Some effects of mannitol on the glucose metabolism of two derivatives of a strain ofRhizobium japonicum differing in mannitol dehydrogenase

The effects of mannitol were investigated by comparing some metabolic features in colonial derivatives, I-110 and L1-110, ofRhizobium japonicum strain 3IIb110, grown either on glucose alone (G-cells) or in glucose media supplemented with mannitol (GM-cells). The polyol stimulated the synthesis of not only mannitol dehydrogenase, which is active in derivative L1-110, but also the nicotinamide adenine dinucleotide (NAD)-linked 6-phosphogluconate (6-PG) dehydrogenase (EC 1.1.1.43). As revealed by radiorespirometry, when GM-cells were allowed to metabolize glucose, they produced relatively more CO₂ from the first and sixth carbons of the sugar than G-cells did. This finding is evidence that NAD-linked 6-PG dehydrogenase might initiate an unknown pathway different from the hexose cycle and the pentose phosphate (PP) pathway. Mannitol exerted no allosteric control on the oxygen consumption and the glucose transport systems. Active uptake of the polyol was correlated with the presence of mannitol dehydrogenase (EC 1.1.1.67); it did not hinder the transport of glucose even though both systems derive their energy for active transport from a common source presumptively characterized as the energized membrane state. Mannitol, however, suppressed by two- or threefold the glucose uptake system. Addition of the polyol to the cell suspensions of both colonial types ofR. japonicum metabolizing glucose caused an immediate 40–50% drop of adenosine triphosphate (ATP) concentrations, owing in part to the mannitol kinase reaction. Type I-110 failed to overcome this reduction of ATP levels, and low growth rates could results. In contrast, type L1-110 offsets the reduction of ATP concentration by oxidizing mannitol as an additional source of energy through mannitol dehydrogenase, fructokinase, and a sequence of glycolytic reactions. The polyol also induced type L1-110 to produce extracellular slimy materials that, apparently, harbor amounts of ATP and proteins.     

Site of production of an oviposition-deterring pheromone component in Rhagoletis pomonella flies

Using behavioural and electrophysiological assay techniques, we identified the posterior half of the midgut as being a principal site of production of a major component of the oviposition-deterring, fruit-marking pheromone of female Rhagoletis pomonella flies. Following secretion into, and accumulation in, the gut lumen, this component is released, together with other gut contents, in the marking trail deposited during dragging of the ovipositor on the fruit surface after egg-laying, as well as in the faeces. Other components of the pheromone may be produced elsewhere.     

Simultaneous analysis of substrates,products, and inhibitors of xanthine oxidase by high-pressure liquid chromatography and gas chromatography

Procedures are presented for the simultaneous analysis of hypoxanthine, xanthine, allopurinol, oxipurinol, and uric acid in standard mixtures and physiological fluids using gas chromatography (gc) or high-pressure liquid chromatography (hplc). Excellent correlation was obtained between the two methods for hypoxanthine, xanthine, oxipurinol, and uric acid. There are advantages and disadvantages to both methods. hplc requires no prior derivatization, uses isocratic elution with a buffer containing no organic solvent, and has 50- to 100-fold greater sensitivity than gc. Simpler methods of prepurification, readily adapted to clinical laboratories, can be used for hplc analysis. Although substances that are found in some urine samples from cancer patients interfere with hplc, separations by gc are not affected by these substances.     

Evolution of haplodiploidy: Models for inbred and outbred systems

Several new models are proposed for the evolution of haplodiploidy. Each of these models is evaluated for its ability to explain (1) special problems associated with transition to haplodiploidy from a population of diplodiploid progenitors, (2) current patterns of population structure in haplodiploid and related species, and (3) the evolution of genetic systems similar but not identical to haplodiploid systems. Of the new models, three are based on special conditions associated with inbreeding. Close inbreeding provides for the automatic effects of reduced problems in expressing recessives, lowered differences in gain from heterozygosity (to produce both heterotic effects and a greater variety of offspring) between haploid and diploid males, effective protection of haploids from direct competition with diploids, and a mechanism for the spread of haplodiploidy through gains derived from increased ability to control sex ratio. These models differ in the context where gain from sex ratio control is expressed. Pathways for the evolution of haplodiploidy in outbreeding populations are also discussed. Females who parthenogenetically produce haploid males have high genetic relatedness to their sons. If the sperm of these males is used to make both sons and daughters, i.e., through matings with diplodiploid females, there may be a net gain for haplodiploids. Another outbreeding model, modified from S. W. Brown (1964, Genetics49, 797–817), deals with selection for females producing haploid males in populations where there are driving sex chromosomes. Biases created by drive in sex ratio may allow haplodiploid females to be the only effective producers of males in the population. Several of the new models explain the whole range of haplodiploid and related adaptations and provide predictions that appear to be more consistent with the known structure of contemporary populations than those available in current models.     

Oxidative demethylation of t-butyl alcohol by rat liver microsomes

Tertiary butyl alcohol has often been used experimentally as a “non-metabolizable” alcohol. In this report, evidence is presented that t-butanol serves as a substrate for rat liver microsomes and that it is oxidatively demethylated to yield formaldehyde. The apparent K_m for t-butanol is 30 mM while V_max is about 5.5 nmol per min per mg microsomal protein. Formaldehyde production is stimulated by azide, which prevents destruction of H₂O₂ by catalase. Hydroxyl radical scavenging agents, such as benzoate, mannitol, and 2-keto-4-thiomethylbutyrate, suppress formaldehyde production. Therefore, the microsomal reaction pathway appears to involve the interaction of t-butanol with hydroxyl radicals generated from H₂O₂ by the microsomes. Formaldehyde is also produced when t-butanol is incubated with model hydroxyl radical-generating systems such as the iron-EDTA-stimulated oxidation of xanthine by xanthine oxidase or the iron-EDTA-catalyzed autoxidation of ascorbate. These results indicate that t-butanol cannot be used to distinguish metabolically-linked from non-metabolically-linked actions of ethanol.     

Cross-reactivity between human and murine lymphocyte antigens

The anti-H-2 alloantiserum D-32 [(BlO.A(2R) × C3H.SW) anti-C3H] is cytolytic to human lymphocytes. Fab₂ blocking assays, indirect immunoprecipitation and sequential immunoprecipitation experiments showed that the anti-H-2 alloantiserum D-32 recognizes antigenic determinants which are expressed on the heavy chain of subpopulations of HLA-A, B antigens. These determinants are different from those defining the serological polymorphism of the HLA-A, B, C system, are the same as or spatially close to those recognized by the anti-HLA-A, B monoclonal antibody Q6/64 and are expressed on rabbit, rat or guinea pig lymphocytes.