Intracellular pH regulation in a nonmalignant and a derived malignant human breast cell line

Tumor cells in vivo often exist in an ischemic microenvironment that would compromise the growth of normal cells. To minimize intracellular acidification under these conditions, these cells are thought to upregulate H(+) transport mechanisms and/or slow the rate at which metabolic processes generate intracellular protons. Proton extrusion has been compared under identical conditions in two closely related human breast cell lines: nonmalignant but immortalized HMT-3522/S1 and malignant HMT-3522/T4-2 cells derived from them. Only the latter were capable of tumor formation in host animals or long-term growth in a low-pH medium designed to mimic conditions in many solid tumors. However, detailed study of the dynamics of proton extrusion in the two cell lines revealed no significant differences. Thus, even though the ability to upregulate proton extrusion in a low pH environment (pH(e)) may be important for cell survival in a tumor, this ability is not acquired along with the capacity to form solid tumors and is not unique to the transformed cell. This conclusion was based on fluorescence measurements of intracellular pH (pH(i)) on cells that were plated on extracellular matrix, allowing them to remain adherent to proteins to which they had become attached 24 to 48 h earlier. Proton translocation under conditions of low pH(e) was observed by monitoring pH(i) after exposing cells to an acute acidification of the surrounding medium. Proton translocation at normal pH(e) was measured by monitoring the recovery after introduction of an intracellular proton load by treatment with ammonium chloride. Even in the presence of inhibitors of the three major mechanisms of proton translocation (sodium-proton antiport, bicarbonate transport, and proton-lactate symport) together with acidification of their medium, cells showed only about 0.4 units of reduction in pH(i). This was attributed to a slowing of metabolic proton generation because the inhibitors were shown to be effective when the same cells were given an intracellular acidification.     

The sucrase-isomaltase structural gene (Si-s) and a regulatory gene (Si-r) are closely linked to esterase-26 (Es-26) on mouse Chromosome 3

A cDNA clone of the rat sucrase-isomaltase (SI) structural gene detected two distinct patterns of DNA fragments on Southern blots of mouse DNA. Screening of 18 AKXL and 25 AKXD recombinant inbred (RI) strains revealed that all bands in each pattern co-segregated and there were no (0/43) recombinants with Es-26 on mouse Chromosome (Chr) 3. Since CBA/CaJ mice have approximately threefold less sucrase activity than other strains, we intercrossed them with SJL/J mice to map the previously identified SI regulatory gene, Si-r. Fifty-six mice from the F₂ generation were assayed for sucrase activity, and the genotype of the murine SI structural gene locus, Si-s, was determined by Southern blot analysis. Nine animals (16%) were homozygous for the CBA/CaJ allele (C) and had an average sucrase activity (jejunum + ileum) of 1.51 moles/h/mg protein (SE=0.067), 19 (34%) were homozygous for the SJL/J allele (S) and had an average sucrase activity of 5.95 moles/h/mg protein (SE=0.267), and 28 (50%) were heterozygous (C/S) for Si-s with an average sucrase activity of 3.70 moles/h/mg protein (SE=0.127). We conclude that Si-s and Si-r are closely linked on Chr. 3.     

Grazing by rotifers and crustacean zooplankton on nanoplanktonic protists

Predation on nanoflagellates by metazoan zooplankton was investigated using a radioactively labeled flagellate, Poterioochromonas malhamensis, as a tracer cell in laboratory incubations of freshly collected plankton assemblages. Experiments conducted in the fall, winter and spring indicated that rotifers dominated the grazing on nanoflagellates by metazoans in the winter (68%) and spring (92%). Rotifer grazing was not determined in the autumn. It is likely that the greater impact of rotifer grazing in the spring was due to the occurrence of abundant filamentous cyanobacteria and gelatinous colonial phytoplankton which selectively depressed feeding rates of crustaceans compared to rotifers. Crustacean predation on nanoflagellates was highest in the autumn when cladocerans (primarily Daphnia spp.) were abundant. Predation by metazoan zooplankton in this lake appeared capable of removing the total standing stock of heterotrophic and phototrophic nanoplankton in < 1 d. Impacts of ciliated protozoa on nanoplankton, calculated from abundances and literature feeding rates, ranged from approximately one-third to four times that of metazoan predation depending on season and method of calculation. The relative importance of the different groups of predators appears to vary seasonally which is expected to alter the transfer of energy, carbon and nutrients from bacteria to higher trophic levels.     

