A complete chitinolytic system in the atherinopsid pike silverside Chirostoma estor: gene expression and activities.

The expression and digestive activity of pike silverside Chirostoma estor endogenous chitinases were analysed in samples from four life stages: whole eggs; larvae; juvenile intestine and hepatopancreas and adult intestine and hepatopancreas. A chitinase cDNA was cloned and partially sequenced (GenBank accession number: FJ785521). It was highly homologous to non-acidic chitinase sequences from other fish species, suggesting that it is a chitotriosidase. Quantitative PCR showed that this chitinase was expressed throughout the life span of C. estor, with maximum expression in the hepatopancreas of juveniles. Chitotriosidase and chitobiosidase activities were found at all life stages, along with a very high level of N-acetyl glucosaminidase (NAGase). The chitotriosidase activity could be encoded by the cloned complementary (c)DNA, although additional chitinase genes may be present. The chitotriosidase activity appeared to be transcriptionally regulated only at the juvenile stage. The expression and activity of chitinases tended to increase from the early to juvenile stages, suggesting that these variables are stimulated by chitin-rich live food. Nevertheless, the feeding of juvenile and adult fish with both live food and a balanced commercial diet seemed to provoke significant reductions in pancreatic NAGase secretion and/or synthesis in the gut. Moreover, all chitinase activities were lower in adults, probably reflecting a higher intake and use of the balanced diet. The observation of chitotriosidase and chitobiosidase activities together with a very high NAGase activity suggest the presence of a complete and compensatory chitinolytic chitinase system that enables this stomachless short-gut fish species to use chitin as an energy substrate. These novel findings suggest that dietary inclusions of chitin-rich ingredients or by-products might reduce the farming costs of C. estor without impairing performance.

[Respiratory oxidases: the enzymes which use most of the oxygen which living things breathe]. / Las oxidasas respiratorias: las enzimas que utilizan la mayor parte del oxígeno que los seres vivos respiran.

The respiratory oxidases are the last enzymes of the aerobic respiratory chain. They catalize the reduction of molecular oxygen to water, with generation of an electrochemical gradient useful for the energy demanding cellular processes. Most of the oxidases belong to the heme-copper superfamily. They possess a heme-copper center, constituted of a high spin heme and a CuB center, where the reduction of oxygen takes place and probably where the link to proton pumping is located. The superfamily is divided in two classes: the quinol- and the cytochrome c-oxidases. The latter are divided in the aa3 and the cbb3-type cytochrome c oxidases. The main difference between quinol- and the aa3-type cytochrome c-oxidases is the CuA center, which is absent in the quinol oxidases. The cbb3-type cytochrome oxidases have the binuclear center, but lack the CuA center. They also does not have the classical subunits II and III. These differences seem not to affect the oxygen reduction or the proton pumping. Probably the oxidases have evolved from some denitrification enzymes and prior the photosynthetic process. Also is possible that the cbb3-type cytochrome oxidases or others very similar have been the first oxidases to appear.

[P53 protein and human papillomavirus oncogenes in carcinogenesis of the uterine cervix]. / La proteína p53 y los oncogenes de papilomavirus humanos en la carcinogénesis del cuello uterino.

Human papillomavirus (HPV) DNA sequences are found in the majority (90%) of cervical tumors, and in cell lines derived from them. The products of the viral E6 and E7 oncogenes inactivate those from the p53 and Rb tumor suppressor genes. The p53 protein controls the entrance to the cell cycle. When DNA damage occurs, p53 levels are increased, resulting in cell arrest. This allows cells to repair the damage before replication occurs. Cells without p53 (either mutated or absent) will replicate their unrepaired DNA, increasing their genomic instability. In cells from cervical cancer the E6 protein will induce degradation of p53, so continuous expression of viral oncogenes will lead to genomic instability, that in turn will increase the risk of acquiring new mutations that probably contribute to cancer development.