Comparative genomic and transcriptomic analysis revealed genetic characteristics related to solvent formation and xylose utilization in Clostridium acetobutylicum EA 2018

<p>Abstract</p> <p>Background</p> <p><it>Clostridium acetobutylicum</it>, a gram-positive and spore-forming anaerobe, is a major strain for the fermentative production of acetone, butanol and ethanol. But a previously isolated hyper-butanol producing strain <it>C. acetobutylicum </it>EA 2018 does not produce spores and has greater capability of solvent production, especially for butanol, than the type strain <it>C. acetobutylicum </it>ATCC 824.</p> <p>Results</p> <p>Complete genome of <it>C. acetobutylicum </it>EA 2018 was sequenced using Roche 454 pyrosequencing. Genomic comparison with ATCC 824 identified many variations which may contribute to the hyper-butanol producing characteristics in the EA 2018 strain, including a total of 46 deletion sites and 26 insertion sites. In addition, transcriptomic profiling of gene expression in EA 2018 relative to that of ATCC824 revealed expression-level changes of several key genes related to solvent formation. For example, <it>spo0A </it>and <it>adhEII </it>have higher expression level, and most of the acid formation related genes have lower expression level in EA 2018. Interestingly, the results also showed that the variation in CEA_G2622 (CAC2613 in ATCC 824), a putative transcriptional regulator involved in xylose utilization, might accelerate utilization of substrate xylose.</p> <p>Conclusions</p> <p>Comparative analysis of <it>C. acetobutylicum </it>hyper-butanol producing strain EA 2018 and type strain ATCC 824 at both genomic and transcriptomic levels, for the first time, provides molecular-level understanding of non-sporulation, higher solvent production and enhanced xylose utilization in the mutant EA 2018. The information could be valuable for further genetic modification of <it>C. acetobutylicum </it>for more effective butanol production.</p

Global Changes in Staphylococcus aureus Gene Expression in Human Blood

Staphylococcus aureus is a leading cause of bloodstream infections worldwide. In the United States, many of these infections are caused by a strain known as USA300. Although progress has been made, our understanding of the S. aureus molecules that promote survival in human blood and ultimately facilitate metastases is incomplete. To that end, we analyzed the USA300 transcriptome during culture in human blood, human serum, and trypticase soy broth (TSB), a standard laboratory culture media. Notably, genes encoding several cytolytic toxins were up-regulated in human blood over time, and hlgA, hlgB, and hlgC (encoding gamma-hemolysin subunits HlgA, HlgB, and HlgC) were among the most highly up-regulated genes at all time points. Compared to culture supernatants from a wild-type USA300 strain (LAC), those derived from an isogenic hlgABC-deletion strain (LACΔhlgABC) had significantly reduced capacity to form pores in human neutrophils and ultimately cause neutrophil lysis. Moreover, LACΔhlgABC had modestly reduced ability to cause mortality in a mouse bacteremia model. On the other hand, wild-type and LACΔhlgABC strains caused virtually identical abscesses in a mouse skin infection model, and bacterial survival and neutrophil lysis after phagocytosis in vitro was similar between these strains. Comparison of the cytolytic capacity of culture supernatants from wild-type and isogenic deletion strains lacking hlgABC, lukS/F-PV (encoding PVL), and/or lukDE revealed functional redundancy among two-component leukotoxins in vitro. These findings, along with a requirement of specific growth conditions for leukotoxin expression, may explain the apparent limited contribution of any single two-component leukotoxin to USA300 immune evasion and virulence

Comparative Genome Analysis of Filamentous Fungi Reveals Gene Family Expansions Associated with Fungal Pathogenesis

Fungi and oomycetes are the causal agents of many of the most serious diseases of plants. Here we report a detailed comparative analysis of the genome sequences of thirty-six species of fungi and oomycetes, including seven plant pathogenic species, that aims to explore the common genetic features associated with plant disease-causing species. The predicted translational products of each genome have been clustered into groups of potential orthologues using Markov Chain Clustering and the data integrated into the e-Fungi object-oriented data warehouse (http://www.e-fungi.org.uk/). Analysis of the species distribution of members of these clusters has identified proteins that are specific to filamentous fungal species and a group of proteins found only in plant pathogens. By comparing the gene inventories of filamentous, ascomycetous phytopathogenic and free-living species of fungi, we have identified a set of gene families that appear to have expanded during the evolution of phytopathogens and may therefore serve important roles in plant disease. We have also characterised the predicted set of secreted proteins encoded by each genome and identified a set of protein families which are significantly over-represented in the secretomes of plant pathogenic fungi, including putative effector proteins that might perturb host cell biology during plant infection. The results demonstrate the potential of comparative genome analysis for exploring the evolution of eukaryotic microbial pathogenesis

Genes Involved in the Degradation of Ether Fuels by Bacteria of the Mycobacterium/Rhodococcus Group

