水稻双链RNA结合蛋白同源基因OsRBP的克隆及其表达的分析

在基因数据库中发现两个水稻EST片段与大白菜BcpLH基因的双链RNA结合结构域 (dsRBD)有同源的区域 ,根据同源片段的位置特征设计引物 ,用RT-RCR扩增粳稻 (Oryzasativasubsp .japonica)愈伤组织的cDNA ,得到大小为 1.8kb的DNA片段。该cDNA片段含完整的编码区 ,有两个典型的dsRBD ,分别与BcpLH的dsRBD在氨基酸水平上同源性为 75 %左右 ,故将其命名为OsRBP。RT -PCR表达分析显示该基因在未成熟的种子和愈伤组织中表达 ,在根、茎、叶、穗、成熟种子及胚芽鞘中没有表达信号 ,由此推测该基因的表达可能与种子和胚的早期发育相关。该研究首次从水稻中分离到双链RNA结合蛋白基因 ,并初步研究了其表达方式 ,为进一步探讨水稻重要器官的发育和植物中双链RNA结合蛋白的调节作用奠定了基础     

Structural and functional analysis reveals that human OASL binds dsRNA to enhance RIG-I signaling

The oligoadenylate synthetase (OAS) enzymes are cytoplasmic dsRNA sensors belonging to the antiviral innate immune system. Upon binding to viral dsRNA, the OAS enzymes synthesize 2′-5′ linked oligoadenylates (2-5As) that initiate an RNA decay pathway to impair viral replication. The human OAS-like (OASL) protein, however, does not harbor the catalytic activity required for synthesizing 2-5As and differs from the other human OAS family members by having two C-terminal ubiquitin-like domains. In spite of its lack of enzymatic activity, human OASL possesses antiviral activity. It was recently demonstrated that the ubiquitin-like domains of OASL could substitute for K63-linked poly-ubiquitin and interact with the CARDs of RIG-I and thereby enhance RIG-I signaling. However, the role of the OAS-like domain of OASL remains unclear. Here we present the crystal structure of the OAS-like domain, which shows a striking similarity with activated OAS1. Furthermore, the structure of the OAS-like domain shows that OASL has a dsRNA binding groove. We demonstrate that the OAS-like domain can bind dsRNA and that mutating key residues in the dsRNA binding site is detrimental to the RIG-I signaling enhancement. Hence, binding to dsRNA is an important feature of OASL that is required for enhancing RIG-I signaling.     

trans-Autophosphorylation by the isolated kinase domain is not sufficient for dimerization or activation of the dsRNA-activated protein kinase PKR

The double-stranded (ds) RNA-activated protein kinase PKR phosphorylates the alpha-subunit of the eukaryotic initiation factor 2 (eIF2alpha) and inhibits translation initiation. PKR contains two dsRNA binding domains in its amino terminus and a kinase domain in its carboxy terminus. dsRNA binding activates PKR from a latent state by inducing dimerization and trans-autophosphorylation. Recent studies show that PKR is also activated by caspase cleavage to remove the inhibitory dsRNA binding domains. In this report, we show that the isolated kinase domain of PKR is a constitutively active monomeric kinase that has an activity similar to that of wild-type PKR. We used a solid-phase kinase assay system to show that PKR does not transfer its own phosphate to either PKR or eIF2alpha but rather uses the gamma-phosphate from ATP. In addition, the isolated autophosphorylated kinase domain of PKR phosphorylated intact monomeric PKR in trans in a reaction that did not require dsRNA binding. However, this trans-phosphorylation did not occur at the critical Thr446/451 sites and was not sufficient to induce dimerization and/or activation of PKR. The results show that dsRNA binding domains of PKR are not only required for dimerization of PKR but also required for phosphorylation of Thr446/451 sites of PKR. The results imply that even though the isolated kinase domain of PKR phosphorylates intact PKR and eIF2alpha, it is unable to activate PKR.     

