Structural and functional aspects of the multiplicity of Neu differentiation factors.

We used molecular cloning and functional analyses to extend the family of Neu differentiation factors (NDFs) and to explore the biochemical activity of different NDF isoforms. Exhaustive cloning revealed the existence of six distinct fibroblastic pro-NDFs, whose basic transmembrane structure includes an immunoglobulin-like motif and an epidermal growth factor (EGF)-like domain. Structural variation is confined to three domains: the C-terminal portion of the EGF-like domain (isoforms alpha and beta), the adjacent juxtamembrane stretch (isoforms 1 to 4), and the variable-length cytoplasmic domain (isoforms a, b, and c). Only certain combinations of the variable domains exist, and they display partial tissue specificity in their expression: pro-NDF-alpha 2 is the predominant form in mesenchymal cells, whereas pro-NDF-beta 1 is the major neuronal isoform. Only the transmembrane isoforms were glycosylated and secreted as biologically active 44-kDa glycoproteins, implying that the transmembrane domain functions as an internal signal peptide. Extensive glycosylation precedes proteolytic cleavage of pro-NDF but has no effect on receptor binding. By contrast, the EGF-like domain fully retains receptor binding activity when expressed separately, but its beta-type C terminus displays higher affinity than alpha-type NDFs. Likewise, structural heterogeneity of the cytoplasmic tails may determine isoform-specific rate of pro-NDF processing. Taken together, these results suggest that different NDF isoforms are generated by alternative splicing and perform distinct tissue-specific functions.

Human alpha 2-HS-glycoprotein/bovine fetuin homologue in mice: identification and developmental regulation of the gene.

Human alpha 2-HS-glycoprotein (AHSG) is a plasma protein synthesized in liver and selectively concentrated in bone matrix. It has been reported to be involved in bone formation and resorption as well as immune responses. Recently, AHSG was found to be the species equivalent protein of fetuin, the major fetal serum protein in cattle and sheep. The function and regulation of AHSG/fetuin in different species are not understood. We have isolated a liver cDNA clone that encodes the human AHSG/bovine fetuin homologue in the mouse. The AHSG/fetuin gene may have a role in differentiation since it is expressed in mouse limb buds and brain only at certain stages during development. Mouse liver AHSG/fetuin mRNA was present at low level at 12 days gestation but its level increased during the late part of gestation and peaked between 1 to 3 months after birth. The regulation of mouse AHSG/fetuin synthesis during development was found to be significantly different from that of sheep and bovine fetuin. Compared to fetuin, which is reduced in adult to 1 to 2% of the fetal level, mouse AHSG synthesis subsides only 50% 4 months after birth.

Cloning of cDNAs encoding human TIMP-3, a novel member of the tissue inhibitor of metalloproteinase family.

Proteins of the tissue inhibitor of metalloproteinase (TIMP) family bind and inactivate matrix metalloproteinases such as collagenases and gelatinases. We report the cloning and sequencing of cDNAs encoding a novel human TIMP, which we designated TIMP-3, the third member of the human TIMP family. Degenerate PCR primers derived from highly conserved regions of TIMP family cDNAs amplified a 402-bp product from human fetal kidney cDNA. This product and a related 333-bp PCR product were used as probes to screen two cDNA libraries. Three TIMP-3 cDNA clones were isolated, including a 1240-bp fetal kidney clone that contained a complete TIMP-3 precursor coding region of 211 amino acids (aa). The deduced precursor protein includes twelve Cys and 27 other aa that are invariant in the TIMP family. The predicted aa sequence is 89, 39 and 46% identical to those of ChIMP-3, human TIMP-1 and human TIMP-2, respectively. Northern blot analyses detected three TIMP-3 mRNA bands of 2.2, 2.5 and 4.4 kb in several human cell lines.

Evolutionary and structural relationships among the group-specific component, albumin and alpha-fetoprotein.

The group-specific component (Gc) is a plasma protein that binds vitamin D. Recent characterization of human Gc cDNA demonstrated homology with serum albumin and alpha-fetoprotein. This study compares the sequences of the three proteins and demonstrates a strong evolutionary relationship. Albumin, alpha-fetoprotein and Gc evolved from an ancestral gene containing an intragenic triplication. Comparison of the amino acid sequences and patterns of double disulfide bonds suggests that the Gc gene may have diverged from an ancestral gene earlier in evolution than the genes encoding albumin and alpha-fetoprotein. Analysis of the amino acid and nucleotide sequences of the three internal domains of Gc revealed 19-23% amino acid sequence identity and the localization of three homology blocks with 40-44% nucleotide sequence identity. The deduced amino sequence of Gc furnished data for comparing its molecular configuration based on the predicted secondary structure with those predicted for human albumin and alpha-fetoprotein. Utilization of Gc cDNA has also led to the identification of its genomic DNA and detection of a human DNA polymorphism.

Human group-specific component (Gc) is a member of the albumin family.

The group-specific component (Gc) is the major vitamin D-binding protein in plasma. The gene encoding Gc is linked, on human chromosome 4, to the albumin and alpha-fetoprotein genes. These two genes previously were shown to have evolved from a smaller ancestral gene by intragenic triplication. Recombinant plasmids containing human cDNA encoding Gc have been isolated by screening an adult human liver library with a mixed oligonucleotide probe. Characterization of Gc cDNA has provided the complete amino acid sequence of the protein and revealed strong sequence homology with albumin and alpha-fetoprotein. Of particular interest is a conserved pattern of disulfide bridges that form the triple-domain structures in albumin, alpha-fetoprotein, and Gc. Gc cDNA was used as a probe in Southern blot analysis of somatic-cell hybrids to confirm that the Gc locus is on chromosome 4.

Human ceruloplasmin. Tissue-specific expression of transcripts produced by alternative splicing.

Ceruloplasmin (CP) is a plasma glycoprotein that transports copper throughout the body. In previous studies (Yang, F., Naylor, S., Lum, J., Cutshaw, S., McCombs, J., Naberhaus, K., McGill, J., Adrian, G., Moore, C., Barnett, D., and Bowman, B. (1986) Proc. Natl. Acad. Sci. U. S. A. 83, 3277-3261), two CP cDNA clones, CP-1 and CP-2, from a human cDNA library, differed from each other by the presence or absence, respectively, of 12 nucleotide bases encoding a deduced sequence of Gly-Glu-Tyr-Pro near the carboxyl-terminal region of the ceruloplasmin molecule. Examination of genomic DNA demonstrates that the two CP mRNAs are produced from a single gene by alternative spliced patterns. The additional amino acids deduced in CP-1 are products of alternative splicing within an intron of the CP gene at a site 12 nucleotide bases 3' to the commonly used site of CP-2. The CP-1 mRNA transcript encoding four extra amino acids appeared as a minor species accompanying CP-2 mRNA in placenta and chondrocytes. CP-1 mRNA was the predominant CP transcript in a lymphoblastic leukemia cell line, CEM. The mRNA examined from other tissues contained only CP-2 mRNA transcripts. These findings predict that alternative RNA splicing may lead to the differential expression of CP genomic sequences and produce alternate isoforms from a single CP gene in specific tissues.