Specific receptors for lutropin (luteinizing hormone; LH) and follitropin (follicle-stimulating hormone; FSH) mediate the actions of human chorionic gonadotropin (hCG) and FSH5 on the gonads. Here we report that short independent sequences of the beta-subunit enable hCG to distinguish between the receptors for FSH and LH. Residues between the 11th and 12th cysteines restrict FSH receptor binding; residues between the 10th and 11th cysteines and, to a much lesser extent, residues carboxy-terminal to the 12th cysteine also affect LH receptor binding. CF101-109, an hCG analogue containing hFSH beta residues between the 11th and 12th cysteines, had high affinity for both LH and FSH receptors. Modifications to CF101-109 that reduce binding to either LH or FSH receptors yield gonadotropin analogues having differing ratios of LH:FSH activity. Ligand-binding specificity of the LH receptor is determined by residues encoded by parts of exons 2-4 and 7-9 which prevent hFSH binding but have little effect on hCG binding. FSH receptor specificity is controlled primarily by residues encoded by exons 5 and 6 that prevent hCG binding but have little effect on hFSH binding. These determinants can be interchanged to create receptor analogues that bind hCG and hFSH. Our observations support a model in which distinct negative determinants restrict ligand-receptor interaction. This explains coevolution of binding specificity in families of homologous ligands and their receptors. Natural or designed manipulation of these determinants leads to the 'evolution' of new, specific protein-protein interactions.
We report the cloning of five overlapping cDNAs bearing sequences specific for the human pro alpha 1(I) collagen chain. Poly-A RNA enriched for collagen sequences was purified from normal human fibroblasts and used as template to synthesize double stranded cDNA. The cDNA was inserted into the Eco RI site of pBR 322 by blunt-ending and dG:dC tailing. The clones were screened by colony hybridization using the original RNA population and the resulting five positive clones subjected to restriction endonuclease mapping analysis and DNA sequencing. These overlapping clones cover from residue 247 in the alpha chain to part of the 3' end untranslated region of the pro alpha 1(I) mRNA for a total of 3400 nucleotides.
Nucleotide sequences of complementary deoxyribonucleic acids for the pro.alpha.1 chain of human type I procollagen. Statistical evaluation of structures that are conserved during evolution
Nucleotide sequences were determined for two cloned cDNAs encoding for over three-fourths of the pro alpha 1 (I) chain of type I procollagen from man. Comparison with previously published data on amino acid sequences of the alpha 1 (I) chain of type I collagen made it possible to examine mutations in the transcribed products of the gene which have occurred during the evolution of man, calf, rat, mouse, and chick. Comparison of the nucleotide sequences with the corresponding sequences of cDNAs from chick [Fuller, F., & Boedtker, H. (1981) Biochemistry 20, 996] and with cDNAs for the pro alpha 2(I) chain from man [Bernard, M.P., Myers, J. C., Chu, M.-L., Ramirez, F., Eikenberry, E. F., & Prockop, D. J. (1983) Biochemistry 22, 1139] demonstrated that selective pressure during evolution for 250 million or more years acted more strongly on the structure of the pro alpha 1 (I) chain than on the pro alpha 2(I) chain. To improve the reliability of the comparison, the nucleotide sequences were examined with a modification of previous procedures for evaluating mutations in replacement sites and silent sites. The corrected divergence for replacement sites between the alpha 1 (I) chains was 6 +/- 0.8% whereas it was 15 +/- 1.9% for the alpha 2(I) chains. The C-propeptide domain of the pro alpha 1 (I) chain was also highly conserved with a corrected divergence at replacement sites of 5 +/- 0.9%, a value that was not distinguishable from the value previously found for the C-propeptide of the pro alpha 2(I) chain. Therefore, a large part of the structure of both C-propeptides appears to be under selective pressure. Inspection of changes in the C-propeptide of the pro alpha 1 (I) chain suggested that there was a highly conserved region around the carbohydrate attachment site similar to the highly conserved region of 37 amino acids previously found in the C-propeptide of the pro alpha 2(I) chain. Two statistical tests, however, were unable to confirm nonrandom distribution of changes in the C-propeptide of the pro alpha 1(I) chain. The same tests established the presence of a nonrandom distribution in nucleotide changes of the C-propeptide of the pro alpha 2(I) chain. The 3'-noncoding region of the cDNA for pro alpha 1(I) of human type I procollagen showed no homology with the same region in the chick.(ABSTRACT TRUNCATED AT 400 WORDS)