Production and characterization of a monoclonal antibody able to discriminate galectin-1 from galectin-2 and galectin-3

Antisera raised against galectin-1 exhibit crossreactivities with other galectins or related molecules. In order to overcome this problem, a monoclonal antibody to human brain galectin-1 was obtained by selecting clones without reactivity toward galectin-3. This mAb specifically bound galectin-1 of various animal origins but neither galectin-2 nor galectin-3. Western-blotting analysis of soluble human brain extracts after 2D gel electrophoresis revealed only the two most acidic isoforms of galectin-1. The ability of this mAb to bind galectin-1/asialofetuin complexes indicates that its epitope is not localized in the carbohydrate recognition domain of galectin-1. This particularity induces with efficiency its monospecificity.      

Blue Light Overrides Repression of Asexual Sporulation by Mating Type Genes in the Basidiomycete Coprinus cinereus

Monokaryotic mycelia of the homobasidiomycete Coprinus cinereus form asexual spores (oidia) constitutively in abundant numbers. Mycelia with mutations in both mating type loci (Amut Bmut homokaryons) also produce copious oidia but only when exposed to blue light. We used such an Amut Bmut homokaryon to define environmental and inherent factors that influence the light-induced oidiation process. We show that the Amut function causes repression of oidiation in the dark and that light overrides this effect. Similarly, compatible genes from different haplotypes of the A mating type locus repress sporulation in the dark and not in the light. Compatible products of the B mating type locus reduce the outcome of light on A-mediated repression but the mutated B function present in the Amut Bmut homokaryons is not effective. In dikaryons, the coordinated regulation of asexual sporulation by compatible A and B mating type genes results in moderate oidia production in light. Copyright 1998 Academic Press.     

125I-UdR Induced Division Delay

The interaction of Ca++ with acidic phospholipids in black lipid films and lipid bilayers formed from two monolayers was studied by measuring their physical stability and conductance. It was found that the addition of CaCl2 to only one side of lipid bilayers formed from phosphatidylserine or cardiolipin does not appreciably change these parameters. In contrast, black films are unstable to the asymmetric addition of CaCl2. Therefore, the destabilizing effect of Ca++ cannot be attributed to a surface charge difference. The only variation in composition between both bilayer membranes, namely the solvent content of the bilayer, seems to be responsible for the distinctive effect of Ca++. A tentative explanation is presented.     

Stereoisomers of tetrahydrothiamin pyrophosphate, potent inhibitors of the pyruvate dehydrogenase multienzyme complex from Escherichia coli

Tetrahydrothiamin pyrophosphate, an analogue of thiamin pyrophosphate (TPP) in which the thiazolium ring has been reduced to a thiazolidine ring, was prepared by borohydride reduction of TPP. It consists of four stereoisomers, comprising two diastereomers each of which is a racemic mixture, generated by the introduction of two chiral centers on the thiazolidine ring. The major and minor diastereomers were separated and inferred to be of the cis and trans configurations, respectively, from a study of the nuclear Overhauser effects in the 1H NMR spectrum of the simpler tetrahydrothiamin. Tetrahydro-TPP behaves as a mixture of potent inhibitors of the pyruvate decarboxylase (E1) component of the pyruvate dehydrogenase complex from Escherichia coli. The site of binding is probably the TPP-binding site on E1, and the Kd for each of the four stereoisomers was estimated. The cis isomers of tetrahydro-TPP bind more tightly than does TPP, whereas the trans isomers appear to bind with about the same Kd as TPP. Sodium borohydride caused a rapid inhibition of E1 activity in the presence of TPP, believed to be due to reaction of borohydride with enzyme-bound TPP. The experiments are consistent with an enhancement of the reactivity of the thiazole ring of TPP when bound to the catalytic site of E1, which could be due to polarization of the greater than +N=C bond near a hydrophobic or positively charged region of the protein. A spontaneous reactivation occurred after the initial inhibition by borohydride, attributable to a weakly binding inhibitor, not tetrahydro-TPP, being formed at the catalytic site.     

Hydroxyurea retards the progression of G2 cells

Continuous treatment of monolayer cultures of Chinese hamster ovary (CHO) cells with 1.0 mM HU reduced the rate at which G2 cells entered mitosis. Although all cells in G2+M at the start of treatment eventually entered mitosis, early G2 cells, which were exposed to HU the longest, entered mitosis 45 min later than untreated G2 cells. This perturbation of G2 progression should be considered when employing HU as a synchronizing agent in mammalian cell populations.