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。     

Identification of a novel protein,PDIP38, that interacts with the p50 subunit of DNA polymerase delta and proliferating cell nuclear antigen

The yeast two-hybrid screening method was used to identify novel proteins that associate with human DNA polymerase delta (pol delta). Two baits were used in this study. These were the large (p125) and small (p50) subunits of the core pol delta heterodimer. p50 was the only positive isolated with p125 as the bait. Two novel protein partners, named PDIP38 and PDIP46, were identified from the p50 screen. In this study, the interaction of PDIP38 with pol delta was further characterized. PDIP38 encodes a protein of 368 amino acids whose C terminus is conserved with the bacterial APAG protein and with the F box A protein. It was found that PDIP38 also interacts with proliferating cell nuclear antigen (PCNA). The ability of PDIP38 to interact with both the p50 subunit of pol delta and with PCNA was confirmed by pull-down assays using glutathione S-transferase (GST)-PDIP38 fusion proteins. The PCNA-PDIP38 interaction was also demonstrated by PCNA overlay experiments. The association of PDIP38 with pol delta was shown to occur in calf thymus tissue and mammalian cell extracts by GST-PDIP38 pull-down and coimmunoprecipitation experiments. PDIP38 was associated with pol delta isolated by immunoaffinity chromatography. The association of PDIP38 with pol delta could also be demonstrated by native gel electrophoresis.     

Genomic structure and fine mapping of the two human filamin gene paralogues FLNB and FLNC and comparative analysis of the filamin gene family

The genomic structure of the filamin gene paralogues FLNB and FLNC was determined and related to FLNA. FLNB consists of 45 exons and 44 introns and spans approximately 80 kb of genomic DNA. FLNC is divided into 48 exons and 47 introns and covers approximately 29.5 kb of genomic DNA. A previously unknown intron was found in FLNA. The comparison of all three filamin gene paralogues revealed a highly conserved exon-intron structure with significant differences in the exons 32 of all paralogues encoding the hinge I region, as well as the insertion of a novel exon 40A in FLNC only. Gene organization does not correlate with the domain structures of the respective proteins. To improve candidate gene cloning approaches, FLNB was precisely mapped at 3p14 in an interval of 0.81 cM between WI3771 and WI6691 and FLNC at 7q32 in an interval of 2.07 cM between D7S530 and D7S649.     

Identification and characterization of a novel gene disrupted by a pericentric inversion inv(4)(p13.1q21.1) in a family with cleft lip

Cleft lip with or without cleft palate is a common birth defect affecting 1 in every 700 live births. Several genetic loci are believed to be involved in the pathogenesis of syndromic and non-syndromic clefting. We identified a pericentric inversion of chromosome 4, inv(4)(p13q21) that segregates with cleft lip in a two-generation family. By using a combination of fluorescence in situ hybridization, yeast artificial chromosome, bacterial artificial chromosome contig mapping, and database searching we mapped and sequenced the inversion breakpoint region. The pericentric inversion disrupts a gene (ACOD4) on chromosome 4q21 that codes for a novel acyl-CoA desaturase enzyme. The 3.0 kb human ACOD4 cDNA spans approximately 170 kb and is composed of five exons of ACOD4. The inversion breakpoint is located in the second exon. The 3.0 kb mRNA is expressed at high level in fetal brain; a lower expression level was found in fetal kidney. No expression of ACOD4 was detected in fetal lung or liver or in adult tissues. The five exons code for a protein of 330 amino acids, with a predicted molecular weight of 37.5 kDa. The protein is highly similar to acyl-CoA desaturases from Drosophila melanogaster to Homo sapiens. The catalytically essential histidine clusters and the potential transmembrane domains are well conserved.     

A novel PDIP1-related protein, KCTD10, that interacts with proliferating cell nuclear antigen and DNA polymerase delta

Rat potassium channel tetramerisation domain-containing 10 (KCTD10) gene was cloned and identified as a novel member of polymerase delta-interacting protein 1 (PDIP1) gene family. Rat KCTD10 is highly expressed in lung and moderately expressed in heart and testis. KCTD10 shares significant similarity in amino acid sequence to PDIP1 and can interact with the small subunit of DNA polymerase delta and PCNA as PDIP1 does. Like PDIP1, the expression of KCTD10 gene can be induced by TNF-alpha in NIH3T3 cells.     

The human hedgehog-interacting protein gene: structure and chromosome mapping to 4q31.21-->q31.3.

