Cupriavidus metallidurans biomineralization ability and its application as a bioconsolidation enhancer for ornamental marble stone.

Bacterially induced calcium carbonate precipitation of a Cupriavidus metallidurans isolate was investigated to develop an environmentally friendly method for restoration and preservation of ornamental stones. Biomineralization performance was carried out in a growth medium via a Design of Experiments (DoE) approach using, as design factors, the temperature, growth medium concentration, and inoculum concentration. The optimum conditions were determined with the aid of consecutive experiments based on response surface methodology (RSM) and were successfully validated thereafter. Statistical analysis can be utilized as a tool for screening bacterial bioprecipitation as it considerably reduced the experimental time and effort needed for bacterial evaluation. Analytical methods provided an insight to the biomineral characteristics, and sonication tests proved that our isolate could create a solid new layer of vaterite on marble substrate withstanding sonication forces. C. metallidurans ACA-DC 4073 provided a compact vaterite layer on the marble substrate with morphological characteristics that assisted in its differentiation. The latter proved valuable during spraying minimum amount of inoculated media on marble substrate under conditions close to an in situ application. A sufficient and clearly distinguishable layer was identified.

Gilthead sea bream (Sparus auratus) and European sea bass (Dicentrarchus labrax) expressed sequence tags: Characterization, tissue-specific expression and gene markers.

The gilthead sea bream, Sparus auratus, and the European sea bass, Dicentrarchus labrax, are two of the most important marine species cultivated in Southern Europe. This study aimed at increasing genomic resources for the two species and produced and annotated two sets of 30,000 expressed sequence tags (EST) each from 14 normalized tissue-specific cDNA libraries from sea bream and sea bass. Clustering and assembly of the ESTs formed 5268 contigs and 12,928 singletons for sea bream and 4573 contigs and 13,143 singletons for sea bass, representing 18,196 and 17,716 putative unigenes, respectively. Assuming a similar number of genes in sea bass, sea bream and in the model fish Gasterosteus aculeatus genomes, it was estimated that approximately two thirds of the sea bream and the sea bass transcriptomes were covered by the unigene collections. BLAST sequence similarity searches (using a cut off of e-value <10(-5)) against fully the curated SwissProt (and TrEMBL) databases produced matches of 28%(37%) and 43%(53%) of the sea bream and sea bass unigene datasets respectively, allowing some putative designation of function. A comparative approach is described using human Ensembl peptide ID homolog's for functional annotation, which increased the number of unigenes with GO terms assigned and resulted in more GO terms assigned per unigene. This allowed the identification of tissue-specific genes using enrichment analysis for GO pathways and protein domains. The comparative annotation approach represents a good strategy for transferring more relevant biological information from highly studied species to genomic resource poorer species. It was possible to confirm by interspecies mRNA-to-genomic alignments 25 and 21 alternative splice events in sea bream and sea bass genes, respectively. Even using normalized cDNA from relatively few pooled individuals it was possible to identify 1145 SNPs and 1748 microsatellites loci for genetic marker development. The EST data are being applied to a range of projects, including the development microarrays, genetic and radiation hybrid maps and QTL genome scans. This highlights the important role of ESTs for generating genetic and genomic resources of aquaculture species.