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Query: UNIPROT:Q9UIJ5 (
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In the accompanying article, we established that in the rat distal colon expression of H, B, and Le(b) blood group antigens by goblet cells is phenotypically fetal in nature. Because of the cocarcinogenic property of ethanol, the present study examined the effects of dietary ethanol consumption, fasting, and withdrawal on the expression of these antigens in the adult rat colon. To that effect, male adult Sprague-Dawley rats were pair-fed ethanol-containing or control Lieber-DeCarli liquid diets for 3 weeks. The effects of ethanol withdrawal were studied in rats fed the ethanol-containing diet for 3 weeks followed by the control diet for 1, 3, and 6 days. In rats fed the control diet, no antigen expression in the distal colon was observed, as expected.
Ethanol
feeding for 3 weeks resulted in a striking reappearance of H, B, and Le(b) antigens in goblet cells of the distal colon. In colonic crypts, a lower-to-upper crypt gradient of increasing numbers of positive goblet cells was present, suggesting that the induction of antigen expression paralleled the differentiation of goblet cells. After an overnight fast, the number of positive cells was significantly decreased. Withdrawal of ethanol for 1 day further decreased the number of positive goblet cells. The decrease was reflected by a downward shift in the number of positive cells per crypt column, which was more striking in the lower and mid-crypt segments than in the upper segment, suggesting that antigen expression was more labile in immature differentiating goblet cells than in mature ones. No antigen staining of goblet cells was detected after 3 and 6 days of ethanol withdrawal. Hence, expression of H, B, and Le(b) antigens by goblet cells of the distal colon can be modulated by ethanol consumption. Expression in the distal colon of A and Le(a) antigens, which did not exhibit a fetal phenotype, was not affected by ethanol feeding. In conclusion, because of the oncofetal phenotype of H, B, and Le(b) antigens, their reappearance in the distal colon may serve as a cytochemical marker for early recognition of epithelial changes of the colon in ethanol-related cocarcinogenesis before more overt manifestations of neoplasia.
Anat
Rec
2000 08 01
PMID:Blood group antigen expression in the rat colon II. Modulation by dietary ethanol consumption. 1090 32
We have studied microbial secondary metabolism in a simulated microgravity (SMG) environment provided by NASA rotating-wall bioreactors (RWBs). These reactors were designed to simulate some aspects of actual microgravity that occur in space. Growth and product formation were observed in SMG in all cases studied, i.e., Bacillus brevis produced gramicidin S (GS), Streptomyces clavuligerus made beta-lactam antibiotics, Streptomyces hygroscopicus produced rapamycin, and Escherichia coli produced microcin B17 (MccB17). Of these processes, only GS production was unaffected by SMG; production of the other three products was inhibited. This was determined by comparison with performance in an RWB positioned in a different mode to provide a normal gravity (NG) environment. Carbon source repression by glycerol of the GS process, as observed in shaken flasks, was not observed in the RWBs, whether operated in the SMG or NG mode. The same phenomenon occurred in the case of MccB17 production, with respect to glucose repression. Thus, the negative effects of carbon source on GS and beta-lactam formation are presumably dependent on shear, turbulence, and/or vessel geometry, but not on gravity. Stimulatory effects of phosphate and the precursor L-lysine on beta-lactam antibiotic production, as observed in flasks, also occurred in SMG. An almost complete shift in the localization of produced MccB17 from cells to extracellular medium was observed when E. coli was grown in the RWB under SMG or NG. If a plastic bead was placed in the RWB, accumulation became cellular, as it is in shaken flasks, indicating that sheer stress favors a cellular location. In the case of rapamycin, the same type of shift was observed, but it was less dramatic, i.e., growth in the RWB under SMG shifted the distribution of produced rapamycin from 2/3 cellular:1/3 extracellular to 1/3 cellular:2/3 extracellular. Stress has been shown to induce or promote secondary metabolism in a number of other microbial systems. RWBs provide a low stress SMG environment, which, however, supports only poor production of MccB17, as compared to production in shaken flasks. We wondered whether the poor production in RWBs under SMG is due to the low level of stress, and whether increasing stress in the RWBs would raise the amount of MccB17 formed. We found that increasing shear stress by adding a single Teflon bead to the RWB improved MccB17 production. Although shear stress seems to have a marked positive effect on MccB17 production in SMG, addition of various concentrations of ethanol to RWBs (or to shaken flasks) failed to increase MccB17 production.
Ethanol
stress merely decreased production and, at higher concentrations, inhibited growth. Interestingly, cells growing in the RWB were much more resistant to the growth- and production-inhibitory effects of ethanol than cells growing in shaken flasks. With respect to S. hygroscopicus, addition of Teflon beads to the RWB reversed the inhibition of growth, but rapamycin production was still markedly inhibited, and the distribution did not revert back to a preferential cellular site.
Chem
Rec
2001
PMID:Secondary metabolism in simulated microgravity. 1189 73
IOGEN Corporation of Ottawa, Canada, has recently built a 40t/d biomass-to-ethanol demonstration plant adjacent to its enzyme production facility. It has partnered with the University of Toronto to test the C6/C5 cofermenta-tion performance characteristics of the National Renewable Energy Labora-tory's metabolically engineered Zymomonas mobilis using various biomass hydrolysates. IOGEN's feedstocks are primarily agricultural wastes such as corn stover and wheat straw. Integrated recombinant Z. mobilis strain AX101 grows on D-xylose and/or L-arabinose as the sole carbon/energy sources and ferments these pentose sugars to ethanol in high yield. Strain AX101 lacks the tetracycline resistance gene that was a common feature of other recombinant Zm constructs. Genomic integration provides reliable cofermentation performance in the absence of antibiotics, another characteristic making strain AX101 attractive for industrial cellulosic ethanol production. In this work, IOGEN's biomass hydrolysate was simulated by a pure sugar medium containing 6% (w/v) glucose, 3% xylose, and 0.35% arabinose. At a level of 3 g/L (dry solids), corn steep liquor with inorganic nitrogen (0.8 g/L of ammonium chloride or 1.2 g/L of diammonium phosphate) was a cost-effective nutritional supplement. In the absence of acetic acid, the maximum volumetric ethanol productivity of a continuous fermentation at pH 5.0 was 3.54 g/L x h. During prolonged continuous fermentation, the efficiency of sugar-to-ethanol conversion (based on total sugar load) was maintained at >85%. At a level of 0.25% (w/v) acetic acid, the productivity decreased to 1.17 g/L x h at pH 5.5. Unlike integrated, xylose-utilizing
rec
Zm strain C25, strain AX101 produces less lactic acid as byproduct, owing to the fact that the Escherichia coli arabinose genes are inserted into a region of the host chromosome tentatively assigned to the gene for D-lactic acid dehydrogenase. In pH-controlled batch fermentations with sugar mixtures, the order of sugar exhaustion from the medium was glucose followed by xylose and arabinose. Both the total sugar load and the sugar ratio were shown to be important determinants for efficient cofermentation.
Ethanol
at a level of 3% (w/v) was implicated as both inhibitory to pentose fermentation and as a potentiator of acetic acid inhibition of pentose fermentation at pH 5.5. The effect of ethanol may have been underestimated in other assessments of acetic acid sensitivity. This work underscores the importance of employing similar assay conditions in making comparative assessments of biocatalyst fermentation performance.
...
PMID:Performance testing of Zymomonas mobilis metabolically engineered for cofermentation of glucose, xylose, and arabinose. 1201 70
