Pancreatic carboxylester lipase from Atlantic salmon (Salmo salar). cDNA sequence and computer-assisted modelling of tertiary structure.

We report the isolation and characterization of a 1795-bp cDNA fragment encoding Atlantic salmon pancreatic carboxylester lipase from salmon pancreas mRNA. The nearly full-length cDNA contained a 540-amino-acid open-reading frame, encompassing the mature protein (by similarity to mammalian carboxylester lipase enzymes). The salmon carboxylester lipase primary structure shared 58% identity with mammalian carboxylester lipases, lacking the proline-rich C-terminal repeats found in human and rat carboxylester lipases. Congruent with other esterase B type enzymes, the salmon carboxylester lipase contained a canonical serine-esterase catalytic triad motif consisting of serine, histidine and aspartic acid. Computer-assisted modelling of the tertiary structure for salmon carboxylester lipase was conducted using acetylcholine esterase (Torpedo californica) as a template structure. The model, in conjunction with sequence comparisons and available enzymological data, has been used to locate putative bile-salt-binding and lipid-binding sites. The carboxylester lipase enzymes contain a unique, highly conserved insert region that may be associated with bile-salt binding. In the model structure, this region is located close to the active site, and contains a tyrosine residue with an adjacent carboxylester-lipase-conserved arginine. These traits have previously been predicted for the non-specific (regarding bile-salt hydroxylation) bile-salt-binding site in carboxylester lipase enzymes. At this site, a dihydroxy or trihydroxy bile-salt molecule may bind the tyrosine via hydrophobic interactions, the anionic bile-salt head group may bind the arginine, while hydrogen bonding between the bile-salt 12 alpha hydroxy group and an adjacent aspargine residue is possible. The model does not contain an active site 'lid' structure as found in other lipases. The carboxylester lipase structural homolog to the 'flap' of the lipases from Geotrichum candidum and Candida rugosa contains a carboxylester-lipase-conserved deletion that renders this region unable to cover the active site. Instead, the shortening of this loop leads to solvent exposure of the carboxylester lipase insert region, an additional indication of the functional importance of this region.

[Electrolyte solution with polyethylene glycol to cleanse the colon for colonoscopy or enema]. / Solución electrolítica con polietilenglicol en la limpieza colónica para colonoscopia o colon por enema.

The efficacy and safety of an electrolyte-polyethylene glycol solution (SE-PEG) for colonic lavage, was compared with standard bowel preparation (SBP) in a randomized blinded study of volunteers and patients undergoing colonoscopy and barium enema examination. Side effects, biochemical and hematologic changes and quality of examinations were monitored. Colonoscopy and barium enema was scored by colonic segment for type of residual stool and percentage of bowel wall visualized. For colonoscopy and barium enema, preparation with SE-PEG allowed better visualization and produced more optimal exams (8 vs 3; p less than 0.03) and (6 vs 4; p = NS) respectively. We conclude that colonic lavage with SE-PEG is an alternative bowel preparation method and is cheaper, more safe and effective than SBP procedure.

Growth support and toxicity of homocysteine and its effects on methionine metabolism in non-transformed and chemically transformed C3H/10T1/2 cells.

The effects of homocysteine (Hcy) on one non-transformed (Cl 8) and two malignant clones (Cl 16 and Cl T422) of the C3H/10T1/2 mouse embryo fibroblasts, were examined with regard to toxicity, ability to support growth and effects on methionine (Met) metabolism and glutathione level. Homocysteine in its reduced form (Hcy-SH) was toxic to all cell lines, and the LD90 was estimated to be 1.0 X 10(-4) M for Cl 8 and Cl 16 cells measured by plating efficiency, 0.8 X 10(-4) M for Cl 8 and 0.3 X 10(-4) M for Cl 16 when measured by total cell growth. At toxic concentrations, Hcy-SH showed a drastic effect on cell morphology both in the presence and absence of Met. The same effect was demonstrated with L-cysteine. No toxic effect was seen with homocystine (Hcy-SS-Hcy) or homocysteine thiolactone (Hcy-tl) at similar concentrations. Hcy-tl supported growth of both the non-transformed and malignant cells in Met-deficient medium but with decreasing efficiency in the order Cl 8, Cl 16 and Cl T422. The growth rate constant compared to that of Met-supplemented medium was 0.62 for Cl 8, 0.44 for Cl 16 and 0.38 for Cl T422 cells. The intracellular level of S-adenosylhomocysteine (AdoHcy) increased in all three cell lines in Hcy-tl-supplemented medium. The S-adenosylmethionine (AdoMet) content increased in Cl 8 cells, was constant in Cl 16 cells and decreased in Cl T422 cells under the same conditions. This resulted in a constant ratio of AdoMet/AdoHcy in the non-transformed cells (Cl 8) whereas this ratio decreased by 40% in Cl 16 and by 72% in Cl T422 cells when Hcy-tl replaced Met in the medium. The ability of Hcy-tl to support growth thus seemed to correlate well with alteration in Met metabolism in this cell culture system. The intracellular level of glutathione (GSH) was measured during exponential growth, but showed small variations between non-transformed cells and Cl 16 cells. However, Cl T422 cells showed a distinct lower level of GSH in Met-supplemented medium, and this increased 3- to 4-fold when Met was replaced with Hcy-tl.