小鼠KCTD10特异性抗体制备及其在小鼠背神经上皮和背根神经节中的表达

KCTD10蛋白是一个TNF-α诱导表达的蛋白,能与DNA聚合酶δ的小亚基和PCNA相互作用。但其具体功能尚不清楚。为了研究KCTD10的功能,用小鼠KCTD10融合蛋白免疫新西兰大白兔获得兔抗鼠KCTD10多克隆抗体。由于小鼠KCTD10蛋白与小鼠PDIP1蛋白和TNFAIP1蛋白有较高的蛋白序列相似性,KCTD10抗体同PDIP1蛋白、TNFAIP1蛋白有抗体交叉反应。将同源蛋白PDIP1和TNFAIP1的部分降解片段与抗KCTD10血清在4℃下孵育3h从而消除非特异性抗体,成功地消除了KCTD10多克隆抗体对PDIP1蛋白和TNFAIP1蛋白的交叉反应。用此抗体做小鼠胚胎及胚胎切片的免疫组化,发现KCTD10蛋白在E12.5d的小鼠胚胎背根神经节以及神经管神经上皮中有明显的表达。该结果提示KCTD10可能在小鼠的神经管神经上皮和背根神经节发育中发挥作用。     

Analysis of the Sarcocystis neurona microneme protein SnMIC10: protein characteristics and expression during intracellular development

Sarcocystis neurona, an apicomplexan parasite, is the primary causative agent of equine protozoal myeloencephalitis. Like other members of the Apicomplexa, S. neurona zoites possess secretory organelles that contain proteins necessary for host cell invasion and intracellular survival. From a collection of S. neurona expressed sequence tags, we identified a sequence encoding a putative microneme protein based on similarity to Toxoplasma gondii MIC10 (TgMIC10). Pairwise sequence alignments of SnMIC10 to TgMIC10 and NcMIC10 from Neospora caninum revealed approximately 33% identity to both orthologues. The open reading frame of the S. neurona gene encodes a 255 amino acid protein with a predicted 39-residue signal peptide. Like TgMIC10 and NcMIC10, SnMIC10 is predicted to be hydrophilic, highly alpha-helical in structure, and devoid of identifiable adhesive domains. Antibodies raised against recombinant SnMIC10 recognised a protein band with an apparent molecular weight of 24 kDa in Western blots of S. neurona merozoites, consistent with the size predicted for SnMIC10. In vitro secretion assays demonstrated that this protein is secreted by extracellular merozoites in a temperature-dependent manner. Indirect immunofluorescence analysis of SnMIC10 showed a polar labelling pattern, which is consistent with the apical position of the micronemes, and immunoelectron microscopy provided definitive localisation of the protein to these secretory organelles. Further analysis of SnMIC10 in intracellular parasites revealed that expression of this protein is temporally regulated during endopolygeny, supporting the view that micronemes are only needed during host cell invasion. Collectively, the data indicate that SnMIC10 is a microneme protein that is part of the excreted/secreted antigen fraction of S. neurona. Identification and characterisation of additional S. neurona microneme antigens and comparisons to orthologues in other Apicomplexa could provide further insight into the functions that these proteins serve during invasion of host cells.     

草鱼IL-10单克隆抗体的制备与鉴定

白细胞介素10(Interleukin-10, IL-10)参与机体免疫应答调节, 协同其他细胞因子维持免疫系统稳态。为探究草鱼(Ctenopharyngodon idella)IL-10的细胞来源, 研究利用大肠杆菌(Escherichia coli, E. coli)表达系统制备了高纯度的草鱼IL-10重组蛋白, 免疫小鼠制备单克隆抗体后通过免疫印迹、激光共聚焦和流式细胞术对抗体进行分析。结果表明, 获得的单克隆抗体不仅能特异识别大肠杆菌表达的CiIL-10重组蛋白, 而且能识别HEK293细胞中表达的真核IL-10重组蛋白。脂多糖(Lipopolysaccharide, LPS)和草鱼白细胞介素1β(IL-1β)刺激草鱼性腺细胞系(GCO)36h的免疫荧光染色分析表明, 草鱼IL-10单克隆抗体能与草鱼内源IL-10结合, 但IL-10阳性细胞数量在LPS处理前后无明显变化。该研究成功制备了高纯度CiIL-10重组蛋白, 获得了特异性好的高质量单克隆抗体, 为研究草鱼ILC2和Th2细胞的增殖、分化和功能奠定了基础。     

hZwint-1 bridges the inner and outer kinetochore: identification of the kinetochore localization domain and the hZw10-interaction domain