Hedgehog-interacting protein (Hhip) is a novel regulatory component in the vertebrate hedgehog-signalling pathway. The murine Hhip encodes a type I TM protein that attenuates hedgehog signalling by binding all three mammalian hedgehog proteins. Here we describe the cloning and characterisation of the homologous human hedgehog-interacting protein gene (HHIP). HHIP comprises 13 exons and spans >91kb encoding a protein of 700 aa which shares 94% sequence iden- tity with mouse Hhip. HHIP maps to chromosome 4q31.21--> q31.3. Additionally, we have mapped murine Hhip to chromosome 8.     

PDIP38 is a novel mitotic spindle-associated protein that affects spindle organization and chromosome segregation

In order to maintain genomic integrity during mitosis, cells assemble the mitotic spindle to separate sister chromosomes to the two daughter cells. A variety of motor- and non motor-proteins are involved in the organization and regulation of this complex apparatus. DNA polymerase δ-interacting protein 38 (PDIP38) is a highly conserved protein and has so far been shown to be a cytoplasmic and nuclear protein. Cell cycle dependent nuclear localization and the interaction with DNA polymerase δ and proliferating cell nuclear antigen (PCNA) indicate a role for PDIP38 in DNA modification and/or proliferation. Here, we show for the first time that PDIP38 localizes to the mitotic spindle throughout mitosis. Using anti-PDIP38 antibody injections and siRNA silencing, we demonstrate that PDIP38 loss-of-function causes problems with spindle organization, aberrant chromosome segregation, and multinucleated cells. Taken together, the data indicate different roles for PDIP38 in safeguarding a proper cell division at various stages of the cell cycle, including DNA synthesis and repair, organization of the mitotic spindle and chromosome segregation.     

The t(4;11) chromosome translocation of human acute leukemias fuses the ALL-1 gene, related to Drosophila trithorax, to the AF-4 gene.

The ALL-1 gene located at human chromosome 11 band q23 is rearranged in acute leukemias with interstitial deletions or reciprocal translocations between this region and chromosomes 1, 4, 6, 9, 10, or 19. The gene spans approximately 100 kb of DNA and contains at least 21 exons. It encodes a protein of more than 3910 amino acids containing three regions with homology to sequences within the Drosophila trithorax gene, including cysteine-rich regions that can be folded into six zinc finger-like domains. The breakpoint cluster region within ALL-1 spans 8 kb and encompasses several small exons, most of which begin in the same phase of the open reading frame. The t(4;11) chromosome translocation results in two reciprocal fusion products coding for chimeric proteins derived from ALL-1 and from a gene on chromosome 4. This suggests that each 11q23 abnormality gives rise to a specific oncogenic fusion protein.     

Cloning, genomic structure, and expression profiles of TULIP1 (GARNL1), a brain-expressed candidate gene for 14q13-linked neurological phenotypes, and its murine homologue

Previously, we have described the clinical and molecular characterization of a de novo 14q13.1-q21.1 microdeletion, less than 3.5 Mb in size, in a patient with severe microcephaly, psychomotor retardation, and other clinical anomalies. Here we report the characterization of the genomic structure of the human tuberin-like protein gene 1 (TULIP1; approved gene symbol GARNL1), a CpGisland-associated, brain-expressed candidate gene for the neurological findings in our patient, and its murine homologue. The human TULIP1 gene was mapped to chromosome band 14q13.2 by fluorescence in situ hybridization of BAC clone RP11-355C3 (GenBank Accession No. AL160231), containing the 3' region of the gene. TULIP1 spans about 271 kb of human genomic DNA and is divided into 41 exons. An untranscribed, processed pseudogene of TULIP1 was found on human chromosome band 9q31.1. The active locus TULIP1, encoding a predicted protein of 2036 amino acids, is expressed ubiquitously in pre- and postnatal human tissues. The murine homologue Tulip1 spans about 220 kb of mouse genomic DNA and is also divided into 41 exons, encoding a predicted protein of 2035 amino acids. No pseudogene could be found in the available mouse sequence data. Several splicing variants were found. Considering the location, expression profile, and predicted function, TULIP1 is a strong candidate for several neurological features seen in 14q deletion patients. Additionally we searched for mutations in the coding region of TULIP1 in subjects from a family with idiopathic basal ganglia calcification (IBGC; Fahr disease), previously linked to chromosome 14q. We identified two novel SNPs in the intron-exon boundaries; however, they did not segregate only with affected subjects in the predicted model of an autosomal dominant disease such as IBGC.