The goal of these studies was to devise a model that explains how human chorionic gonadotropin (hCG) interacts with lutropin (LH) receptors to elicit a hormone signal. Here we show that alpha-subunit residues near the N terminus, the exposed surface of the cysteine knot, and portions of the first and third loops most distant from the beta-subunit interface were recognized by antibodies that bound to hCG-receptor complexes. These observations were combined with similar data obtained for the beta-subunit (Cosowsky, L., Rao, S.N.V., Macdonald, G.J., Papkoff, H., Campbell, R.K., and Moyle, W.R. (1995) J. Biol. Chem. 270, 20011-20019), information on residues of hCG that can be changed without disrupting hormone function, the crystal structure of deglycosylated hCG, and the crystal structure of a leucine-repeat protein to devise a model of hCG-receptor interaction. This model suggest that the extracellular domain of the LH receptor is "U-" or "J"-shaped and makes several contacts with the transmembrane domain. High affinity hormone binding results from interactions between residues in the curved portion of the extracellular domain of the receptor and the groove in the hormone formed by the apposition of the second alpha-subunit loop and the first and third beta-subunit loops. Most of the remainder of the hormone is found in the large space between the arms of the extracellular domain and makes few, if any, additional specific contacts with the receptor needed for high affinity binding. Signal transduction is caused by steric or other influences of the hormone on the distance between the arms of the extracellular domain, an effect augmented by the oligosaccharides. Because the extracellular domain is coupled at multiple sites to the transmembrane domain, the change in conformation of the extracellular domain is relayed to the transmembrane domain and subsequently to the cytoplasmic surface of the plasma membrane. While the model does not require the hormone to contact the transmembrane domain to initiate signal transduction, small portions of both subunits may be near the transmembrane domain and assist in initiating the hormonal signal. This is the first model that is consistent with all known information on the activity of the gonadotropins including the amounts of the hormone that are exposed in the hormone-receptor complex, the apparent lack of specific contacts between much of the hormone and the receptor, and the roles of the oligosaccharides in signal transduction.(ABSTRACT TRUNCATED AT 400 WORDS)
Structure of a cDNA for the pro.alpha.2 chain of human type I procollagen. Comparison with chick cDNA for pro.alpha.2(I) identifies structurally conserved features of the protein and the gene
Nucleotide sequences were determined for cloned cDNAs encoding for more than half of the pro alpha 2 chain of type I procollagen from man. Comparisons with previously published data on homologous cDNAs from chick embryos made it possible to examine evolution of the gene in two species which have diverged for 250-300 million years. The amino acid sequence of the alpha-chain domain supported previous indications that there is a strong selective pressure to maintain glycine as every third amino acid and to maintain a prescribed distribution of charged amino acids. However, there is little apparent selective pressure on other amino acids. The amino acid sequence of the C-propeptide domain showed less divergence than the alpha-chain domain. The 5' end or N terminus of the human C-propeptide, however, contained an insert of 12 bases coding for 4 amino acids not found in the chick C-propeptide. About 100 amino acid residues from the N terminus, two residues found in the chick sequence were missing from the human. In the second half of the C-propeptide, there was complete conservation of a 37 amino acid sequence and conservation of 50 out of 51 amino acids in the same region, an observation which suggested that the region serves some special purpose such as directing the association of one pro alpha 2(I) C-propeptide with two pro alpha 1(I) C-propeptides so as to produce the heteropolymeric structure of type I procollagen. In addition, comparison of human and chick DNAs for pro alpha 2(I) revealed three different classes of conservation of nucleotide sequence which have no apparent effect on the structure of the protein: a preference for U on the third base position of codons for glycine, proline, and alanine; a high degree of nucleotide conservation in the 51 amino acid highly conserved region of the C-propeptide; a high degree of nucleotide conservation in the 3'-noncoding region. These three classes of nucleotide conservation may reflect unusual features of collagen genes, such as their high GC content or their highly repetitive coding sequences.