Cloning and expression of cDNA for human endonexin II, a Ca2+ and phospholipid binding protein

Endonexin II is a member of the family of Ca2+-dependent phospholipid binding proteins known as annexins. We cloned human endonexin II cDNA and expressed it in Escherichia coli. The apparent size and Ca2+-dependent phospholipid binding properties of purified recombinant endonexin II were indistinguishable from those of the placental protein. A single mRNA of approximately 1.6 kilobase pairs was found to be expressed in human cell lines and placenta and was in close agreement with the length of the cDNA clone (1.59 kilobase pairs). The cDNA predicted a 320-amino acid protein with a sequence that was in agreement with the previously determined partial amino acid sequence of endonexin II isolated from placenta. Endonexin II contained 58, 46, and 43% sequence identity to protein II, calpactin I (p36, protein I), and lipocortin I (p35), respectively. The partial sequence of bovine endonexin I was aligned with the sequence of endonexin II to give 63% sequence identity. Like these other proteins, endonexin II had a 4-fold internal repeat of approximately 70 residues preceded by an amino-terminal domain lacking similarity to the repeated region. It also had significant sequence identity with 67-kDa calelectrin (p68), a protein with an 8-fold internal repeat. Comparing the amino-terminal domains of these four proteins of known sequence revealed that, in general, only endonexin II and protein II had significant sequence identity (29%). Endonexin II was not phosphorylated by Ca2+/phospholipid-dependent enzyme (protein kinase C) even though it contained a threonine at a position analogous to the protein kinase C phosphorylation sites of lipocortin I, calpactin I, and protein II.     

Structural insights into RNA recognition by RIG-I

Intracellular RIG-I-like receptors (RLRs, including RIG-I, MDA-5, and LGP2) recognize viral RNAs as pathogen-associated molecular patterns (PAMPs) and initiate an antiviral immune response. To understand the molecular basis of this process, we determined the crystal structure of RIG-I in complex with double-stranded RNA (dsRNA). The dsRNA is sheathed within a network of protein domains that include a conserved "helicase" domain (regions HEL1 and HEL2), a specialized insertion domain (HEL2i), and a C-terminal regulatory domain (CTD). A V-shaped pincer connects HEL2 and the CTD by gripping an α-helical shaft that extends from HEL1. In this way, the pincer coordinates functions of all the domains and couples RNA binding with ATP hydrolysis. RIG-I falls within the Dicer-RIG-I clade of the superfamily 2 helicases, and this structure reveals complex interplay between motor domains, accessory mechanical domains, and RNA that has implications for understanding the nanomechanical function of this protein family and other ATPases more broadly.     

cDNA cloning,expression pattern and RNA binding analysis of human selenocysteine insertion sequence (SECIS) binding protein 2

Selenocysteine and selenoprotein synthesis require a complex molecular machinery in mammals. Among the key players is the RNA-protein complex formed by the selenocysteine insertion sequence (SECIS) binding protein (SBP2) and the SECIS element, an RNA hairpin in the 3' untranslated regions of selenoprotein messenger RNAs (mRNAs). We have isolated the DNA complementary to mRNA of the human SBP2, enabling us to establish that it differs from a previously reported human SBP2-like protein. Examination of the expression pattern revealed that the human SBP2 protein is encoded by a 4 kb long mRNA that is over-expressed in testis. Compared to the rat SBP2 sequence, the human SBP2 protein displays two highly conserved domains with 92 and 95% amino acid identity, the latter one containing the RNA binding domain. The inter-domain section carries 55% sequence identity, the remainder of the SBP2 sequences showing about 65% identity, values lower than expected for two mammalian proteins. Interestingly, we could show that the binding of human SBP2 to the SECIS RNA is stimulated by the selenoprotein-specialized elongation translation factor mSelB/eEFsec.     

Streptomyces chrysomallus FKBP-33 is a novel immunophilin consisting of two FK506 binding domains; its gene is transcriptionally coupled to the FKBP-12 gene.

