Molecular Cloning and Characterization of a Novel Human Classic Cadherin Homologous with Mouse Muscle Cadherin

Shimoyama, Yutaka; Shibata, Tatsuhiro; Kitajima, Masaki; Hirohashi, Setsuo

doi:10.1074/jbc.273.16.10011

Cited by 14 publications

(31 citation statements)

References 59 publications

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“…A cadherin-6 cDNA fragment corresponding to EC5, a region with low homology to the other classic cadherins (12)(13)(14), and containing KpnI and HindIII sites at the 5Ј-and 3Ј-ends, respectively, was amplified by polymerase chain reaction, digested with KpnI and HindIII, and ligated to a prokaryotic expression vector, pR-SET B (Invitrogen Corp.) that had been cleaved with the same enzymes. The resultant plasmid was introduced into an Escherichia coli strain, BL21(DE3)pLysS (Novagen), and expression of the fusion protein was induced by 1 mM isopropyl-␤-D-thiogalactoside.…”

Section: Methodsmentioning

confidence: 99%

“…Other Biochemical Procedures-Immunoprecipitation, N-terminal amino acid sequencing, and determination of the trypsin sensitivity was performed as described previously (14). Exposure of cadherin molecules on the surface of the transfected L cells was also examined as described previously (14).…”

Section: Methodsmentioning

confidence: 99%

“…Exposure of cadherin molecules on the surface of the transfected L cells was also examined as described previously (14).…”

Section: Methodsmentioning

confidence: 99%

“…The human classic cadherins E-, N-, and P-cadherin and cadherin-4 have been classified as type I, and cadherin-6, -8, -11, -12, and -14 are classified as type II. Although cadherin-5 and -15 (Mcadherin) have been proposed to be type II and I, respectively (2), we think that they do not clearly belong to either subgroup (14).…”

mentioning

confidence: 86%

“…We recently reported that the susceptibility of cadherin-15 to trypsin digestion in the presence of Ca ϩ causes a low aggregation rate in the short term assay (14). We therefore examined the trypsin sensitivities of cadherin-6 and -14 (Fig.…”

Section: Expression Of Cadherin-6 and -14 By L Cells-l Cells Whichmentioning

confidence: 99%

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Biochemical Characterization and Functional Analysis of Two Type II Classic Cadherins, Cadherin-6 and -14, and Comparison with E-cadherin

Shimoyama¹,

Takeda²,

Yoshihara³

et al. 1999

Journal of Biological Chemistry

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Classic cadherins can be grouped based on their deduced primary structures. Among them the type I cadherins have been well characterized; however, little is known about non-type I cadherins. In this study we characterized two human type II cadherins, cadherin-6 and cadherin-14, using a cDNA transfection system. They were each detected as two bands electrophoretically, were expressed on the external cell surface at cell-cell contact sites, and were associated with catenins. Direct sequencing of the N-terminal amino acids showed that the two bands of cadherin-14 corresponded to precursor and mature forms, whereas the two bands of cadherin-6 both had the N-terminal sequence of the mature form. Unlike type I cadherins, both cadherin-6 and -14 were not protected from trypsin degradation by Ca 2؉ . We evaluated their adhesive functions by a long term cell aggregation method. The results suggest that both cadherin-6 and -14 have cell-cell binding strengths virtually equivalent to that of E-cadherin and that their binding specificities are distinct from that of E-cadherin. Cadherin-6 and -14 interacted with each other in an incomplete manner. They have a QAI tripeptide in the first extracellular subdomain instead of the HAV motif that is characteristic of type I cadherins and is intimately involved in the adhesive function. The QAI tripeptide, however, appeared not to be involved in the adhesive functions of cadherin-6 and -14.Cadherin was originally identified as a cell-cell adhesion molecule that functions in a Ca 2ϩ -dependent and homophilic manner and that is involved in various morphogenetic events during development (1). The first cadherins to be identified are known as the classic cadherins. In the last decade, numerous molecules that share the extracellular subdomain (EC) 1 structure (cadherin repeat) of the classic cadherins have been discovered in both vertebrates and invertebrates, and they are now considered to constitute a large gene family, the cadherin superfamily. Besides the classic cadherins this family includes truncated type cadherins, desmosomal cadherins, protocadherins and protocadherin-related proteins, and HPT/LI-cadherins (2). The biological functions of most of these non-classic cadherins remain elusive.Classic cadherins share a common primary structure that consists of a signal peptide and a prosequence, which are both removed by intracellular proteolytic processing, five cadherin repeats, a transmembrane domain, and a highly conserved cytoplasmic domain, which is essential for association with catenins, the ensuing linkage to the cytoskeleton, and full functioning as a Ca 2ϩ -dependent cell-cell adhesion molecule (3-5). Full cDNA cloning of 11 human classic cadherin molecules has been accomplished so far as follows: E-, N-, and P-cadherin, cadherin-4 (R-cadherin), -5, -6, -8, -11 (OB-cadherin), -12, -14, and -15 (M-cadherin) (6 -14). Suzuki (2) proposed that the classic cadherins were divided into two subgroups, type I and type II, on the basis of their overall sequence similarities and the ...

