We report the isolation of a novel vitamin K-dependent protein from the calcified cartilage of Adriatic sturgeon (Acipenser nacarii). This 10.2-kDa secreted protein contains 16 ␥-carboxyglutamic acid (Gla) residues in its 74-residue sequence, the highest Gla percent of any known protein, and we have therefore termed it Gla-rich protein (GRP). GRP has a high charge density (36 negative ؉ 16 positive ؍ 20 net negative) yet is insoluble at neutral pH. GRP has orthologs in all taxonomic groups of vertebrates, and a paralog (GRP2) in bony fish; no GRP homolog was found in invertebrates. There is no significant sequence homology between GRP and the Gla-containing region of any presently known vitamin K-dependent protein. Forty-seven GRP sequences were obtained by a combination of cDNA cloning and comparative genomics: all 47 have a propeptide that contains a ␥-carboxylase recognition site and a mature protein with 14 highly conserved Glu residues, each of them being ␥-carboxylated in sturgeon. The protein sequence of GRP is also highly conserved, with 78% identity between sturgeon and human GRP. Analysis of the corresponding gene structures suggests a highly constrained organization, particularly for exon 4, which encodes the core Gla domain. GRP mRNA is found in virtually all rat and sturgeon tissues examined, with the highest expression in cartilage. Cells expressing GRP include chondrocytes, chondroblasts, osteoblasts, and osteocytes. Because of its potential to bind calcium through Gla residues, we suggest that GRP may regulate calcium in the extracellular environment.
A growing interest in the understanding of the ontogeny and mineralization of fish skeleton has emerged from the recent implementation of fish as a vertebrate model, particularly for skeletal development. Whereas several in vivo studies dealing with the regulation of bone formation in fish have been published, in vitro studies have been hampered because of a complete lack of fish-bone-derived cell systems. We describe here the development and the characterization of two new cell lines, designated VSa13 and VSa16, derived from the vertebra of the gilthead sea bream. Both cell types exhibit a spindle-like phenotype and slow growth when cultured in Leibovitz's L-15 medium and a polygonal phenotype and rapid growth in Dulbecco's modified Eagle medium (D-MEM). Scanning electron microscopy and von Kossa staining have revealed that the VSa13 and VSa16 cells can only mineralize their extracellular matrix when cultured in D-MEM under mineralizing conditions, forming calcium-phosphate crystals similar to hydroxyapatite. We have also demonstrated the involvement of alkaline phosphatase, a marker of bone formation in vivo, and Gla proteins (osteocalcin and matrix Gla protein, MGP) in the process of mineralization. Finally, we have shown that VSa13 and VSa16 cell lines express osteocalcin and MGP in a mutually exclusive manner. Thus, both cell lines are capable of mineralizing in vitro and of expressing genes found in chondrocyte and osteoblast cell lineages, emphasizing the suitability of these new cell lines as valuable tools for analyzing the expression and regulation of cartilage- and bone-specific genes.
Aquaporin water channels facilitate the transmembrane diffusion of water and higher organisms possess a large number of isoforms. The genome of the yeast Saccharomyces cerevisiae contains two highly similar aquaporin genes, AQY1 and AQY2. AQY1 has been shown to encode a functional water channel but only in certain laboratory strains. Here we show that the AQY2 gene is interrupted by an 11 bp deletion in 23 of the 27 laboratory strains tested, with the exception of strains from the Σ1278b background, which also exhibit a functional Aqy1p. However, although the AQY2 gene from Σ1278b is highly homologous to functional aquaporins, we did not observe Aqy2p‐mediated water transport in Xenopus oocytes. A survey of 52 yeast strains revealed that all industrial and wild yeasts carry the allele encoding a functional Aqy1p, while none of these strains appear to have a functional Aqy2p. We conclude that natural and industrial conditions provide selective pressure to maintain AQY1 but apparently not AQY2. Copyright © 2000 John Wiley & Sons, Ltd.
Two genes YER081W and YIL074C, renamed SER3 and SER33, respectively, which encode phosphoglycerate dehydrogenases in Saccharomyces cerevisiae were identified. These dehydrogenases catalyze the first reaction of serine and glycine biosynthesis from the glycolytic metabolite 3-phosphoglycerate. Unlike either single mutant, the ser3⌬ ser33⌬ double mutant lacks detectable phosphoglycerate dehydrogenase activity and is auxotrophic for serine or glycine for growth on glucose media. However, the requirement for the SER-dependent "phosphoglycerate pathway" is conditional since the "glyoxylate" route of serine/glycine biosynthesis is glucose-repressed. Thus, in cells grown on ethanol both expression and activity of all SER-encoded proteins are low, including the remaining enzymes of the phosphoglycerate pathway, Ser1p and Ser2p. Moreover the available nitrogen source regulates the expression of SER genes. However, for only SER33, and not SER3, expression was regulated in relation to the available nitrogen source in a coordinated fashion with SER1 and SER2. Based on these mRNA data together with data on enzyme activities, Ser33p is likely to be the main isoenzyme of the phosphoglycerate pathway during growth on glucose. Moreover, since phosphoglycerate dehydrogenase activity requires NAD ؉ as cofactor, deletion of SER3 and SER33 markedly affected redox metabolism as shown by substrate and product analysis.
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