The nucleotide sequence of the region 5' to the fkbA gene, encoding the Streptomyces chrysomallus FK506 binding protein (FKBP-12), revealed an open reading frame (fkbB) encoding a protein of 312 amino acids, with an M(r) of approximately 33,000. FkbB and fkbA appear to be co-transcribed under the control of a promoter upstream of fkbB. The presumptive protein encoded by fkbB would be an FKBP (designated FKBP-33) consisting of two FK506 binding domains with 43 and 32% sequence identity to FKBP-12 and a signal peptide sequence characteristic of bacterial membrane lipoproteins. The portion of the gene comprising the two FKBP domains, as well as each individual domain, were expressed as fusion proteins in Escherichia coli and purified. Each expressed domain, as well as FKBP-33 itself, possesses peptidyl-prolyl cis-trans isomerase activity, though with much lower specific activities than FKBP-12. FKBP-33 is located in the cell membrane of S.chrysomallus and of other streptomycetes, as predicted from the presence of the signal peptide sequence. Pulse-chase experiments with radioactive palmitate in whole cells revealed significant labelling of FKBP-33, which probably carries palmitate at its N-terminus and an additional diacylglycerol residue attached to the N-terminal cysteine in thioether linkage. The two domains of FKBP-33 showed considerable homology with numerous eukaryotic and prokaryotic FKB domains. Calculations of phylogenetic relationships indicate with high probability that the two domains of the protein have arisen by a double gene duplication of fkbA lying in tandem to fkbB.     

Double-stranded RNA binding by human cytomegalovirus pTRS1

The human cytomegalovirus (HCMV) TRS1 and IRS1 genes rescue replication of vaccinia virus (VV) that has a deletion of the double-stranded RNA binding protein gene E3L (VVDeltaE3L). Like E3L, these HCMV genes block the activation of key interferon-induced, double-stranded RNA (dsRNA)-activated antiviral pathways. We investigated the hypothesis that the products of these HCMV genes act by binding to dsRNA. pTRS1 expressed by cell-free translation or by infection of mammalian cells with HCMV or recombinant VV bound to dsRNA. Competition experiments revealed that pTRS1 preferentially bound to dsRNA compared to double-stranded DNA or single-stranded RNA. 5'- and 3'-end deletion analyses mapped the TRS1 dsRNA-binding domain to amino acids 74 through 248, a region of identity to pIRS1 that contains no homology to known dsRNA-binding proteins. Deletion of the majority of this region (Delta86-246) completely abrogated dsRNA binding. To determine the role of the dsRNA-binding domain in the rescue of VVDeltaE3L replication, wild-type or deletion mutants of TRS1 were transfected into HeLa cells, which were then infected with VVDeltaE3L. While full-length TRS1 rescued VVDeltaE3L replication, deletion mutants affecting a carboxy-terminal region of TRS1 that is not required for dsRNA binding failed to rescue VVDeltaE3L. Analyses of stable cell lines revealed that the carboxy-terminal domain is necessary to prevent the shutoff of protein synthesis and the phosphorylation of eIF2alpha after VVDeltaE3L infection. Thus, pTRS1 contains an unconventional dsRNA-binding domain at its amino terminus, but a second function involving the carboxy terminus is also required for countering host cell antiviral responses.     

dsRNA with 5′ overhangs contributes to endogenous and antiviral RNA silencing pathways in plants

In plants, SGS3 and RNA‐dependent RNA polymerase 6 (RDR6) are required to convert single‐ to double‐stranded RNA (dsRNA) in the innate RNAi‐based antiviral response and to produce both exogenous and endogenous short‐interfering RNAs. Although a role for RDR6‐catalysed RNA‐dependent RNA polymerisation in these processes seems clear, the function of SGS3 is unknown. Here, we show that SGS3 is a dsRNA‐binding protein with unexpected substrate selectivity favouring 5′‐overhang‐containing dsRNA. The conserved XS and coiled‐coil domains are responsible for RNA‐binding activity. Furthermore, we find that the V2 protein from tomato yellow leaf curl virus, which suppresses the RNAi‐based host immune response, is a dsRNA‐binding protein with similar specificity to SGS3. In competition‐binding experiments, V2 outcompetes SGS3 for substrate dsRNA recognition, whereas a V2 point mutant lacking the suppressor function in vivo cannot efficiently overcome SGS3 binding. These findings suggest that SGS3 recognition of dsRNA containing a 5′ overhang is required for subsequent steps in RNA‐mediated gene silencing in plants, and that V2 functions as a viral suppressor by preventing SGS3 from accessing substrate RNAs.     