A cluster of genes encoding a cytochrome P-450 monooxygenase system involved in the utilisation of ethyl tert-butyl ether (ETBE) was cloned in Rhodococcus ruber IFP 2001. This cluster includes ethR, a putative regulator gene of the araC/xylS family; ethA, encoding a ferredoxin reductase; ethB, encoding a cytochrome P-450, ethC, encoding a ferredoxin; and ethD, which is required for the function of the monooxygenase system, but whose exact role is unknown. The ethRABCD cluster is flanked on either side by two identical copies of a class II transposon, which explains that it is lost at high frequency by homologous recombination when the strain is grown under non selective conditions. Two other, highly conserved clusters of eth genes were detected in the ETBE-utilizing strains Rhodococcus zopfii IFP 2005 and Mycobacterium sp. IFP 2009. In all cases, the eth locus is inserted in a different genomic context, suggesting that it may be transferred horizontally between different species and inserted at different sites in the genome. In addition, in R. zopfii IFP 2005, the downstream copy of the transposon carries a 117-bp (base pairs) deletion; in Mycobacterium sp. IFP 2009, the upstream copy is absent and the downstream copy is inserted 2771 bp closer to the ethRABCD cluster

Genes Involved in the Degradation of Ether Fuels by Bacteria of the Mycobacterium/Rhodococcus Group

International audienceA cluster of genes encoding a cytochrome P-450 monooxygenase system involved in the utilisation of ethyl tert-butyl ether (ETBE) was cloned in Rhodococcus ruber IFP 2001. This cluster includes ethR, a putative regulator gene of the araC/xylS family; ethA, encoding a ferredoxin reductase; ethB, encoding a cytochrome P-450, ethC, encoding a ferredoxin; and ethD, which is required for the function of the monooxygenase system, but whose exact role is unknown. The ethRABCD cluster is flanked on either side by two identical copies of a class II transposon, which explains that it is lost at high frequency by homologous recombination when the strain is grown under non selective conditions. Two other, highly conserved clusters of eth genes were detected in the ETBE-utilizing strains Rhodococcus zopfii IFP 2005 and Mycobacterium sp. IFP 2009. In all cases, the eth locus is inserted in a different genomic context, suggesting that it may be transferred horizontally between different species and inserted at different sites in the genome. In addition, in R. zopfii IFP 2005, the downstream copy of the transposon carries a 117-bp (base pairs) deletion; in Mycobacterium sp. IFP 2009, the upstream copy is absent and the downstream copy is inserted 2771 bp closer to the ethRABCD cluster

Identification of a histidyl residue in the active-center of endoglucanase-D from Clostridium-ihermocellum

Diethylpyrocarbonate modification of endoglucanase D from Clostridium thermocellum, cloned in Escherichia coli, resulted in a rapid but partial (maximally 70-80%) loss of activity. The second-order rate constant of inactivation proved to be exceptionally high (3210 M-1 . min-1). A 3-fold reduction of the k(cat) and a 2-fold increase of the K(m) for 2'-chloro-4'-nitrophenyl beta-cellobioside were observed. Spectrophotometric analysis indicate the presence of one rapidly (k = 0.45 min-1) and two slower (k = 0.23 min-1) reacting histidyl residues. In the presence of 50 mM methyl beta-cellotrioside, the rate of inactivation was reduced 16-fold, and the kinetics of modification were compatible with the protection of 1 histidyl residue. Since peptide analysis was inconclusive, identification of the critical residue was attempted by site-directed mutagenesis. Each of the 12 histidyl residues present in the endoglucanase D sequence was mutated into either Ala or Ser. Seven of the mutant enzymes had specific activities lower than 50% of the wild-type. Only in the case of the Ser-516 mutant, however, was the residual activity not affected by diethyl pyrocarbonate. These findings suggest an important functional or structural role for His-516 in the wild-type enzyme

Calcium-binding affinity and calcium-enhanced activity of Clostridium thermocellum endoglucanase D.

Clostridium thermocellum endoglucanase D (EC 3.2.1.4: EGD), which is encoded by the celD gene, was found to bind Ca2+ with an association constant of 2.03 x 10(6) M-1. Ca2+ stimulated the activity of EGD towards swollen Avicel by 2-fold. In the presence of Ca2+, the Kd of the enzyme towards p-nitrophenyl-beta-D-cellobioside and carboxymethylcellulose was decreased by 4-fold. Furthermore, Ca2+ increased the half-life of the enzyme at 75 degrees C from 13 to 47 min. Since the 3' sequence of celD encodes a duplicated region sharing similarities with the Ca2+-binding site of several Ca2+-binding proteins, a deleted clone was constructed and used to purify a truncated form of the enzyme which no longer contained the duplicated region. The truncated enzyme was very similar to EGD expressed from the intact gene with respect to activity, Ca2(+)-binding kinetics and Ca2+ effects on substrate binding and thermostability. Thus the latter parameters do not appear to be mediated through the duplicated conserved region