Use of phlorizin binding to demonstrate induction of intestinal glucose transporters

Summary We used specific binding of phlorizin to the intact intestinal mucosa in order to measure glucose transport site density in intestines of mice fed a high-carbohydrate or no-carbohydrate diet. Nonspecific binding varied with intestinal position but showed only modest dependence on diet. Specific binding to glucose transporters was 1.9 times greater in jejunum of high-carbohydrate mice than of no-carbohydrate mice; this ratio was the same as the ratio for V_max values of actived-glucose uptake between the two diet groups. The gradient in specific binding of phlorizin along the intestine paralleled the gradient in V_max of glucose transport. These results directly demonstrate that the increase in intestinal glucose transport caused by a high-carbohydrate diet is due to induction of glucose transporter. They also indicate that the normal positional graident in glucose transport along the intestine arises from a gradient in transporters, induced by the normal gradient in luminal glucose concentration.     

Glycosylation defects alter insulin but not insulin-like growth factor I binding to Chinese hamster ovary cells

Insulin binding to two Chinese hamster ovary cell lines with well-defined defects in their glycosylation pathway has been characterized and compared to insulin-like growth factor I (IGF-I) binding in the same cell lines. Insulin competition curves indicate that B4-2-1 cells, which transfer co-translationally to proteins an endoglycosidase H insensitive, truncated lipid-linked oligosaccharide, bind insulin with higher than normal affinity. Lec 1 cells, which fail to process oligosaccharide side chains to complex types, bind with a reduced affinity. The potencies of chicken and guinea pig insulins are appropriate for an insulin receptor in the control (WTB) and both mutant cell lines, whereas rat IGF-II is 3 times more potent than expected in the Lec 1 cells and human IGF-I is less potent than anticipated. Insulin bound to Lec 1 cells dissociates more quickly upon dilution than does insulin bound to either WTB or B4-2-1 cells. The Lec 1 insulin receptor is insensitive to pH change, whereas the other lines show the usual optimum of 8. 125I-IGF-I binds well to all three cell lines and is equally pH-sensitive in all three. Serum from a patient with circulating autoantibodies to the insulin receptor competes for insulin but not IGF-I binding, whereas alpha IR3, a monoclonal antibody directed toward the human IGF-I receptor inhibits IGF-I but not insulin binding. Cross-linking of either 125I-insulin or 125I-IGF-I reveals a typical alpha-subunit in the WTB and B4-2-1 cells but a band with faster mobility in the Lec 1 cells. Insulin (10(-8) M) stimulates autophosphorylation of a beta-subunit in all three lines, but again the Lec 1 subunit demonstrates an anomalous mobility on sodium dodecyl sulfate-polyacrylamide gel electrophoresis. These data demonstrate the differential effect of glycosylation on two closely related receptor molecules.     

DNA damage and repair in embryonic mouse limbs exposed to teratogenic doses of methylnitrosourea

The alkaline elution assay was used to monitor DNA single-strand breaks in embryonic tissue following exposure to the DNA-damaging teratogen N-methyl-N-nitrosourea (MNU, CAS No. 694-93-5). An animal model was developed in which nearly every fetus exposed to the highest dose of MNU had malformations of the hindlimbs while the fetuses exposed to the lowest dose of MNU had none. Hindlimbs pooled within litters were analyzed for DNA single-strand breaks by alkaline elution conducted at rapid (0.35 ml/min) and slow (0.35 ml/min) speeds. Breaks in the DNA of hindlimbs exposed to teratogenic doses of MNU were readily detected by alkaline elution only if slower speeds were used in the assay. Using the more sensitive procedure, DNA breakage was monitored over a 24-h period. DNA breakage peaked in the MNU-exposed hindlimbs in a dose-dependent manner 4 h after injection. While the elution profiles of hindlimbs exposed to the lower doses of MNU returned to control levels 8 h after injection, single-strand breaks persisted in the hindlimbs exposed to the highest dose of MNU for at least 20 h. These latter data suggest that the highly teratogenic dose of MNU induced DNA damage that was more slowly repaired than that produced at lower doses, possibly by saturation of DNA repair systems. Although some necrosis did occur in hindlimbs exposed at teratogenic dose levels, it was not severe and it did not appear to influence the alkaline elution results. These experiments show that alkaline elution is a sensitive assay for the detection of DNA damage in embryonic tissues.     

Interaction of sodium molybdate with highly purified glucocorticoid receptor

Sodium molybdate can affect the properties of the glucocorticoid receptor in relatively crude preparations. To obtain more information as to whether these effects are due to direct interactions of the ion with the receptor or with other components present in the receptor-containing mixtures, the effects were examined of sodium molybdate on glucocorticoid receptors purified 3000-5000-fold to about 10% homogeneity from rat liver cytosol. The ion was found to: (1) increase the stability of the purified receptor at either 0 or 20 degrees C, although the effect was more pronounced at 20 degrees C (2) induce an apparent dimerization of the receptors as judged by sephadex G-150 gel filtration and sucrose density gradient sedimentation and (3) decrease the ionic strength required for elution of the purified receptor from DEAE-cellulose columns. Although, it is conceivable that each of these observed effects is due to indirect actions of the ion on contaminants in the preparations, it is more likely that the ion exerts its effects through direct interactions with the receptor.     

