Crystal Structure and Functional Analysis of the Protein Disulfide Isomerase-Related Protein ERp29

The protein disulfide isomerase-related protein ERp29 is a putative chaperone involved in processing and secretion of secretory proteins. Until now, however, both the structure and the exact nature of interacting substrates remained unclear. We provide for the first time a crystal structure of human ERp29, refined to 2.9 Å, and show that the protein has considerable structural homology to its Drosophila homolog Wind. We show that ERp29 binds directly not only to thyroglobulin and thyroglobulin-derived peptides in vitro but also to the Wind client protein Pipe and Pipe-derived peptides, although it fails to process Pipe in vivo. A monomeric mutant of ERp29 and a D domain mutant in which the second peptide binding site is inactivated also bind protein substrates, indicating that the monomeric thioredoxin domain is sufficient for client protein binding. Indeed, the b domains of ERp29 or Wind, expressed alone, are sufficient for binding proteins and peptides. Interacting peptides have in common two or more aromatic residues, with stronger binding for sequences with overall basic character. Thus, the data allow a view of the two putative peptide binding sites of ERp29 and indicate that the apparent, different processing activity of the human and Drosophila proteins in vivo does not stem from differences in peptide binding properties.     

Assignment of the dipeptidylpeptidase IV (DPP4) gene to pig Chromosome 15q21

A porcine 2-kb partial dipeptidylpeptidase IV (DPP4, EC 3.4.14.5) cDNA clone and a porcine 16-kb genomic fragment containing parts of the DPP4 gene were isolated, characterized, and used as probes to map the DPP4 gene to pig Chr (Chr) 15q21 by fluorescence in situ hybridization. A two-allele RFLP was revealed for the DPP4 gene. This polymorphism was utilized in a linkage test against the erythrocyte antigen G (EAG), previously assigned to Chr 15, and the microsatellite S0088, which is linked to EAG. The linkage analyses revealed significant evidence for linkage confirming the assignment of DPP4 to Chr 15.     

Molecular Characterization of Human Neogenin, a DCC-Related Protein, and the Mapping of Its Gene (NEO1) to Chromosomal Position 15q22.3–q23

Neogenin was first identified in the chick embryo, and like a number of cell surface proteins of the immunoglobulin (Ig) superfamily, including N-CAM and L1 (generally called cell adhesion molecules or CAMs), it is expressed on growing nerve cells in the developing nervous system of vertebrate embryos. Neogenin is also expressed in other embryonic tissues, suggesting a more general role in developmental processes such as tissue growth regulation, cell–cell recognition, and cell migration. Neogenin, unlike the CAMs, is closely related to a unique tumor suppressor candidate molecule, deleted in colorectal carcinoma (DCC). Like DCC, the neogenin protein consists of four immunoglobulin-like (Ig-like) domains followed by six fibronectin type III domains, a transmembrane domain, and an intracellular domain. We now report the cloning and sequencing of cDNA clones coding for the human neogenin protein. Human neogenin shares 87% identity with its chicken homolog, and like its chicken counterpart it is expressed in at least two different isoforms derived from alternative splicing in the intracellular domain. Northern blot analysis revealed two mRNA species of about 5 and 7 kb. The chromosomal location of the human neogenin gene (HGMW-approved symbol NEO1) was determined as 15q22.3–q23, using fluorescencein situhybridization. The gene therefore maps in the vicinity of a locus associated with Bardet–Biedl syndrome. The identification of human neogenin and its chromosomal location provides a basis for studying its involvement in genetic disorders or diseases.     

Molecular Cloning and Chromosomal Localization to 17q21 of the Human WNT3 Gene

In mouse mammary tumors, the Wnt-3 gene can be activated by proviral insertion. Here we report on the isolation of a human homolog, WNT3. A genomic clone was isolated by use of mouse Wnt-3 sequences as a probe, after which cDNA containing most of the protein-encoding domain of the human gene was obtained by PCR. Comparison between the deduced mouse and human WNT-3 protein sequences showed four changes in 333 amino acids. WNT3 is located on chromosome 17q21. The gene was not found to be amplified or rearranged in a collection of human breast tumors.     

Assignment of the Y4Receptor Gene (PPYR1) to Human Chromosome 10q11.2 and Mouse Chromosome 14

The human and mouse genes for the neuropeptide Y₄receptor have been isolated, sequenced, and shown to contain no introns within the coding region of the gene. Nonisotopicin situhybridization and interspecific mouse backcross mapping have localized the genes to human chromosome 10q11.2 and mouse chromosome 14. Five nucleotide variants, which do not alter the protein sequence, have been identified within the coding region of the human receptor gene. The human Y₄subtype is most closely related to the Y₁-receptor subtype (42%), suggesting that it evolved from an ancestral Y₁-like receptor via an RNA-mediated transpositional event.