Functional characterization of a cis-acting DNA antisilencer region that modulates myelin proteolipid protein gene expression

Regulation of myelin proteolipid protein (PLP:) gene expression is tightly controlled, both spatially and temporally. Previously, we have shown with transgenic mice that a PLP:-lacZ fusion gene (which includes the entire sequence for PLP: intron 1 DNA) is regulated in a similar manner to endogenous PLP: gene expression. Furthermore, by deletion-transfection analyses using assorted PLP:-lacZ constructs with partial deletion of PLP: intron 1 sequences, we have shown that the first intron possesses an antisilencer region that is capable of over-coming repression mediated by two distinct regions located elsewhere within intron 1 DNA. Here, we report the ability of various fragments encompassing the antisilencer region to restore beta-galactosidase activity when inserted into PLP:-lacZ constructs, which originally exhibited low levels of beta-galactosidase activity. Additional constructs were generated to test the effects of these antisilencer-containing fragments in constructs that are missing either one or both of the negative regulatory regions that are overridden during antisilencing. Transfection analyses, in conjunction with protein-DNA binding assays, suggest that several nuclear factors are necessary for derepression of PLP: gene activity in an oligodendroglial cell line. Moreover, either the "core" or complete antisilencing region can act in an additive or synergistic fashion when multiple copies are inserted into the Plp-lacZ constructs.     

Regulation of glucose and maltose transport in strains ofSaccharomyces

Summary Growth of yeast cells on glucose resulted in complete inactivation of maltose transport and repression of the high affinity glucose transport system. When the cells were grown on maltose or subjected to substrate starvation, an increase in glucose and maltose transport was observed in both brewing and non-brewing yeast strains. The concentration of glucose employed in the growth medium was also observed to affect sugar transport activity. The higher the glucose concentration, the more pronounced the repressive effect. In addition, the time of growth of yeast on glucose or maltose also intermining the rate of sugar transport. These results are consistent with the repressive effect of glucose on the high affinity glucose and maltose transport systems.     

Phytochrome-regulated PIL1 derepression is developmentally modulated

We define the photoresponsiveness, during seedling de-etiolation,of PHYTOCHROME-INTERACTING FACTOR 3-LIKE 1 (PIL1), initiallyidentified by microarray analysis as an early-response genethat is robustly repressed by first exposure to light. We showthat PIL1 mRNA abundance declines rapidly, with a half-timeof 15 min, to a new steady-state level, 10-fold below the initialdark level, within 45 min of first exposure to red light. Analysisof phy-null mutants indicates that multiple phytochromes, includingphyA and phyB, impose this repression. Conversely, PIL1 expressionis rapidly derepressed by subsequent far-red irradiation ofpreviously red light-exposed seedlings. However, the magnitudeof this derepression is modulated over time, in a biphasic manner,in response to increasing duration of pre-exposure to continuousred light: (i) an early phase (up to about 6 h) of relativelyrapidly increasing effectiveness of far-red reversal of repression,as declining phyA levels relieve initial very low fluence suppressionof this response; and (ii) a second phase (beyond 6 h) of graduallydeclining effectiveness of far-red reversal, to only 20% ofmaximal derepression, within 36 h of continuous red light exposure,with no evidence of circadian modulation of this responsiveness,an observation in striking contrast to a previous report forentrained, green seedlings exposed to vegetative shade. Thesedata, together with analysis of phytochrome signaling mutantsand overexpressors with aberrant de-etiolation phenotypes, suggestthat the second-phase decline in robustness of PIL1 derepressionis an indirect consequence of the global developmental transitionfrom the etiolated to the de-etiolated state, and that circadiancoupling of derepression requires entrainment.     

Regulation of lysine and dipicolinic acid biosynthesis in Bacillus brevis ATCC 10068: significance of derepression of the enzymes during the change from vegetative growth to sporulation

Lysine biosynthetic pathway enzymes of Bacillus brevis ATCC 1068 were studied as a function of stage of development (growth and sporulation). The synthesis of aspartic-2-eemialdehyde dehydrogenase (ASA-dehydrogenase), dihydrodipicolinate synthase (DHDPA-synthase), DHPA-reductase and diaminopimelate decarboxylase (DAP-decarboxylase) was found not to be co-regulated, since lysine was not a co-repressor for these enzymes. Unlike the aspartokinase isoenzymes, the other enzymes of the lysine pathway were not derepressed in thiosine-resistant, lysine-excreting mutants. Thus, the aspartokinase isoenzymes were the key enzymes during growth and regulation of lysine biosynthesis through restriction of l-ASA synthesis via feedback control by lysine on the aspartokinases was therefore suggested.In contrast to other Bacillus species, the levels of the lysine biosynthetic pathway enzymes of strain ATCC 10068 were not derepressed during the change from vegetative growth to sporulation. Two control mechanisms, enabling the observed preferential channelling of carbon for the synthesis of spore-specific diaminopimelic acid (DAP) and dipicolinic acid (DPA) were a) loss of DAP-decarboxylase, b) inhibition of DHDPA-reductase by DPA. Increase in the level of the DAP pool during sporulation, as a consequence of the loss of DAP-decarboxylase, and its relevance to the non-enzymatic formation of DPA has been discussed.Abbreviations l-ASA l-aspartic-2-semialdehyde - DAP diaminopimelic acid - DPA dipicolinic acid - DHDPA dihydrodipicolinate - AGM aspargine-glycerol medium - PY peptone-yeast extract - NB+NSM nutrient broth plus nutrient sporulation medium     

