 and R2, and an 80 amino acid C-terminus. In the studies reported here we have examined the functional properties of the different Sxl protein domains in RNA binding and in protein:protein interactions. The two RRM domains are responsible for RNA binding. Specificity in the recognition of target RNAs requires both RRM domains, and proteins which consist of the single domains or duplicated domains have anomalous RNA recognition properties. Moreover, the length of the linker between domains can affect RNA recognition properties. Our results indicate that the two RRM domains mediate Sxl:Sxl protein interactions, and that these interactions probably occur both in cis and trans. We speculate that cis interactions between R1 and R2 play a role in RNA recognition by the Sxl protein, while trans interactions stabilize complex formation on target RNAs that contain two or more closely spaced binding sites. Finally, we show that the interaction of Sxl with the snRNP protein Snf is mediated by the R1 RRM domain.     

α-Helical coiled-coil oligomerization domains in extracellular proteins

Subunit oligomerization of many proteins is mediated by α-helical coiled-coil domains. 3,4-Hydrophobic heptad repeat sequences, the characteristic feature of the coiled-coil protein folding motif, have been found in a wide variety of gene products including cytoskeletal, nuclear, muscle, cell surface, extracellular, plasma, bacterial, and viral proteins. Whereas the majority of coiled-coil structures is represented by intracellular α-helical bundles that contain two polypeptide chains, examples of extracellular coiled-coil proteins are fewer in number. Most proteins located in the extracellular space form three-stranded α-helical assemblies. Recently, five-stranded coiled coils have been identified in thrombospondins 3 and 4 in cartilage oligomeric matrix protein, and the formation of a heterotetramer has been observed in in vitro studies with the recombinant asialoglycoprotein receptor oligomerization domain. Coiled-coil domains in laminins and probably also in tenascins and thrombospondins are responsible for the formation of tissue-specific isoforms by selective oligomerization of different polypeptide chains.     

Molecular cloning,expression patterns and subcellular localization of porcine <Emphasis Type="Italic">TMCO1</Emphasis> gene

The product of transmembrane and coiled-coil domains 1 (TMCO1) gene is a member of DUF841 superfamily of several eukaryotic proteins with unknown function. The partial DNA sequence of porcine TMCO1 was first cloned with a pig 567 bp ORF encoding 188 amino acids. By tissues expression analysis, the TMCO1 was found highly expressed in the liver, kidney and heart. The porcine TMCO1 protein was subsequently demonstrated to localize in the mitochondrion by confocal fluorescence microscopy. This data provides an important basis for conducing further studies on the functions and regulatory mechanisms underlying the role of TMCO1 gene.     

Distinct roles of the R3H and RRM domains in poly(A)-specific ribonuclease structural integrity and catalysis

Deadenylases specifically catalyze the degradation of eukaryotic mRNA poly(A) tail in the 3′- to 5′-end direction with the release of 5′-AMP as the product. Among the deadenylase family, poly(A)-specific ribonuclease (PARN) is unique in its domain composition, which contains three potential RNA-binding domains: the catalytic nuclease domain, the R3H domain and the RRM domain. In this research, we investigated the roles of these RNA-binding domains by comparing the structural features and enzymatic properties of mutants lacking either one or two of the three RNA-binding domains. The results showed that the R3H domain had the ability to bind various oligonucleotides at the micromolar level with no oligo(A) specificity. The removal of the R3H domain dissociated PARN into monomers, which still possessed the RNA-binding ability and catalytic functions. Unlike the critical role of the RRM domain in PARN processivity, the removal of the R3H domain did not affect the catalytic pattern of PARN. Our results suggested that both R3H and RRM domains were essential for the high affinity of long poly(A) substrate, but the R3H domain did not contribute to the substrate recognition of PARN. Compared to the RRM domain, the R3H domain played a more important role in the structural integrity of the dimeric PARN. The multiple RNA-binding domain architecture endows PARN the property of highly efficient catalysis in a highly processive mode.     

