Large-scale analysis of the genome of the rare alkaline-halophilic Stachybotrys microspora reveals 46 cellulase genes.

Fungi are of great importance in biotechnology, for example in the production of enzymes and metabolites. The main goal of this study was to obtain a high-coverage draft of the Stachybotrys microspora genome and to annotate and analyze the genome sequence data. The rare fungus S. microspora N1 strain is distinguished by its ability to grow in an alkaline halophilic environment and to efficiently secrete cellulolytic enzymes. Here we report the draft genome sequence composed of 3715 contigs, a genome size of 35 343 854 bp, with a GC content of 53.31% and a coverage around 20.5×. The identification of cellulolytic genes and of their corresponding functions was carried out through analysis and annotation of the whole genome sequence. Forty-six cellulases were identified using the fungicompanion bioinformatic tool. Interestingly, an S. microspora endoglucanase selected from those with a low isoelectric point was predicted to have a halophilic profile and share significant homology with a well-known bacterial halophilic cellulase. These results confirm previous biochemical studies revealing a halophilic character, which is a very rare feature among fungal cellulases. All these properties suggest that cellulases of S. microspora may have potential for use in the biofuel, textile, and detergent industries.

Safety assessment of fish oil green extraction and in vivo acute toxicity evaluation.

Sardine co-products can represent an interesting source of bioactive compounds, such as polyunsaturated fatty acids and in particular omega-3. This study aimed to investigate extraction of oil from sardine co-products by enzymatic hydrolysis using two proteases: commercial Alcalase and protease Bb from a local fungal strain (P2) of Beauveria bassiana, which overproduces proteases. Despite a higher degree of hydrolysis (41.34%) than Alcalase (24.28%), protease Bb allowed the extraction of approximately the same oil content. Resulting oil from both processes had the same fatty acid profile. Interestingly, the all-produced oil displayed an attractive w6/w3 ratio, an indicator of nutritional quality, of the order of 0.16. The safety of the generated oils was also assessed by treating two groups of Wistar rats with the fish oil administered by oral gavage at the doses (30 mg/kg and 300 mg/kg body weight) for 14 days using olive oil as a vehicle. Compared to controls used, both treated groups showed no statistically significant differences. Consequently, the acute oral toxicity evaluated by hematological, biochemical, and histological studies showed the safety of the oil generated using B. bassiana protease.

Molecular and bioinformatics analyses reveal two differentially expressed intracellular GH1 ß-glucosidases from the rare alkalophilic fungus Stachybotrys microspora.

The present study reports the isolation and analysis of two novel GH1 ß-glucosidases from the alkalophilic fungus Stachybotrys microspora, using PCR and Nested-PCR. Three major gene fragments were obtained by PCR: the first two are very similar and constitute a novel gene, which was named Smbgl1A, and the third PCR fragment is part of a different gene, named Smbgl1B. The truncated gene sequences were completely filled using the recent partial whole genome sequencing data of S. microspora (data not yet published). Moreover, we investigated the relative effects of glucose in comparison to cellulose rather than evaluate their absolute effects. In fact, RT-PCR analysis showed that while Smbgl1A was expressed when the fungus was grown in the presence of cellulose but not when grown with glucose, Smbgl1B was equally expressed under both conditions. The putative catalytic residues and the conserved glycone binding sites were identified. Zymogram analysis showed the intracellular production of ß-glucosidases in S. microspora. The predicted secondary structure exhibited a classical (ß/α)8 barrel fold, showing that both SmBGL1A and SmBGL1B belong to the GH1 family. Phylogenetic studies showed that SmBGL1A and SmBGL1B belong to the same branch as ß-glucosidases from Stachybotrys chlorohalonata and Stachybotrys chartarum. However, SmBGL1A and SmBGL1B form two distinct clades.

Investigations on a hyper-proteolytic mutant of Beauveria bassiana: broad substrate specificity and high biotechnological potential of a serine protease.

A new strain of Beauveria bassiana was identified on the basis of the 18S rRNA gene sequence homology. This strain, called P2, is a spontaneously arisen mutant that was isolated after successive sub-culturing the wild-type B. bassiana P1 strain. P2 showed hyper-production of extracellular protease(s) as much as ninefold more than P1. An extracellular protease (SBP) having a molecular weight of 32 kDa was purified from the P2 strain. SBP was completely inhibited by the phenyl methyl sulphonyl fluoride, which suggests that it belongs to the serine protease family. Based on the homology analysis of its N-terminal and the gene sequences, the enzyme was identified as subtilisin. The enzyme displays maximum activity at 60 °C and pH 8, and was stable at pH 6-12. The enzyme hydrolyses natural proteins such as keratin and is activated in presence of ß-mercaptoethanol and Tween detergents. SBP was compatible with some laundry detergent formulations and showed high efficacy in the removal of blood stains from cotton fabric. Moreover, it was observed to degrade the melanised feathers and to hydrolyse the gelatine from X-ray films. All these results highlight the suitability of SBP protease as a very efficient microbial bio-resource.

A spontaneous direct repeat deletion in the pGEX fusion vector decreases the expression level of recombinant proteins in Escherichia coli.

pGEX vectors are widely used for GST-fusion protein expression in Escherichia coli under the control of a strong IPTG inducible tac promoter. While using pGEX-4T-2 vector in heterologous protein expression we noticed that the GST or GST-fusion protein were expressed at a very low levels. Interestingly, we found a spontaneous deletion of 701 bp DNA fragment harbouring the tac promoter in both, native and recombinant pGEX-4T-2 vectors. This deletion took place between two direct repeats of 43 bases and led to the loss of a 701 bp DNA fragment. This explained the decrease in GST or GST-fused protein level since the tac promoter, that directs transcription was deleted. The lacZ promoter, located upstream of the deleted fragment, replaced tac promoter but was less efficient. The deleted DNA also specifies part of the lacZ gene coding for the N-terminal end of the beta-galactosidase (the alpha-peptide), which is slightly functional. Consequently, bacterial cells transformed with the original pGEX are of a faint blue colour while those bearing the deleted ones are white, when plated on X-Gal containing medium. The deletion, did not affect neither the sequence nor the molecular weight of GST and fusion protein since it took place just before the GST start codon. It occurred in E. coli TOP10 cells which are deficient in RecA protein, suggesting that the deletion did not require the RecA recombination system.