Ubiquinone （Coenzyme Q） Biosynthesis in Chlamydophila pneumoniae AR39： Identification of the ubiD Gene

Ubiquinone is an essential electron carrier in prokaryotes.Ubiquinone biosynthesis involves atleast nine reactions in Escherichia coli.3-octaprenyl-4-hydroxybenzoate decarboxylase (UbiD) is an importantenzyme on the pathway and deletion of the ubiD gene in E.coli gives rise to ubiquinone deficiency in vivo.A protein from Chlamydophila pneumoniae AR39 had significant similarity compared with protein UbiDfrom E.coli.Based on this information,the protein-encoding gene was used to swap its counterpart inE.coli,and gene expression in resultant strain DYC was confirmed by RT-PCR.Strain DYC grew usingsuccinate as carbon source and rescued ubiquinone content in vivo,while ubiD deletion strain DYD did not.Results suggest that the chlamydial protein exerts the function of UbiD.     

Regulation of the isofunctional genes ubiD and ubiX of the ubiquinone biosynthetic pathway of Escherichia coli

The expressions of the isofunctional genes ubiD and ubiX of the ubiquinone biosynthetic pathway of Escherichia coli were compared under a variety of growth conditions and in several genetic backgrounds. LacZ operon fusions were constructed and were inserted in single copies into strain MC4100 and into its fnr, arcA or hemA carrying derivatives. During aerobic growth the expressions of both ubiD and ubiX depended on the carbon source: succinate>glycerol>glucose. Mutations in fnr, arcA or hemA increased the expressions of both genes. During anaerobic growth in LB medium glucose strongly inhibited the expression of ubiD but not of ubiX.     

Biosynthesis of Ubiquinone in Escherichia coli K-12: Location of Genes Affecting the Metabolism of 3-Octaprenyl-4-hydroxybenzoic Acid and 2-Octaprenylphenol

Two genes (ubiB and ubiD) concerned with two successive reactions in ubiquinone biosynthesis in Escherichia coli were mapped and found to be closely linked. Mutant strains of E. coli carrying the ubiB(-) and ubiD(-) alleles were shown to accumulate 2-octaprenylphenol and 3-octaprenyl-4-hydroxybenzoic acid, respectively. These compounds were isolated and identified by using nuclear magnetic resonance and mass and infrared spectroscopy. Cell extracts from the mutant strain carrying the ubiD(-) allele lack 3-octaprenyl-4-hydroxybenzoate decarboxylase activity.     

Distribution of genes encoding the microbial non-oxidative reversible hydroxyarylic acid decarboxylases/phenol carboxylases

Bacterial non-oxidative, reversible multi subunit hydroxyarylic acid decarboxylases/phenol carboxylases are encoded by the three clustered genes, B, C, and D, of approximately 0.6, 1.4, and 0.2 kb, respectively. There are more than 160 homologues in the database with significant similarity to gene B (homology to ubiX) and C (ubiD) distributed in all three microbial domains, however, homologues to gene D, are not numerous ( approximately 15). The occurrence of the entire BCD gene cluster encoding for either identified or presumptive hydroxyarylic acid decarboxylase to date has been revealed in Sedimentibacter hydroxybenzoicus (unique genes arrangement CDB), Streptomyces sp. D7, Bacillus subtilis, B. licheniformis, E. coli O157:H7, Klebsiella pneumoniae, Enterobacter cloacae, Shigella dysenteriae, Salmonella enterica, S. paratyphi, S. typhimurium, S. bongori, and S. diarizonae. The corresponding genes from S. hydroxybenzoicus, B. subtilis, Streptomyces sp. D7, E. coli O157:H7, K. pneumoniae, and S. typhimurium were cloned and expressed in E. coli DH5alpha (void of analogous genes), and shown to code for proteins exhibiting non-oxidative hydroxyarylic acid decarboxylase activity.     