Collagen-binding matrix proteins from elastomeric extraorganismic byssal fibers

The byssal threads of marine mussels represent a peculiar case of extraorganismic extracellular material. The threads consist of fibrous chimeric collagens such as preCol-P (with collagenous, elastin-like and histidine-rich domains) embedded in a microfibrillar matrix. We report here on the extraction, purification, and characterization of water-soluble proximal thread matrix protein 1 (PTMP1), which is preferentially located in the proximal portion of each byssal thread and decreases in a proximal to distal direction. PTMP1 has a mass of about 50 kDa as determined by matrix-assisted laser desorption-ionization with time-of-flight (MALDI-TOF) mass spectrometry. Glycine is the most common residue at 12.2 mol %, followed by asparagine/aspartic acid and glutamine/glutamic acid at 11.4 and 9.9 mol %, respectively. Glycosylation has been detected by Western blotting with biotinylated concanavalin A and neutral sugar analysis. With degenerate primers designed from the N-terminal sequence and an additional internal peptide derived by Lys-C endopeptidase digestion, a complete cDNA sequence for this protein was obtained by polymerase chain reaction (PCR) amplification of a Mytilus edulis foot cDNA library. Two variants with minor sequence differences limited to the N-terminus were found. The cDNA-deduced protein sequence reveals two symmetric internal repeats that together account for >85% of the protein. Sequence and epitope similarity of PTMP1 to the A domains of von Willebrand factor and integrin alpha(1)I suggest a capacity for collagen binding. Enzyme-linked immunosorbent assay (ELISA)-based measurement of PTMP1 binding to immobilized type I collagen shows high affinity (apparent K(D) = 0.25 microM), but the binding exhibits no dependence on metals. Using primers designed from M. edulis, we also found a PTMP1-like cDNA in a related species, M. galloprovincialis, with a deduced protein sequence having 97% identity with one M. edulis variant and 99% identity with the other. The corresponding cDNA sequences have 94% and 96% identity, respectively.     

DEAD-box RNA helicase domains exhibit a continuum between complete functional independence and high thermodynamic coupling in nucleotide and RNA duplex recognition

DEAD-box helicases catalyze the non-processive unwinding of double-stranded RNA (dsRNA) at the expense of adenosine triphosphate (ATP) hydrolysis. Nucleotide and RNA binding and unwinding are mediated by the RecA domains of the helicase core, but their cooperation in these processes remains poorly understood. We therefore investigated dsRNA and nucleotide binding by the helicase cores and the isolated N- and C-terminal RecA domains (RecA_N, RecA_C) of the DEAD-box proteins Hera and YxiN by steady-state and time-resolved fluorescence methods. Both helicases bind nucleotides predominantly via RecA_N, in agreement with previous studies on Mss116, and with a universal, modular function of RecA_N in nucleotide recognition. In contrast, dsRNA recognition is different: Hera interacts with dsRNA in the absence of nucleotide, involving both RecA domains, whereas for YxiN neither RecA_N nor RecA_C binds dsRNA, and the complete core only interacts with dsRNA after nucleotide has been bound. DEAD-box proteins thus cover a continuum from complete functional independence of their domains, exemplified by Mss116, to various degrees of inter-domain cooperation in dsRNA binding. The different degrees of domain communication and of thermodynamic linkage between dsRNA and nucleotide binding have important implications on the mechanism of dsRNA unwinding, and may help direct RNA helicases to their respective cellular processes.     