Accurate chromosome segregation in mitosis is required to maintain genetic stability. hZwint-1 [human Zw10 (Zeste white 10)-interacting protein 1] is a kinetochore protein known to interact with the kinetochore checkpoint protein hZw10. hZw10, along with its partners Rod (Roughdeal) and hZwilch, form a complex which recruits dynein-dynactin and Mad1-Mad2 complexes to the kinetochore and are essential components of the mitotic checkpoint. hZwint-1 localizes to the kinetochore in prophase, before hZw10 localization, and remains at the kinetochore until anaphase, after hZw10 has dissociated. This difference in localization timing may reflect a role for hZwint-1 as a structural kinetochore protein. In addition to hZw10, we have found that hZwint-1 interacts with components of the conserved Ndc80 and Mis12 complexes in yeast two-hybrid and GST (glutathione transferase) pull-down assays. Furthermore, hZwint-1 was found to have stable FRAP (fluorescence recovery after photobleaching) dynamics similar to hHec1, hSpc24 and hMis12. As such, we proposed that hZwint-1 is a structural protein, part of the inner kinetochore scaffold and recruits hZw10 to the kinetochore. To test this, we performed mutagenesis-based domain mapping to determine which regions of hZwint-1 are necessary for kinetochore localization and which are required for interaction with hZw10. hZwint-1 localizes to the kinetochore through the N-terminal region and interacts with hZw10 through the C-terminal coiled-coil domain. The two domains are at opposite ends of the protein as expected for a protein that bridges the inner and outer kinetochore.     

Cell cycle-dependent proteolysis and phosphorylation of human Mcm10

Mcm10 (Dna43) is an essential protein for chromosomal DNA replication in Saccharomyces cerevisiae. Recently, we identified a human Mcm10 homolog that interacts with the mammalian Orc2 and Mcm2-7 complex. We additionally demonstrated that human Mcm10 binds nuclease-resistant nuclear structures during S phase and dissociates from them in G(2) phase. In this study, we have further characterized the subcellular localization, modification, and expression levels of human Mcm10 protein throughout the cell cycle. Human Mcm10 protein decreased in late M phase, remained low during G(1) phase, started to accumulate, and bound chromatin at the onset of S phase. Proteasome inhibitors stabilized Mcm10 levels, suggesting that proteolysis is involved in the down-regulation of the protein in late M/G(1) phase. Dissociation of Mcm10 from chromatin in G(2)/M phase was concomitant with alterations in the electrophoretic mobility of the protein. Treatment with lambda phosphatase revealed that mobility shifts were due to hyperphosphorylation. These results indicate that human Mcm10 is regulated by proteolysis and phosphorylation in a cell cycle-dependent manner. It is further suggested that mammalian Mcm10 is involved in S phase progression, and not the formation of a prereplicative complex, as previously proposed from data on the S. cerevisiae protein.     

AtZW10蛋白亚细胞定位的初步研究

利用不同的工具对AtZW10基因编码的蛋白进行生物信息学分析,结果表明,拟南芥AtZW10在进化上比较保守,在该蛋白的内部存在一个和着丝粒/动粒结合蛋白ZW10相似的保守区域,与果蝇DmZW10蛋白之间存在较高的相似性;AtZW10是一类亲水蛋白,没有明显的跨膜结构域,很可能定位于细胞核和细胞质中。为了进一步确定AtZW10的亚细胞定位,以野生型拟南芥cDNA为模板,通过PCR技术克隆AtZW10基因,构建与黄色荧光蛋白基因（YFP）融合的pA7-AtZW10-YFP表达载体,以及与绿色荧光蛋白基因（GFP）融合的p2300-AtZW10-GFP表达载体。将AtZW10-YFP和AtZW10-GFP分别转化野生型拟南芥叶肉细胞的原生质体和本生烟草的表皮细胞。通过对融合蛋白的分布位置进行分析表明,AtZW10很可能是一种核质定位蛋白,但主要分布在细胞核中。这一结果和生物信息学分析的结论是一致的。本文通过对AtZW10分子特性和亚细胞定位分析,可以为今后研究其功能提供基础。     

The interaction between E-tropomodulin and thymosin beta-10 rescues tumor cells from thymosin beta-10 mediated apoptosis by restoring actin architecture

Thymosin beta-10 (TB10) is a small G-actin binding protein that induces depolymerization of intracellular F-actin pools by sequestering actin monomers. Previously, we demonstrated that overexpression of TB10 in ovarian tumor cells increased the rate of cell death. As an initial step to define molecular mechanism of TB10-dependent apoptotic process in ovarian tumor cells, we searched a human ovary cDNA library for a novel TB10 binding protein using a yeast two-hybrid system. The selected protein was human E-tropomodulin (E-Tmod), another component of the actin binding proteins. Subsequently, two interacting protein components were determined quantitatively. Results showed that the full-length TB10 is required to bind with E-Tmod, and the TB10 binding site on E-Tmod partially overlaps with the actin binding site on E-Tmod. Moreover, introduction of E-Tmod cDNA into a tumor cell line reversed TB10 mediated apoptosis and restored actin architectures. These results may suggest that TB10 regulates apoptotic homeostasis by not only just binding to actin but also competing or blocking the protein complex formation of E-Tmod with actin.     