Low Ubiquinone Content in Escherichia coli Causes Thiol Hypersensitivity

Thiol hypersensitivity in a mutant of Escherichia coli (IS16) was reversed by complementation with a plasmid that carried the ubiX gene. The mutant had low ubiquinone content. Complementation elevated the ubiquinone level and eliminated thiol hypersensitivity. Analysis of chromosomal ubiX genes indicated that both parent and mutant strains were ubiX mutants. The low ubiquinone content of IS16 was possibly caused by a ubiD ubiX genotype. A ubiA mutant also exhibited thiol hypersensitivity. Neither IS16 nor the ubiA mutant strain could produce alkaline phosphatase (in contrast to their parent strains) after 2 h of induction, thus showing Dsb⁻ phenotypes. The phenomena of thiol hypersensitivity and low ubiquinone content may be linked by their connections to the periplasmic disulfide bond redox machinery.     

Alternative hydroxylases for the aerobic and anaerobic biosynthesis of ubiquinone in Escherichia coli.

The synthesis of ubiquinone under anaerobic conditions was examined in a variety of strains of Escherichia coli K12. All were shown to synthesize appreciable quantities of ubiquinone 8 when grown anaerobically on glycerol in the presence of fumarate. Under these conditions, ubiquinone 8 was in most cases the principal quinone formed, and levels in the range 50--70% of those obtained aerobically were observed. Studies with mutants blocked in the various reactions of the aerobic pathway for ubiquinone 8 synthesis established that under anaerobic conditions three alternative hydroxylation reactions not involving molecular oxygen are used to derive the C-4, -5, and -6 oxygens of ubiquinone 8. Thus, mutants blocked in either of the three hydroxylation reactions of the aerobic pathway (ubiB, ubiH, or ubiF) are each able to synthesize ubiquinone 8 anaerobically, whereas mutants lacking the octaprenyltransferase (ubiA), carboxy-lyase (ubiD), or methyltransferases (ubiE or ubiG) of the aerobic pathway remain blocked anaerobically. The demonstration that E. coli possesses a special mechanism for the anaerobic biosynthesis of ubiquinone suggests that this quinone may play an important role in anaerobic metabolism.     

Reconstructing the evolution of genes along the species tree

A model and algorithm are proposed to infer the evolution of a gene family described by the corresponding gene tree, with respect to the species evolution described by the corresponding species tree. The model describes the evolution using the new concept of a nested tree. The algorithm performance is illustrated by the example of several orthologous protein groups. The considered evolutionary events are speciation, gene duplication and loss, and horizontal gene transfer retaining the original gene copy. The transfer event with the loss of the original gene copy is considered as a combination of gene transfer and loss. The model maps each evolutionary event onto the species phylogeny.     

The problem of the gene

During the early 20th century the diverse practices of genetics were unified by the concept of the gene. This classical gene was simultaneously a unit of structure, function, mutation, and recombination. Starting in the 1940s, however, the classical gene began to fragment. Today when we speak of a gene for some malady, a regulatory gene, a structural gene, or a gene frequency, it is entirely possible that we are deploying different gene concepts even though we are using the same term. The problem of the gene addresses the fragmentation of the classical gene concept by asking to what extent a comprehensive and unifying gene concept is possible or desirable. Fully comprehensive gene concepts seem untenable today, but, within different disciplinary domains, unifying, but non-comprehensive, gene concepts can be epistemically worthwhile. The problem of the gene persists, however, not because of its epistemic value, but because of its political value. Using both the arguments for newly proposed gene concepts and the historical dispute over the classical gene, I argue that the desirability of gene concepts rests in part on the political ramifications of their deployment and contestation.     