dsRNA binding properties of RDE-4 and TRBP reflect their distinct roles in RNAi

Double-stranded RNA (dsRNA)-binding proteins facilitate Dicer functions in RNA interference. Caenorhabditis elegans RDE-4 facilitates cleavage of long dsRNA to small interfering RNA (siRNA), while human trans-activation response RNA-binding protein (TRBP) functions downstream to pass siRNA to the RNA-induced silencing complex. We show that these distinct in vivo roles are reflected in in vitro binding properties. RDE-4 preferentially binds long dsRNA, while TRBP binds siRNA with an affinity that is independent of dsRNA length. These properties are mechanistically based on the fact that RDE-4 binds cooperatively, via contributions from multiple domains, while TRBP binds noncooperatively. Our studies offer a paradigm for how dsRNA-binding proteins, which are not sequence specific, discern dsRNA length. Additionally, analyses of the ability of RDE-4 deletion constructs and RDE-4/TRBP chimeras to reconstitute Dicer activity suggest RDE-4 promotes activity using its dsRNA-binding motif 2 to bind dsRNA, its linker region to interact with Dicer, and its C-terminus for Dicer activation.     

Interaction of a brain extracellular matrix protein with hyaluronic acid.

A glial hyaluronate-binding protein (GHAP) was isolated from bovine spinal cord and partially characterized. Bovine GHAP consisted of three immunologically related polypeptides with molecular masses of 76, 64, and 54 kDa and isoelectric points of 4.1, 4.2, and 4.4, respectively. Peptide mapping and partial amino acid sequencing showed that all three polypeptides derive from the same protein. The protein was localized immunohistochemically with rabbit antisera in the white matter surrounding the myelinated axons. Sugar analyses indicated that the three polypeptides are glycosylated and the sugar residues account for at least 30% of their weight. After enzymatic deglycosylation, the apparent molecular mass of the bovine GHAP was reduced to 43 kDa. The biochemical properties of bovine GHAP were compared to those of human GHAP. Initial peptide mapping indicated similarities between bovine and human GHAP. Partial amino acid sequencing of bovine GHAP showed a striking identity (up to 90%) with human GHAP and with the hyaluronate binding domain of the large human fibroblast proteoglycan, versican. Bovine and human GHAP were demonstrated to bind specifically to hyaluronic acid (HA) with one protein molecule binding to an average 17 disaccharide repeating units. The binding of bovine and human GHAP was inhibited by oligosaccharides of HA and specifically by the octamer. Salt concentrations of up to 1 M NaCl had very little effect on the binding of the GHAP to HA. The GHAP-HA interaction was pH dependent. Dissociation only took place at low pH (less than 3.5). Analysis of several polypeptides derived from GHAP by limited proteolysis allowed us to conclude that one of the tandem repeated sequences is sufficient for HA binding and that the aminoterminal domain (which contains an immunoglobulin-like fold) is not involved in the GHAP-HA-binding event.     

The YvfTU Two-component System is involved in plcR expression in Bacillus cereus

Background

Protein A, protein G and protein L are three well-defined immunoglobulin (Ig)-binding proteins (IBPs), which show affinity for specific sites on Ig of mammalian hosts. Although the precise functions of these molecules are not fully understood, it is thought that they play an important role in pathogenicity of bacteria. The single domains of protein A, protein G and protein L were all demonstrated to have function to bind to Ig. Whether combinations of Ig-binding domains of various IBPs could exhibit useful novel binding is interesting.

Results

We used a combinatorial phage library which displayed randomly-rearranged various-peptide-linked molecules of D and A domains of protein A, designated PA(D) and PA(A) respectively, B2 domain of protein G (PG) and B3 domain of protein L (PL) for affinity selection with human IgG (hIgG), human IgM (hIgM), human IgA (hIgA) and recombinant hIgG1-Fc as bait respectively. Two kinds of novel combinatorial molecules with characteristic structure of PA(A)-PG and PA(A)-PL were obtained in hIgG (hIgG1-Fc) and hIgM (hIgA) post-selection populations respectively. In addition, the linking peptides among all PA(A)-PG and PA(A)-PL structures was strongly selected, and showed interestingly divergent and convergent distribution. The phage binding assays and competitive inhibition experiments demonstrated that PA(A)-PG and PA(A)-PL combinations possess comparable binding advantages with hIgG/hIgG1-Fc and hIgM/hIgA respectively.

