D A Rochefort scite author profile

We performed molecular phylogenetic analyses of glutamine synthetase (GS) genes in order to investigate their evolutionary history. The analyses were done on 30 DNA sequences of the GS gene which included both prokaryotes and eukaryotes. Two types of GS genes are known at present: the GSI gene found so far only in prokaryotes and the GSII gene found in both prokaryotes and eukaryotes. Our study has shown that the two types of GS gene were produced by a gene duplication which preceded, perhaps by >1000 million years, the divergence of eukaryotes and prokaryotes. The results are consistent with the facts that (t0 GS is a key enzyme of nitrogen metabolism found in all extant life forms and (fi) the oldest biological fossils date back 3800 million years. Thus, we suggest that GS genes are one of the oldest existing and functioning genes in the history of gene evolution and that GSI genes should also exist in eukaryotes. Furthermore, our study may stimulate investigation on the evolution of "preprokaryotes," by which we mean the organisms that existed during the era between the origin of life and the divergence of prokaryotes and eukaryotes.Glutamine synthetase (GS) is a key enzyme in nitrogen metabolism; it has dual functions in two essential biochemical reactions, ammonia assimilation and glutamine biosynthesis (1, 2). It is also one of the few amide synthetases found in organisms. Prokaryotes and eukaryotes were once thought to synthesize different GSs: GSI for the former and GSII for the latter. It is now known, however, that GSII is also present in bacteria belonging to Rhizobiaceae (3-6), Frankiaceae (7), and Streptomycetaceae (8, 9). GSI, by contrast, has not been found in any eukaryote.Glutamine produced by GS is essential for protein synthesis, and its amide nitrogen is donated to synthesize many essential metabolites. It is thus natural to consider GS as present in, and probably indispensable to, all organisms. In view of the central roles played by GS, it is reasonable to believe that the GS gene is extremely old. From the sequence alignment of GSI from Salmonella typhimurium and GSII from alfalfa (10), we could observe that the differences in amino acids between them was 0.75 per site. This value is quite large compared with those for other proteins, suggesting also that the GSI and GSII genes share a very old comnmon ancestor.The aforementioned discovery of the GSII gene in plant symbiotic bacteria led to the suggestion that the gene had originated from host plants through lateral gene transfer (3). This was later questioned by the further findings of the GSII gene in plant nonsymbiotic actinomycetes (8, 9). Shatters and Kahn (6) have suggested that the common ancestor of the GSII genes in Rhizobiaceae and in the host plant must be older than the plant itself, and have argued against the gene transfer.In this paper we have traced the evolutionary history of the GS genes, using our own nucleotide sequence data and others' data from prokaryotic and eukaryotic species in order to estimate the age of...

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Molecular cloning, sequencing, and expression of the glutamine synthetase II (glnII) gene from the actinomycete root nodule symbiont Frankia sp. strain CpI1

Rochefort

Benson

1990

J Bacteriol

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In common with other plant symbionts, Frankia spp., the actinomycete N2-fixing symbionts of certain nonleguminous woody plants, synthesize two glutamine synthetases, GSI and GSII. DNA encoding the Bradyrhizobium japonicum gene for GSII (glnII) hybridized to DNA from three Frankia strains. B. japonicum glnII was used as a probe to clone the glnII gene from a size-selected KpnI library of Frankia strain CpI1 DNA. The region corresponding to the Frankia sp. strain CpI1 glnII gene was sequenced, and the amino acid sequence was compared with that of the GS gene from the pea and glnII from B. japonicum. The Frankia glnII gene product has a high degree of similarity with both GSII from B. japonicum and GS from pea, although the sequence was about equally similar to both the bacterial and eucaryotic proteins. The Frankia glnII gene was also capable of complementing an Escherichia coli delta glnA mutant when transcribed from the vector lac promoter, but not when transcribed from the Frankia promoter. GSII produced in E. coli was heat labile, like the enzyme produced in Frankia sp. strain CpI1 but unlike the wild-type E. coli enzyme.

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Close linkage of genes encoding glutamine synthetases I and II in Frankia alni CpI1

1993

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Frankia alni CpI1 has two glutamine synthetases (GSs), GSI and GSII. The GSI gene (glnA) was isolated from a cosmid library of F. alni CpI1 DNA by heterologous probing with glnA from Streptomyces coelicolor. The glnA gene was shown to be located upstream of the GSII gene (glnII) by DNA-DNA hybridization. The nucleotide sequences of the 1,422-bp CpI1 glnA gene and of the 449-bp intervening region between glnA and glnII were determined, and the glnA amino acid sequence was deduced. In common with GSIs from other organisms, CpI1 GSI contains five conserved regions near the active site and a conserved tyrosine at the adenylylation site. F. alni CpI1 glnA complemented the glutamine growth requirement of the Escherichia coli glnA deletion strain YMC11 but only when expressed from an E. coli lac promoter. While the functional significance of maintaining two GSs adjacent to one another remains unclear, this arrangement in F. alni provides support for the recently proposed origin of GSI and GSII as resulting from a gene duplication early in the evolution of life.

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D A Rochefort

Evolution of the glutamine synthetase gene, one of the oldest existing and functioning genes.

Molecular cloning, sequencing, and expression of the glutamine synthetase II (glnII) gene from the actinomycete root nodule symbiont Frankia sp. strain CpI1

Close linkage of genes encoding glutamine synthetases I and II in Frankia alni CpI1

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