Genetic modifications and introduction of heterologous pdc genes in Enterococcus faecalis for its use in production of bioethanol.

Genetically-modified Enterococcus faecalis has a potential of survival and can be used in ethanolic fermentations. Fermentation profiles of E. faecalis JH2-2 were assessed using glucose and lactose as carbon sources. Deletion of lactate dehydrogenase (ldh) genes increased the ethanol production from 0.25 to 0.82 g/l, which was further increased to 0.96 g/l by the insertion of a pyruvate decarboxylase (pdc) gene (from Sarcina ventriculi or Clostridium acetobutylicum) in place ldh1. When grown on lactose, the pdcSv and pdcCa showed 13.6 and 17.6 U mg(-1) of pdc specific activity, respectively. Highest activity (47 U mg(-1)) and ethanol concentration (2.3 g/l) were obtained with pdcCa using an expression plasmid. Formate and acetate were also produced in high quantities. Transcriptional analysis showed that aldehyde alcohol dehydrogenase gene was upregulated up to 16-fold. Further optimizations are required for higher ethanol production.

Identification of Geotrichum candidum at the species and strain level: proposal for a standardized protocol.

In this study, the M13 primer was used to distinguish Geotrichum candidum from the anamorphic and teleomorphic forms of other arthrospore-forming species (discriminatory power = 0.99). For intraspecific characterization, the GATA4 primer showed the highest level of discrimination for G. candidum among the 20 microsatellite primers tested. A molecular typing protocol (DNA concentration, hybridization temperature and type of PCR machine) was optimized through a series of intra- and interlaboratory trials. This protocol was validated using 75 strains of G. candidum, one strain of G. capitatum and one strain of G. fragrans, and exhibited a discrimination score of 0.87. This method could therefore be used in the agro-food industries to identify and to evaluate biodiversity and trace strains of G. candidum. The results show that the GATA4 primer might be used to differentiate strains according to their ecological niche.

Genetic diversity among Geotrichum candidum strains from various substrates studied using RAM and RAPD-PCR.

AIMS: Assessment of genetic diversity within the species Geotrichum candidum and development of tools to trace the strains that play an important role in the agro food industry. METHODS AND RESULTS: RAM-PCR and RAPD-PCR techniques were assessed for their ability to discriminate 57 strains of various morphotypes, substrates and geographical origin. The techniques were complementary and, when combined, allowed us to discriminate isolates. Moreover, we established a link between a taxon and its occupation of an ecological niche, which should not be confused with the substrate of isolation. CONCLUSIONS: We observed a high degree of diversity, which could be linked to the variety of the ecological niches chosen and to the high degree of morphological polymorphism encountered within the species. SIGNIFICANCE AND IMPACT OF THE STUDY: Used in combination, RAM-PCR and RAPD-PCR permit traceability and monitoring systems for G. candidum strains during food processing.

Ambient alkaline pH prevents maturation but not synthesis of ASPA, the aspartyl protease from Penicillium roqueforti.

Penicillium roqueforti secretes an aspartyl protease, ASPA, which represents the main extracellular proteolytic activity. Alkaline pH of the medium plays a major role by inhibiting the enzymatic activity and stopping aspA expression in the presence of casein, an inducing protein. However, casein degradation by the mature enzyme produces peptides which can induce aspA expression at acidic and alkaline pH. ASPA synthesized as a proenzyme is processed at an acidic pH but not at an alkaline pH. The data indicate that, in P. roqueforti, alkaline pH has an indirect repressive effect by inhibiting ASPA maturation and the release of inducers. At an acidic pH, the mature enzyme degrades extracellular proteins and peptides are released to induce aspA. In contrast, at an alkaline pH, the proenzyme remains inactive, the inducing substances are consequently not produced and aspA is no longer expressed.

aspS encoding an unusual aspartyl protease from Sclerotinia sclerotiorum is expressed during phytopathogenesis.

The gene aspS encoding an aspartyl protease has been cloned from Sclerotinia sclerotiorum by screening a genomic library with a PCR-amplified fragment of the gene. The open reading frame of 1368 bp interrupted by one intron would encode a preproprotein of 435 amino acids. The catalytic aspartyl residues characteristic of aspartyl proteases are conserved; however, the active-site motif (DSG) in the N-terminal lobe is unusual in that Ser replaced Thr used in the active-site motif (DTG) of the C-terminal lobe and in all other fungal aspartyl proteases. RT-PCR revealed that aspS expression in axenic culture is not subjected to catabolite repression and demonstrated that aspS is expressed from the beginning of infection of sunflower cotyledons.

Isolation and expression of a nitrogen regulatory gene, nmc, of Penicillium roqueforti.

The nmc gene, encoding a global nitrogen regulator, has been cloned and characterized from Penicillium roqueforti, a fungus used in the dairy industry. The deduced amino acid sequence predicts a protein of 860 amino acids in length whose zinc finger DNA binding domain is at least 94% identical to those of the homologous fungal proteins. Northern blot analysis showed that nmc expression is induced by nitrogen starvation and not repressed by variation of the external pH.

Controls of the expression of aspA, the aspartyl protease gene from Penicillium roqueforti.

The gene (aspA) encoding the extracellular aspartyl protease from Penicillium roqueforti was cloned and characterized. Northern hybridization analyses and beta-casein degradation assays revealed that aspA was strongly induced by casein in the medium and efficiently repressed by ammonia. External alkaline pH overrides casein induction, resulting in aspA repression. Cis-acting motifs known to mediate nitrogen and pH regulation of fungal gene expression are present in the aspA promoter and protein-DNA binding experiments showed that mycelial proteins interact with various regions of the promoter. Due to the efficient environmental controls on aspA expression, the promoter of aspA is an attractive candidate for the development of a controllable gene expression system in P. roqueforti.