A novel complex from bovine visual cells of a 33,000-dalton phosphoprotein with beta- and gamma-transducin: purification and subunit structure

Photoreceptors of mammalian retinas contain a 33-kDa (33K) protein that is phosphorylated, in vitro, by cyclic nucleotide dependent protein kinases. The 33K protein is phosphorylated in the dark, in situ, and dephosphorylated upon illumination. The soluble 33K protein from bovine retinas has been purified to near homogeneity by extraction at pH 5.7 and chromatography on ion-exchange, gel filtration, and hydroxylapatite columns. In the native conformation, the 33K protein is associated with a 37-kDa (37K) and a 10-kDa (10K) protein, forming a trimeric complex with a sedimentation coefficient of 4.9 S and an apparent molecular mass of 77 kDa. The 33K protein can be dissociated from the 37K/10K complex by centrifugation in the presence of high pH and high salt; the subunits reassociate to form the trimeric complex upon recentrifugation in an isotonic buffer with neutral pH. The 33K protein is phosphorylated rapidly by exogenous kinase, in vitro, whereas the 37K and 10K subunits remain unphosphorylated. The 37K and 10K subunits cross-react with antibodies prepared against the beta- and gamma-subunits, respectively, of bovine transducin, indicating that the 37K and 10K subunits are immunologically identical with beta- and gamma-transducin, respectively. No immuno-cross-reactivity was observed between the 33K protein and an antibody against the alpha-subunit of bovine transducin. The 33K-beta-/gamma-transducin complex exhibits striking similarity to transducin in its subunit structure and mode of subunit interaction, suggesting it may play an important role in the metabolism and function of rod photoreceptor cells.     

Mpp10p, a U3 small nucleolar ribonucleoprotein component required for pre-18S rRNA processing in yeast.

We have isolated and characterized Mpp10p, a novel protein component of the U3 small nucleolar ribonucleoprotein (snoRNP) from the yeast Saccharomyces cerevisiae. The MPP10 protein was first identified in human cells by its reactivity with an antibody that recognizes specific sites of mitotic phosphorylation. To study the functional role of MPP10 in pre-rRNA processing, we identified the yeast protein by performing a GenBank search. The yeast Mpp10p homolog is 30% identical to the human protein over its length. Antibodies to the purified yeast protein recognize a 110-kDa polypeptide in yeast extracts and immunoprecipitate the U3 snoRNA, indicating that Mpp10p is a specific protein component of the U3 snoRNP in yeast. As a first step in the genetic analysis of Mpp10p function, diploid S. cerevisiae cells were transformed with a null allele. Sporulation and tetrad analysis indicate that MPP10 is an essential gene. A strain was constructed where Mpp10p is expressed from a galactose-inducible, glucose- repressible promoter. After depletion of Mpp10p by growth in glucose, cell growth is arrested and levels of 18S and its 20S precursor are reduced or absent while the 23S and 35S precursors accumulate. This pattern of accumulation of rRNA precursors suggests that Mpp10p is required for cleavage at sites A0, A1, and A2. Pulse-chase analysis of newly synthesized pre-rRNAs in Mpp10p-depleted yeast confirms that little mature 18S rRNA formed. These results reveal a novel protein essential for ribosome biogenesis and further elucidate the composition of the U3 snoRNP.     

Studies on the binding of the ribosomal protein complex L7/12-L10 and protein L11 to the 5''-one third of 23S RNA: a functional centre of the 50S subunit.

The RNA binding sites of the protein complex of L7/12 dimers and L10, and of protein L11, occur within the 5'-one third of 23S RNA. Binding of the L7/12-L10 protein complex to the 23S RNA is stimulated by protein L11 and vice-versa. This is the second example to be established of mutual stimulation of RNA binding by two ribosomal proteins or protein complexes, and suggests that this may be an important principle governing ribosomal protein-RNA assembly. When the L7/12-L10 complex is bound to the RNA, L10 becomes strongly resistant to trypsin. Since the L7/12 dimer does not bind specifically to the 23S RNA, this suggests that L10 constitutes a major RNA binding site of the protein complex. Only one of the L7/12 dimers is bound strongly in the (L7/12-L10)-23S RNA complex; the other can dissociate with no concurrent loss of L10.     