Characterization of the gene conversions between the multigene family members of the yeast genome

Stanley Sawyer's gene conversion detection method, implemented in his GENECONV computer program, was used to detect and characterize the gene conversions between the multigene family members of the yeast genome. This method gave different gene conversion frequencies and size distribution for gene families with two members and multigene families with more than two members. The 69 gene conversions detected in multigene families with more than two members occur at a frequency of 7.8% gene conversion/pair of genes compared and have an average size of 173+/-220 nucleotides. Larger gene conversions are found only between more similar genes, the genes involved in gene conversions are distributed almost randomly among the 16 yeast chromosomes, and the frequency of gene conversions increases as the distance between repeated genes decreases. In contrast to previous studies, no relationship was observed between the level of expression of a gene and its involvement in gene conversions. These analyses also suggest that gene conversions might occur by different mechanisms in closely linked genes and unlinked genes. The excess of converted regions at the 3? end of unlinked genes suggests that recombination with incomplete cDNA molecules is the main mechanism responsible for gene conversions between such genes.     

Molecular analysis of the avirulence gene avr9 of the fungal tomato pathogen Cladosporium fulvum fully supports the gene-for-gene hypothesis

The interaction between the fungal pathogen Cladosporium fulvum and tomato is supposed to have a gene-for-gene basis. Races of C. fulvum which have 'overcome' the resistance gene Cf9 of tomato, lack the avirulence gene avr9 which encodes a race-specific peptide elicitor. Races avirulent on tomato genotypes carrying the resistance gene Cf9 produce the race-specific peptide elicitor, which induces the hypersensitive response (HR) on those genotypes. The causal relationship between the presence of a functional avr9 gene and avirulence on tomato genotype Cf9 was demonstrated by cloning of the avr9 gene and subsequent transformation of C. fulvum. A race virulent on tomato genotype Cf9 was shown to become avirulent by transformation with the cloned avr9 gene. These results clearly demonstrate that the avr9 gene is responsible for cultivar specificity on tomato genotype Cf9 and fully support the gene-for-gene hypothesis. The avr9 gene is the first fungal avirulence gene to be cloned.     

Retroviral long terminal repeat is the promoter of the gene encoding the tumor-associated calcium-binding protein oncomodulin in the rat

Oncomodulin is a small calcium-binding protein normally found only in extra-embryonic tissues such as the placenta, but whose presence in a variety of tumors has been documented. We have isolated the oncomodulin gene from a Buffalo rat genomic library. The rat gene is approximately 9000 bases in length and consists of five exons and four introns. The introns interrupt the coding sequence of oncomodulin in positions identical with those previously reported for the parvalbumin gene, indicating that the two genes are derived from a common ancestor. Analysis of the promoter sequence of the oncomodulin gene revealed that the gene is under the control of a solo long terminal repeat element related to intracisternal-A particles, a family of endogenous retroviral elements. This represents a unique example of a mammalian gene transcribed in normal and tumor cells, from a promoter of viral origin.     

Pseudomonas aeruginosa cytotoxin: the nucleotide sequence of the gene and the mechanism of activation of the protoxin

The gene encoding cytotoxin (ctx) was cloned from Pseudomonas aeruginosa 158 and the nucleotide sequence was determined. The structural gene of ctx encodes the procytotoxin of 286 amino acid residues with a molecular mass of 31,681 Daltons. Procytotoxin was activated by removal of 20 amino acid residues from the C terminus with trypsin. The cloned ctx gene was not expressed in either an Escherichia coli strain or a cytotoxin non-producing strain of P. aeruginosa. An expression system for the ctx gene was constructed by placing the structural gene of ctx downstream of tac promoter on a broad host-range vector plasmid.     

Identifying the rooted species tree from the distribution of unrooted gene trees under the coalescent

Gene trees are evolutionary trees representing the ancestry of genes sampled from multiple populations. Species trees represent populations of individuals—each with many genes—splitting into new populations or species. The coalescent process, which models ancestry of gene copies within populations, is often used to model the probability distribution of gene trees given a fixed species tree. This multispecies coalescent model provides a framework for phylogeneticists to infer species trees from gene trees using maximum likelihood or Bayesian approaches. Because the coalescent models a branching process over time, all trees are typically assumed to be rooted in this setting. Often, however, gene trees inferred by traditional phylogenetic methods are unrooted. We investigate probabilities of unrooted gene trees under the multispecies coalescent model. We show that when there are four species with one gene sampled per species, the distribution of unrooted gene tree topologies identifies the unrooted species tree topology and some, but not all, information in the species tree edges (branch lengths). The location of the root on the species tree is not identifiable in this situation. However, for 5 or more species with one gene sampled per species, we show that the distribution of unrooted gene tree topologies identifies the rooted species tree topology and all its internal branch lengths. The length of any pendant branch leading to a leaf of the species tree is also identifiable for any species from which more than one gene is sampled.     