How do food passage rate and assimilation differ between herbivorous lizards and nonruminant mammals?

Summary What digestive adaptations permit herbivorous nonruminant mammals to sustain much higher metabolic rates than herbivorous lizards, despite gross similarity in digestive anatomy and physiology? We approached this question by comparing four herbivorous species eating the same diet of alfalfa pellets: two lizards (chuckwalla and desert iugana) and two mammals (desert woodrat and laboratory mouse). The mammals had longer small and large intestines, greater intestinal surface area, much higher (by an order of magnitude) food intake normalized to metabolic live mass, and much faster food passage times (a few hours instead of a few days). Among both reptiles and mammals, passage times increase with body size and are longer for herbivores than for carnivores. The herbivorous lizards, despite these much slower passage times, had slightly lower apparent digestive efficiencies than the mammals. At least for chuckwallas, this difference from mammals was not due to differences in body temperature regime. Comparisons of chuckwallas and woodrats in their assimilation of various dietary components showed that the woodrat's main advantage lay in greater assimilation of the dietary fiber fraction. Woodrats achieved greater fiber digestion despite shorter residence time, but possibly because of a larger fermentation chamber, coprophagy, and/or different conditions for microbial fermentation. We conclude with a comparative overview of digestive function in herbivorous lizards and mammals, and with a list of four major unsolved questions.     

Fine structure of cytoplasmic inclusions of some methylotrophic bacteria from plant surfaces

Five strains of pink-pigmented, facultatively methylotrophic bacteria (PPFM) isolated from plant surfaces and grown in different carbon sources, were fixed, embedded and sectioned for examination with the electron microscope. The strains studied represented the two mainsub-groups, those that can use carbohydrates and those that can not use carbohydrates as a sole carbon and energy source. All of the isolates examined, produced crystalloid inclusions, internal membranous vesicles and internal membranous sheets although the number of cells with inclusions, varied with the carbon source and specific strain. Polybetahydroxybutyrate and polyphosphate bodies were observed in all strains, with all carbon sources used for growing cells which includes methanol, formate and glycerol. Isolates that could use glucose accumulated polyglucoside granules but not when other carbon sources were provided. The relationship of these inclusions to growth conditions is discussed.     

Stimulatory effect of gamma-aminobutyric acid upon animo acid incorporation into protein by a ribosomal system from immature rat brain

Abstract—

• 1 GABAstimulated the incorporation of L-[U-¹⁴C]leucine, primarily into the particulate protein of a ribosomal system from immature rat brain, but not from immature rat liver.
• 2 The GABA effect required the presence of Na⁺ and occurred at GABA concentrations which are thought to be physiological (1–5 mM).
• 3 Of all other amino acids tested at tissue extract concentrations in the system, only glycine had a similar effect. No analogues of GABA tested had a significant stimulatory effect upon leucine incorporation into protein, with the exception of homocarnosine which was mildly stimulatory.
• 4 The effect of GABA upon the incorporation of L-[U-¹⁴C]leucine was examined in the presence of added amino acid substrates, both individually and as mixtures. Also, the incorporation of L-[U-¹⁴C]leucine was compared with incorporation of L-[U-¹⁴C]Iysine and L-[U-¹⁴C]phenylalanine. The results are discussed in terms of GABA interaction with activating, transfer and transport mechanisms of other amino acids, inhibition of proteinase activity, and the possibility that GABA is stimulating the synthesis or turnover of specific proteins in the brain ribosomal system.
• 5 The results illustrate the fact that studies of ‘protein synthesis’ in immature rat brain ribosomes, as measured by amino acid incorporation, will yield answers which depend heavily upon substrate conditions and upon the labelled amino acid used as the marker for protein synthesis or turnover.

     

Contributions of unstirred-layer effects to apparent electrokinetic phenomena in the gall-bladder

Summary Passage of electric current across rabbit gall-bladder, which is preferentially permeable to cations, causes water flow towards the negative electrode, as expected for electroosmosis in a cation-selective membrane. Current passage also causes development of a polarization potential difference, i.e. a transepithelial potential difference (p.d.) which transiently remains after cessation of current flow and decays back to zero with a half-time of 22 to 90 sec. The polarization p.d. is due to current-induced local changes of salt concentration in unstirred layers, mainly at the serosal face of the epithelium. These changes originate through the so-called transport-number effect. Calculation shows that much of the observed current-induced water flow represents an osmotic flow due to these local concentration changes, rather than representing true electroosmosis. By implication, a large component of streaming potentials in the gall-bladder is a boundary diffusion potential, owing to water flow producing local changes of salt concentration in unstirred layers.