The human homolog of Saccharomyces cerevisiae Mcm10 interacts with replication factors and dissociates from nuclease-resistant nuclear structures in G(2) phase

Mcm10 (Dna43), first identified in Saccharomyces cerevisiae, is an essential protein which functions in the initiation of DNA synthesis. Mcm10 is a nuclear protein that is localized to replication origins and mediates the interaction of the Mcm2–7 complex with replication origins. We identified and cloned a human cDNA whose product was structurally homologous to the yeast Mcm10 protein. Human Mcm10 (HsMcm10) is a 98-kDa protein of 874 amino acids which shows 23 and 21% overall similarity to Schizosaccharomyces pombe Cdc23 and S.cerevisiae Mcm10, respectively. The messenger RNA level of HsMcm10 increased at the G₁/S-boundary when quiescent human NB1–RGB cells were induced to proliferate as is the case of many replication factors. HsMcm10 associated with nuclease-resistant nuclear structures throughout S phase and dissociated from it in G₂ phase. HsMcm10 associated with human Orc2 protein when overexpressed in COS-1 cells. HsMcm10 also interacted with Orc2, Mcm2 and Mcm6 proteins in the yeast two-hybrid system. These results suggest that HsMcm10 may function in DNA replication through the interaction with Orc and Mcm2–7 complexes.     

The UL10 gene of herpes simplex virus 1 encodes a novel viral glycoprotein, gM, which is present in the virion and in the plasma membrane of infected cells.

The herpes simplex virus 1 UL10 gene encodes a hydrophobic membrane protein dispensable for viral replication in cell culture (J.D. Baines and B. Roizman, J. Virol. 65:938-944, 1991). We report the following. (i) A fusion protein consisting of glutathione S-transferase fused to the C-terminal 93 amino acids of the UL10 protein was used to produce a rabbit polyclonal antiserum. The antiserum reacted with infected-cell proteins which formed in denaturing polyacrylamide gels a sharp band (apparent M(r) of 50,000) and a very broad band (M(r) of 53,000 to 63,000). These bands were not formed by lysates of UL10- virus or by lysates of infected cells boiled in the presence of sodium dodecyl sulfate before electrophoresis. (ii) The proteins forming both bands were labeled by [3H]glucosamine, indicating that they were glycosylated. (iii) The UL10 protein in cells treated with tunicamycin formed a single band (apparent M(r) of 47,000) reactive with the anti-UL10 antibody, indicating that the 47,000-M(r) protein was a precursor of N-glycosylated, more slowly migrating forms of UL10. Treatment of the immunoprecipitate with endoglycosidase H increased the electrophoretic mobility of the 50,000-M(r) species to that of the 47,000-M(r) species, indicating that the 50,000-M(r) species contained high-mannose polysaccharide chains, whereas the proteins forming the 53,000- to 63,000-M(r) bands contained mature chains inasmuch as they were resistant to digestion by the enzyme. (iv) The UL10 protein of R7221 carrying a 20-amino-acid epitope formed only one band with an M(r) of 53,000. This band was sensitive to endoglycosidase H, suggesting that the epitope inserted in the R7221 UL10 protein may have interfered with glycosylation. (v) The UL10 protein does not contain a cleavable signal sequence inasmuch as the first UL10 methionine codon was reflected in the 50,000-M(r) protein. (vi) The UL10 protein is present in virions and plasma membranes of unfixed cells that were reacted with the polyclonal rabbit antibody. In accordance with the current nomenclature, the UL10 protein is designated glycoprotein M.     

Increased phenylalanine incorporation in regenerating skeletal muscle grafts

Skeletal muscle regenerates following grafting, but little is known about protein synthesis and its regulation during regeneration. We determined the sequence of changes in protein synthesis in rat extensor digitorum longus (EDL) muscle by the measurement of phenylalanine (Phe) incorporation into muscle protein at various times after grafting. Compared with control EDL, Phe incorporation in grafts doubled in 1 day, was four- to eight-fold greater from days 2 to 10 after grafting, and then subsided. Tissue mass (wet weight) increased rapidly from days 7 to 20 in EDL grafts. The maximal increase in protein synthesis occurred 7-10 days after grafting, whether or not the nerve was left intact. Autoradiography indicated that incorporated radioactivity was associated with regenerating muscle fibers on day 10. Deficiencies of insulin, pituitary or testicular hormones, or chronic in vivo administration of insulin, growth hormone, testosterone, or tri-iodothyronine did not substantially alter the elevation in incorporation of the Phe into muscle protein 10 days after grafting. The breakdown of EDL protein, measured in vitro simultaneously with protein synthesis, was increased five-fold, and overall protein degradation was elevated six-fold 10 days after grafting. These findings indicate that Phe incorporation is rapidly elevated following grafting of the EDL, and that by days 7-10 reflects synthesis in regenerating muscle fibers. The increase in protein synthesis associated with muscle regeneration at this time appears to be independent of innervation and anabolic hormones.     