Cloning and sequencing of the gene encoding the large (alpha-) subunit of the proteasome from Thermoplasma acidophilum

The gene encoding the alpha-subunit of the proteasome from the archaebacterium Thermoplasma acidophilum was cloned and sequenced. The gene encodes for a polypeptide with 233 amino acid residues and a calculated molecular weight of 25870. Sequence similarity of the alpha-subunit with the Saccharomyces cerevisiae wild-type suppressor gene scll+ encoded polypeptide, which is probably identical with the subunit YC7-alpha of the yeast proteasome, lends support to a putative role of proteasomes in the regulation of gene expression. The significant sequence similarity to the various subunits of eukaryotic proteasomes make it likely that proteasomal proteins are encoded by one gene family of ancient origin.     

Physical mapping of the human ATX1 homologue (HAH1) to the critical region of the 5q- syndrome within 5q32, and immediately adjacent to the SPARC gene

The 5q- syndrome is a myelodysplastic syndrome with the 5q deletion as the sole karyotypic abnormality. The human ATX1 homologue (HAH1), encodes a copper-binding protein with a role in antioxidant defence. We have mapped this gene to the 3 Mb critical region of gene loss of the 5q- syndrome within 5q32, flanked by the genes for ADRB2 and IL12B, using gene dosage analysis. Fine physical mapping of the HAH1 gene within this genomic interval was then performed by screening YAC and BAC contigs spanning the critical region of the 5q- syndrome using PCR amplification. The HAH1 gene maps immediately adjacent to the SPARC gene at 5q32, and is flanked by the genetic markers D5S1838 and D5S1419. The HAH1 gene is expressed in haematological tissues and plays a role in antioxidant defence. Antioxidant levels are low in most cancers and the importance of antioxidant enzymes in cancer genesis is well recognised. Genomic localisation, function and expression would suggest that the HAH1 gene represents a candidate gene for the 5q-syndrome.     

Expression of the crystal protein gene under the control of the alpha-amylase promoter in Bacillus thuringiensis strains.

The expression of an insecticidal crystal protein gene of Bacillus thuringiensis under the control of the alpha-amylase gene promoter was investigated. The cryIC gene, which encodes a protein known to have a unique activity against Spodoptera (armyworm) species, was used in this investigation. The cryIC gene was placed, along with the alpha-amylase promoter from B. subtilis, in a B. thuringiensis-derived cloning vector, generating a pair of recombinant plasmids, pSB744 and pSB745. The cloning vector that contains the minimal replicon of B. thuringiensis subsp. kurstaki HD73 is stably maintained in a variety of B. thuringiensis strains, as previously reported by Gamel and Piot (Gene 120:17-26, 1992). The present study confirmed that the recombinant plasmids are also stably maintained in B. thuringiensis subsp. kurstaki Cry-B and HD73 growing in media without selection pressure for at least 48 h. The cryIC gene on the recombinant plasmids were notably expressed at high levels in both recombinant strains. Expression of the introduced cryIC gene on the recombinant plasmid in B. thuringiensis subsp. kurstaki HD73 did not impair expression of the resident cryIA(c) gene. The CryIA(c) protein is known to have a high level of activity against loopers such as Trichoplusia ni (the cabbage looper). As a result of coexpression of the introduced cryIC gene and the resident cryIA(c) gene, recombinant strain HD73 acquired an additional insecticidal activity against Spodoptera exigua (the beet armyworm) whereas the original activity level against T. ni was maintained.