2,3-butanediol production by acetogenic bacteria, an alternative route to chemical synthesis, using industrial waste gas.

2,3-Butanediol (23BD) is a high-value chemical usually produced petrochemically but which can also be synthesized by some bacteria. To date, the best microbial 23BD production rates have been observed using pathogenic bacteria in fermentation systems that depend on sugars as the carbon and energy sources for product synthesis. Here we present evidence of 23BD production by three nonpathogenic acetogenic Clostridium species-Clostridium autoethanogenum, C. ljungdahlii, and C. ragsdalei-using carbon monoxide-containing industrial waste gases or syngas as the sole source of carbon and energy. Through an analysis of the C. ljungdahlii genome, the complete pathway from carbon monoxide to 23BD has been proposed. Homologues of the genes involved in this pathway were also confirmed for the other two species investigated. A gene expression study demonstrates a correlation between mRNA accumulation from 23BD biosynthetic genes and the onset of 23BD production, while a broader expression study of Wood-Ljungdahl pathway genes provides a transcription-level view of one of the oldest existing biochemical pathways.

Two novel Venturia inaequalis genes induced upon morphogenetic differentiation during infection and in vitro growth on cellophane.

Venturia inaequalis is a hemibiotrophic ascomycete that causes apple scab. Germ tubes, from conidia or ascospores, penetrate the leaf or fruit surface directly via appressoria-like swellings; subsequently the hyphae divide laterally to form a stroma between the cuticle and the outer wall of the epidermal cells. This morphological switch can be mimicked by growing the fungus in vitro on cellophane discs. The aim of this work was to identify genes upregulated in planta using growth on cellophane as a model. Four cDNA clones were found to be induced by growth on cellophane, and qRT-PCR showed two of these genes were up-regulated over a thousand fold in infected apple leaves compared to liquid culture. The predicted proteins for both genes possess putative signal peptides for secretion but have no similarity to sequences in publicly available databases. Both genes encode proteins with novel, imperfect repeat domain structures, the number of which vary in an isolate-specific fashion. Cin1 has seven or eight repeats of about 60 amino acids with four conserved cysteine residues per repeat, while Cin3 has four or five repeats of 32 amino acids with no cysteines. Both proteins appear to have evolved through internal duplication. Cin3, in particular, shows considerable between-strain variation in domain structure, indicating a high degree of recombination at this locus and revealing that the repeat structure has most likely arisen by unequal crossing-over. Results of this study support the hypothesis that cellophane-grown V. inaequalis mimics aspects of biotrophic infection and provide the first insights into novel fungal genes expressed during apple scab infection and their mechanisms of evolution.