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Section: Methodsmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

“…Exposure of cadherin molecules on the surface of the transfected L cells was also examined as described previously (14).…”

Section: Methodsmentioning

confidence: 99%

mentioning

confidence: 86%

Section: Expression Of Cadherin-6 and -14 By L Cells-l Cells Whichmentioning

confidence: 99%

See 3 more Smart Citations

Biochemical Characterization and Functional Analysis of Two Type II Classic Cadherins, Cadherin-6 and -14, and Comparison with E-cadherin

Shimoyama¹,

Takeda²,

Yoshihara³

et al. 1999

Journal of Biological Chemistry

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Expression of cadherin‐8 in renal cell carcinoma and fetal kidney

Blaschke

Mueller

Marković-Lipkovski

et al. 2002

Intl Journal of Cancer

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Renal cell carcinomas (RCCs) represent 3% of all adult malignancies and are often associated with poor prognosis due to early metastasis and limited beneficial effects of current therapeutic modalities. 1 Most of these tumors originate from the proximal tubule. According to cell morphology and growth pattern, 3 main histologic tumor types can be distinguished, including clear cell carcinoma, papillary renal carcinoma and chromophobe RCC. 2 Several factors that may contribute to the process of malignant cell transformation in RCC have previously been characterized, including physical agents, chemical agents, habits, genetics (chromosomal rearrangement) and end-stage renal disease. 3 However, the pathogenic mechanisms that promote tumor progression, i.e., tumor invasion and metastasis, still have to be defined. There is accumulating evidence that cadherins may be involved in the pathogenesis of various human carcinomas by modulating celladhesive properties.The cadherin superfamily represents a group of cell-surface glycoproteins involved in cell recognition, cell signaling, cell communication, morphogenesis as well as angiogenesis and includes the groups of classic cadherins, desmosomal cadherins, protocadherins, 7TM-cadherins and T-cadherin. 4 The human classic cadherins are a group of cell-surface molecules mediating Ca 2ϩ -dependent cell adhesion by homo-or heterophilic interaction. These proteins, m.w. approximately 120 -130 kDa, are composed of an extracellular domain with 5 subdomains, each of which contains a cadherin-specific motif at the N-terminal site, a single transmembrane domain and a rather short and highly conserved cytoplasmic domain at the C-terminal site. The adhesive action of cadherins depends on the presence of Ca 2ϩ and on the function of the intracellular domain. 5 Cadherins are linked to the actin filament network through cytoplasmic interactions with catenins. These catenins regulate cadherin-mediated cell-cell adhesion. 6 In addition, these molecules may function as a downstream transcriptional activator. 7,8 More than 12 different molecules of the classic human cadherins have been identified so far by cDNA cloning. With respect to sequence homology and conservation of several amino acid residue motifs in the extracellular domain, Suzuki et al. 9 first proposed subdividing the classic human cadherins into 2 subgroups: type I (E-, N-and P-cadherins, cadherin-4) and type II (cadherins 5-15). Cadherin-8, a type II cadherin, was cloned by Tanihara et al. 10 and is characterized by strong sequence homology with the classical type I cadherins. 11 In mice, cadherin-8 expression is restricted to the developing CNS and thymus. 12,13 As has been demonstrated for type I cadherins, type II cadherins interact with ␣-and ␤-catenins. 14 Using an L-fibroblast cDNA transfection system and a long-term cell-aggregation assay, Shimoyama et al. 15 clearly demonstrated that all 8 type II cadherins exhibited cell-cell binding activity comparable to that of E-cadherin. Heterophilic interactions among the type I...

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A comparison of prenatal muscle transcriptome and proteome profiles between pigs with divergent growth phenotypes

Shang

Wang

Chamba

et al. 2018

J of Cellular Biochemistry

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The growth of pigs is an important economic trait that involves multiple genes and coordinated regulatory mechanisms. The growth rate and potential of skeletal muscles are largely decided by embryonic myofiber development. Tibetan pig (TP) that is a mini‐type breed has a divergent phenotype in growth rate and adult body weight with Wujin pig (WJ) and large White pig (LW). In the current study, the transcriptome (using RNA‐seq) and proteome (using the isobaric tag for relative and absolute quantification [iTRAQ]) data from the prenatal muscle tissues were analyzed to identify the genes related to postnatal growth rate and growth potential in pigs. In the RNA‐seq experiment, 19 626 genes were detected in the embryonic muscle tissues, and 3626 unique differentially expressed genes (DEGs) were identified in TP in comparison to that in LW and WJ. In the iTRAQ experiment, 2474 proteins were detected, and 735 unique differentially expressed proteins (DEPs) were identified in TP in comparison to that in LW and WJ. Combining the DEGs and DEPs, 209 genes were found to be differentially expressed, consistently at both the messenger RNA and protein levels, between TP and the other two breeds; these are mainly involved in 2‐oxocarboxylic acid metabolism, citrate cycle, and biosynthesis of amino acids. Of these, 20 genes that were related to myoblast differentiation and muscle fiber formation might have important roles in determining the postnatal growth rate and potential body weight in pigs. Our results provide new candidate genes and insights into the molecular mechanisms involved muscle growth traits in pigs.

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Molecular Cloning and Characterization of a Novel Human Classic Cadherin Homologous with Mouse Muscle Cadherin

Cited by 14 publications

References 59 publications

Biochemical Characterization and Functional Analysis of Two Type II Classic Cadherins, Cadherin-6 and -14, and Comparison with E-cadherin

Biochemical Characterization and Functional Analysis of Two Type II Classic Cadherins, Cadherin-6 and -14, and Comparison with E-cadherin

Expression of cadherin‐8 in renal cell carcinoma and fetal kidney

A comparison of prenatal muscle transcriptome and proteome profiles between pigs with divergent growth phenotypes

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