ATP10, a yeast nuclear gene required for the assembly of the mitochondrial F1-F0 complex

A yeast nuclear gene (ATP10) is reported whose product is essential for the assembly of a functional mitochondrial ATPase complex. Mutations in ATP10 induce a loss of rutamycin sensitivity in the mitochondrial ATPase but do not affect respiratory enzymes. This phenotype has been correlated with a defect in the F0 sector of the ATPase. The wild type ATP10 gene has been cloned by transformation of an atp 10 mutant with a yeast genomic library. The gene codes for a protein of Mr = 30,293. The primary structure of the ATP10 product is not related to any known subunit of the yeast or mammalian mitochondrial ATPase complexes. To further clarify the role of this new protein in the assembly of the ATPase, an antibody was prepared against a hybrid protein expressed from a trpE/ATP 10 fusion gene. The antibody recognizes a 30-kDa protein present in wild type mitochondria. The protein is associated with the mitochondrial membrane but does not co-fractionate either with F1 or with the rutamycin-sensitive F1-F0 complex. These data suggest that the ATP10 product is not a subunit of the ATPase complex but rather is required for the assembly of the F0 sector of the complex.     

Mouse Apg10 as an Apg12-conjugating enzyme: analysis by the conjugation-mediated yeast two-hybrid method

Autophagosome formation is a central event in macroautophagy. The Apg12-Apg5 conjugate, which is essential in this process, is generated by a ubiquitin-like protein conjugation system. In yeast, Apg12, following activation by the E1-like Apg7, forms a thioester with Apg10 (E2-like). Apg12 is finally conjugated to Apg5 via an isopeptide bond. The possible requirement of an E3-like protein for the conjugation, however, has not yet been confirmed. The Apg12 system is conserved among eukaryotes, although a mammalian counterpart of Apg10 has not yet been identified. Here, we report the identification and characterization of the mouse Apg10 ortholog. A yeast two-hybrid screen using the mouse Apg5 (mApg5) as bait identified a novel protein with 19% identity to yeast Apg10. We designated this protein mouse Apg10 (mApg10). We demonstrated by a modified yeast two-hybrid assay that mApg10 mediates the conjugation of mApg12 and mApg5. The in vivo interaction of mApg12 with mApg10 in HeLa cells suggests that mApg10 is an Apg12-conjugating enzyme, likely serving as an Apg5-recognition molecule in the Apg12 system. This novel two-hybrid method, which we have named 'conjugation-mediated yeast two-hybrid', proves to be a simple and useful technique with which to analyze protein-protein conjugation.     

The Replacement of 10 Non-Conserved Residues in the Core Protein of JFH-1 Hepatitis C Virus Improves Its Assembly and Secretion

Hepatitis C virus (HCV) assembly is still poorly understood. It is thought that trafficking of the HCV core protein to the lipid droplet (LD) surface is essential for its multimerization and association with newly synthesized HCV RNA to form the viral nucleocapsid. We carried out a mapping analysis of several complete HCV genomes of all genotypes, and found that the genotype 2 JFH-1 core protein contained 10 residues different from those of other genotypes. The replacement of these 10 residues of the JFH-1 strain sequence with the most conserved residues deduced from sequence alignments greatly increased virus production. Confocal microscopy of the modified JFH-1 strain in cell culture showed that the mutated JFH-1 core protein, C10M, was present mostly at the endoplasmic reticulum (ER) membrane, but not at the surface of the LDs, even though its trafficking to these organelles was possible. The non-structural 5A protein of HCV was also redirected to ER membranes and colocalized with the C10M core protein. Using a Semliki forest virus vector to overproduce core protein, we demonstrated that the C10M core protein was able to form HCV-like particles, unlike the native JFH-1 core protein. Thus, the substitution of a few selected residues in the JFH-1 core protein modified the subcellular distribution and assembly properties of the protein. These findings suggest that the early steps of HCV assembly occur at the ER membrane rather than at the LD surface. The C10M-JFH-1 strain will be a valuable tool for further studies of HCV morphogenesis.