Pepsin-solubilized collagen VI was prepared from human placenta and used to separate three constituent chains for determining partial amino acid sequences. Antibodies raised against the chains assisted in the identification and purification of several cDNA clones from three expression lgtl 1 libraries. Most of the clones hybridized to either a 3.5-kb or 4.2-kb mRNA species which by matching peptide and nucleotide sequences could be identified as coding for the a2(VI) or al(V1) chain, respectively. Other clones hybridized to either an 8.5-kb mRNA which very likely encodes the a3(VI) chain or to an unknown 2.0-kb mRNA. Northern blots revealed a considerable variation in the mRNA levels for each collagen VI chain in both skin and cornea fibroblasts and in several tumor cell lines. Limited sequence data generated from peptides and cDNA clones demonstrated a characteristic cysteine pattern at the junction between N-terminal globular domain and triple helix in all three chains. In addition, the data showed occasional interruptions of triplet sequences within the triple-helical domain and the presence of two Arg-Gly-Asp sequences which are potential cell-binding structures.Collagen type VI is a unique member within the family of collagenous proteins [l] and is characterized by a rather short triple helix (length 105 nm, M , = 120000), flanked on each side by a globular domain ( M , z 150000). These monomeric structures have the potential to form well-defined, disulfidelinked dimers and tetramers considered to be the building blocks of microfibrils which are abundant in the extracellular matrix [2]. Collagen VI was originally isolated from pepsin digests of tissues [3], a procedure which results in the loss of more than half of its original mass. Such materials were nevertheless valuable for chemical and electron microscope characterizations [4-71, which indicated that the chain fragments have M , = 40000 -70000. These studies eventually led to the proposal that collagen VI is composed of three constituent chains named al(VI), a2(VI) and a3(VI) [8]. Subsequent studies using antibodies raised against pepsin-solubilized collagen VI demonstrated that the genuine chain constituents are considerably larger, with M , = 110000-140000 19-151. A more recent investigation provided evidence that this size refers only to the al(V1) and a2(VI) chains, as a3(VI) is still larger (Mr = 200000) and is presumably synthesized in precursor form with M , = 250000 [16]. Previously biosynthetic studies demonstrated that a large peptide was closely associated with collagen VI, yet no data had shown that it contained collagenous sequences [17-201. In view of the various attempts to characterize the structure of collagen VI, only little is known about its biological roles [2] which may include the potential for cell-binding [21].A drawback in the studies of intact collagen VI has been the difficulty to isolate the material in amounts sufficient for In an effort to overcome some of these difficulties we have initiated studies on the identificati...
The collagens represent an interesting example of a structurally related but genetically distinct family of proteins. Type I, the most abundant of the vertebrate collagens, comprises two pro alpha 1(I) chains and one pro alpha 2(I) chain, each containing terminal propeptides and a central domain of 338 (Gly, X, Y) repeats. The structure of the chicken pro alpha 2(I) gene shows an intriguing relationship between exon organization and the arrangement of (Gly, X, Y) repeats (see ref. 2 for review). This has led to the suggestion that the collagens evolved from a common ancestral unit of 54 base pairs (bp). Here we present the structure of the entire human pro alpha 1(I) gene and compare this with the chicken pro alpha 2(I). The exon arrangement of the two genes is remarkably similar, although the human pro alpha 1(I) is more compact because of the shorter length of its introns. The data strongly support the notion that the type I genes have evolved from an ancestral multi-exon unit, and that once the gene was translated, a strong evolutionary pressure caused it to maintain this elaborate structure.
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