Site-directed spin labeling electron paramagnetic resonance study of the ORF1 protein from a mouse L1 retrotransposon

Long interspersed nuclear element-1 is a highly abundant mammalian retrotransposon that comprises 17% of the human genome. L1 retrotransposition requires the protein encoded by open reading frame-1 (ORF1p), which binds single-stranded RNA with high affinity and functions as a nucleic acid chaperone. ORF1p has been shown to adopt a homo-trimeric, asymmetric dumbbell-shaped structure. However, its atomic-level structure and mechanism of RNA binding remains poorly understood. Here, we report the results of a site-directed spin labeling electron paramagnetic resonance (SDSL-EPR) study of 27 residues within the RNA binding region of the full-length protein. The EPR data are compatible with the large RNA binding lobe of ORF1p containing a RNA recognition motif (RRM) domain and a carboxyl-terminal domain (CTD) that are predicted from crystallographic and NMR studies of smaller fragments of the protein. Interestingly, the EPR data indicate that residues in strands β3 and β4 of the RRM are structurally unstable, compatible with the previously observed sensitivity of this region to proteolysis. Affinity measurements and RNA-dependent EPR spectral changes map the RNA binding site on ORF1p to residues located in strands β3 and β4 of the RRM domain and to helix α1 of the CTD. Complementary in vivo studies also identify residues within the RRM domain that are required for retrotransposition. We propose that in the context of the full-length trimeric protein these distinct surfaces are positioned adjacent to one another providing a continuous surface that may interact with nucleic acids.     

A fish herpesvirus highlights functional diversities among Zα domains related to phase separation induction and A-to-Z conversion

Zalpha (Zα) domains bind to left-handed Z-DNA and Z-RNA. The Zα domain protein family includes cellular (ADAR1, ZBP1 and PKZ) and viral (vaccinia virus E3 and cyprinid herpesvirus 3 (CyHV-3) ORF112) proteins. We studied CyHV-3 ORF112, which contains an intrinsically disordered region and a Zα domain. Genome editing of CyHV-3 indicated that the expression of only the Zα domain of ORF112 was sufficient for normal viral replication in cell culture and virulence in carp. In contrast, its deletion was lethal for the virus. These observations revealed the potential of the CyHV-3 model as a unique platform to compare the exchangeability of Zα domains expressed alone in living cells. Attempts to rescue the ORF112 deletion by a broad spectrum of cellular, viral, and artificial Zα domains showed that only those expressing Z-binding activity, the capacity to induce liquid-liquid phase separation (LLPS), and A-to-Z conversion, could rescue viral replication. For the first time, this study reports the ability of some Zα domains to induce LLPS and supports the biological relevance of dsRNA A-to-Z conversion mediated by Zα domains. This study expands the functional diversity of Zα domains and stimulates new hypotheses concerning the mechanisms of action of proteins containing Zα domains.     

人类Boule基因在减数分裂时期的生物信息学分析

Boule（boll）基因是DAZ基因家族的一个新成员,含有一个RNA结合域和一个DAZ重复域,是人类精子发生减数分裂过程中主要调控因子。为了研究Boule基因结构及其功能,利用生物信,息学方法对Boule蛋白相关结构、相互作用蛋白及其功能进行分析和预测。结果表明,Boule蛋白存在明显的亲水区、疏水区和卷曲螺旋;不存在信号肽、跨膜结构;主要分布在细胞质、细胞核、线粒体中;二级结构以α-螺旋、延伸链、无规则卷曲所组成,并含有非正规二级结构区;作用蛋白主要为CDC25A蛋白．功能域主要包含RRM保守域。Boule蛋白在精子发生过程中第一次减数分裂的生殖细胞中特异性表达,而在减数分裂完全阻滞的睾丸组织中不表达。因此,Boule蛋白功能可能与雄性生殖细胞减数分裂相关基因表达有关。     

Transmembrane and Coiled-Coil Domain Family 1 Is a Novel Protein of the Endoplasmic Reticulum

The endoplasmic reticulum (ER) is a continuous membrane network in eukaryotic cells comprising the nuclear envelope, the rough ER, and the smooth ER. The ER has multiple critical functions and a characteristic structure. In this study, we identified a new protein of the ER, TMCC1 (transmembrane and coiled-coil domain family 1). The TMCC family consists of at least 3 putative proteins (TMCC1–3) that are conserved from nematode to human. We show that TMCC1 is an ER protein that is expressed in diverse human cell lines. TMCC1 contains 2 adjacent transmembrane domains near the C-terminus, in addition to coiled-coil domains. TMCC1 was targeted to the rough ER through the transmembrane domains, whereas the N-terminal region and C-terminal tail of TMCC1 were found to reside in the cytoplasm. Moreover, the cytosolic region of TMCC1 formed homo- or hetero-dimers or oligomers with other TMCC proteins and interacted with ribosomal proteins. Notably, overexpression of TMCC1 or its transmembrane domains caused defects in ER morphology. Our results suggest roles of TMCC1 in ER organization.     