Conclusion

In this work, a combinatorial phage library displaying Ig-binding domains of protein A, protein G, or protein L joined by various random linking peptides was used to conducted evolutional selection in vitro with four kinds of Ig molecules. Two kinds of novel combinations of Ig-binding domains, PA(A)-PG and PA(A)-PL, were obtained, and demonstrate the novel Ig binding properties.     

A 127 kDa component of a UV-damaged DNA-binding complex, which is defective in some xeroderma pigmentosum group E patients, is homologous to a slime mold protein.

A cDNA which encodes a approximately 127 kDa UV-damaged DNA-binding (UV-DDB) protein with high affinity for (6-4)pyrimidine dimers [Abramic', M., Levine, A.S. & Protic', M., J. Biol. Chem. 266: 22493-22500, 1991] has been isolated from a monkey cell cDNA library. The presence of this protein in complexes bound to UV-damaged DNA was confirmed by immunoblotting. The human cognate of the UV-DDB gene was localized to chromosome 11. UV-DDB mRNA was expressed in all human tissues examined, including cells from two patients with xeroderma pigmentosum (group E) that are deficient in UV-DDB activity, which suggests that the binding defect in these cells may reside in a dysfunctional UV-DDB protein. Database searches have revealed significant homology of the UV-DDB protein sequence with partial sequences of yet uncharacterized proteins from Dictyostelium discoideum (44% identity over 529 amino acids) and Oryza sativa (54% identity over 74 residues). According to our results, the UV-DDB polypeptide belongs to a highly conserved, structurally novel family of proteins that may be involved in the early steps of the UV response, e.g., DNA damage recognition.     

LUMP is a putative double-stranded RNA binding protein required for male fertility in Drosophila melanogaster

In animals, male fertility requires the successful development of motile sperm. During Drosophila melanogaster spermatogenesis, 64 interconnected spermatids descended from a single germline stem cell are resolved into motile sperm in a process termed individualization. Here we identify a putative double-stranded RNA binding protein LUMP that is required for male fertility. lump(1) mutants are male-sterile and lack motile sperm due to defects in sperm individualization. We show that one dsRNA binding domains (dsRBD) is essential for LUMP function in male fertility. These findings reveal LUMP is a novel factor required for late stages of male germline differentiation.     

Structural and functional conservation of synaptotagmin (p65) in Drosophila and humans.

Synaptotagmin (p65) is an abundant synaptic vesicle protein that contains two copies of a sequence that is homologous to the regulatory region of protein kinase C. Full length cDNAs encoding human and Drosophila synaptotagmins were characterized to study its structural and functional conservation in evolution. The deduced amino acid sequences for human and rat synaptotagmins show 97% identity, whereas Drosophila and rat synaptotagmins are only 57% identical but exhibit a selective conservation of the two internal repeats that are homologous to the regulatory region of protein kinase C (78% invariant residues in all three species). The two internal repeats of synaptotagmin are only slightly more homologous to each other than to protein kinase C, and the differences between the repeats are conserved in evolution, suggesting that they might not be functionally equivalent. The cytoplasmic domains of human and Drosophila synaptotagmins produced as recombinant proteins in Escherichia coli specifically bound phosphatidylserine similar to rat synaptotagmin. They also hemagglutinated trypsinized erythrocytes at nanomolar concentrations. Hemagglutination was inhibited both by negatively charged phospholipids and by a recombinant fragment from rat synaptotagmin that contained only a single copy of the two internal repeats. Together these results demonstrate that synaptotagmin is highly conserved in evolution compatible with a function in the trafficking of synaptic vesicles at the active zone. The similarity of the phospholipid binding properties of the cytoplasmic domains of rat, human, and Drosophila synaptotagmins and the selective conservation of the sequences that are homologous to protein kinase C suggest that these are instrumental in phospholipid binding. The human gene for synaptotagmin was mapped by Southern blot analysis of DNA from somatic cell hybrids to chromosome 12 region cen-q21, and the Drosophila gene by in situ hybridization to 23B.