Identification and solution structure of a highly conserved C-terminal domain within ORF1p required for retrotransposition of long interspersed nuclear element-1

Long interspersed nuclear element-1 (LINE-1 or L1) retrotransposons comprise a large fraction of the human and mouse genomes. The mobility of these successful elements requires the protein encoded by open reading frame-1 (ORF1p), which binds single-stranded RNA with high affinity and functions as a nucleic acid chaperone. In this report, we have used limited proteolysis, filter binding, and NMR spectroscopy to characterize the global structure of ORF1p and the three-dimensional structure of a highly conserved RNA binding domain. ORF1p contains three structured regions, a coiled-coil domain, a middle domain of unknown function, and a C-terminal domain (CTD). We show that high affinity RNA binding by ORF1p requires the CTD and residues within an amino acid protease-sensitive segment that joins the CTD to the middle domain. Insights in the mechanism of RNA binding were obtained by determining the solution structure of the CTD, which is shown to adopt a novel fold consisting of a three-stranded beta sheet that is packed against three alpha-helices. An RNA binding surface on the CTD has been localized using chemical shift perturbation experiments and is proximal to residues previously shown to be essential for retrotransposition, RNA binding, and chaperone activity. A similar structure and mechanism of RNA binding is expected for all vertebrate long interspersed nuclear element-1 elements, since residues encoding the middle, protease-sensitive segment, and CTD are highly conserved.     

Autoregulation of Fox protein expression to produce dominant negative splicing factors

The Fox proteins are a family of regulators that control the alternative splicing of many exons in neurons, muscle, and other tissues. Each of the three mammalian paralogs, Fox-1 (A2BP1), Fox-2 (RBM9), and Fox-3 (HRNBP3), produces proteins with a single RNA-binding domain (RRM) flanked by N- and C-terminal domains that are highly diversified through the use of alternative promoters and alternative splicing patterns. These genes also express protein isoforms lacking the second half of the RRM (FoxΔRRM), due to the skipping of a highly conserved 93-nt exon. Fox binding elements overlap the splice sites of these exons in Fox-1 and Fox-2, and the Fox proteins themselves inhibit exon inclusion. Unlike other cases of splicing autoregulation by RNA-binding proteins, skipping the RRM exon creates an in-frame deletion in the mRNA to produce a stable protein. These FoxΔRRM isoforms expressed from cDNA exhibit highly reduced binding to RNA in vivo. However, we show that they can act as repressors of Fox-dependent splicing, presumably by competing with full-length Fox isoforms for interaction with other splicing factors. Interestingly, the Drosophila Fox homolog contains a nearly identical exon in its RRM domain that also has flanking Fox-binding sites. Thus, rather than autoregulation of splicing controlling the abundance of the regulator, the Fox proteins use a highly conserved mechanism of splicing autoregulation to control production of a dominant negative isoform.     

A description of the Mei2-like protein family; structure,phylogenetic distribution and biological context

The Schizosaccharomyces pombe Mei2 gene encodes an RNA recognition motif (RRM) protein that stimulates meiosis upon binding a specific non-coding RNA and subsequent accumulation in a "mei2-dot" in the nucleus. We present here the first systematic characterization of the family of proteins with characteristic Mei2-like amino acid sequences. Mei2-like proteins are an ancient eukaryotic protein family with three identifiable RRMs. The C-terminal RRM (RRM3) is unique to Mei2-like proteins and is the most highly conserved of the three RRMs. RRM3 also contains conserved sequence elements at its C-terminus not found in other RRM domains. Single copy Mei2-like genes are present in some fungi, in alveolates such as Paramecium and in the early branching eukaryote Entamoeba histolytica, while plants contain small families of Mei2-like genes. While the C-terminal RRM is highly conserved between plants and fungi, indicating conservation of molecular mechanisms, plant Mei2-like genes have changed biological context to regulate various aspects of developmental pattern formation.