Studies on inositol-mediated expression of MAL gene encoding maltase and phospholipid biosynthesis in Schizosaccharomyces pombe

In this study, the effects of inositol addition on expression of the MAL gene encoding maltase and phosphatidylinositol (PI) biosynthesis in Schizosaccharomyces pombe (a naturally inositol-requiring strain) were examined. We found that specific maltase activity was at its maximum when the concentration of added inositol reached 6 μg ml⁻¹ in a synthetic medium containing 2.0% (w/v) glucose. When the concentration of added inositol was 1 μg ml⁻¹ in the medium, repression of MAL gene expression occurred at glucose concentration higher than 0.2% (w/v). However, when S. pombe was cultured in the synthetic medium containing 6 μg ml⁻¹, repression of maltase gene expression occurred only at initial glucose concentration above 1.0% (w/v). More mRNA encoding maltase was detected in the cells grown in the medium with 6 μg ml⁻¹ inositol than in those grown in the same medium with 1 μg ml⁻¹ inositol. These results demonstrate that higher inositol concentrations in the synthetic medium could derepress MAL gene expression in S. pombe. PI content of the yeast cells grown in the synthetic medium with 6 μg ml⁻¹ of inositol was higher than that of the yeast cells grown in the same medium with 1 μg ml⁻¹ of inositol. This means that PI may be involved in the derepression of MAL gene expression in S. pombe.     

Sugar uptake in a 2-deoxy-d-glucose resistant mutant ofSaccharomyces cerevisiae

Summary The non-metabolizable and toxic glucose analogue 2-deoxy-d-glucose (2-DOG) has been widely employed to screen for regulatory mutants which lack catabolite repression. A number of yeast mutants resistant to 2-DOG have recently been isolated in this laboratory. One such mutant, derived from aSaccharomyces cerevisiae haploid strain, was demonstrated to be derepressed for maltose, galactose and sucrose uptake. Furthermore, kinetic analysis of glucose transport suggested that the high affinity glucose transport system was also derepressed in the mutant strain. In addition, the mutant had an increased intracellular concentration of trehalose relative to the parental strain. These results indicate that the 2-DOG resistant mutant is defective in general glucose repression.     

Methanol metabolism in yeasts: Regulation of the synthesis of catabolic enzymes

The regulation of the synthesis of four dissimilatory enzymes involved in methanol metabolism, namely alcohol oxidase, formaldehyde dehydrogenase, formate dehydrogenase and catalase was investigated in the yeasts Hansenula polymorpha and Kloeckera sp. 2201. Enzyme profiles in cell-free extracts of the two organisms grown under glucose limitation at various dilution rates, suggested that the synthesis of these enzymes is controlled by derepression — represion rather than by induction — repression. Except for alcohol oxidase, the extent to which catabolite repression of the catabolic enzymes was relieved at low dilution rates was similar in both organisms. In Hansenula polymorpha the level of alcohol oxidase in the cells gradually increased with decreasing dilution rate, whilst in Kloeckera sp. 2201 derepression of alcohol oxidase synthesis was only observed at dilution rates below 0.10 h^–1 and occurred to a much smaller extent than in Hansenula polymorpha.Derepression of alcohol oxidase and catalase in cells of Hansenula polymorpha was accompanied by synthesis of peroxisomes. Moreover, peroxisomes were degraded with a concurrent loss of alcohol oxidase and catalase activities when excess glucose was introduced into the culture. This process of catabolite inactivation of peroxisomal enzymes did not affect cytoplasmic formaldehyde dehydrogenase.     

Derepression of the high-affinity phosphate uptake in the yeast Saccharomyces cerevisiae

Phosphate starvation derepresses a high-affinity phosphate uptake system in Saccharomyces cerevisiae strain A294, while in the same time the low-affinity phosphate uptake system disappears. The protein synthesis inhibitor cycloheximide prevents the derepression, but has no effect as soon as the high-affinity system is fully derepressed. Two other protein synthesis inhibitors, lomofungin and 8-hydroxyquinoline, were found to interfere also with the low-affinity system and with Rb⁺ uptake. After incubation of the yeast cells in the presence of phosphate the high-affinity system is not derepressed, but the $\text{V}{}_{\mathrm{<mtext>max</mtext>}}$ of the low-affinity system has decreased for about 35%. Phosphate supplement after derepression causes the high-affinity system to disappear to a certain extent while in the meantime the low-affinity system reappears. The results are compared with those found in the yeast Candida tropicalis for phosphate uptake.     

Utilization of sulfonic acids as the only sulfur source for growth of photosynthetic organisms

Growth on ethanesulfonic acid as the only sulfur source was found to occur in ten of the 14 green algae tested and in three of the ten cyanobacteria analyzed. Similar growth could not be demonstrated in the higher plant Lemna minor, or in tissue cultures of anise, sunflower and tobacco. Organisms growing on sulfonic acids as the only sulfur source developed an uptake system for ethanesulfonate found neither in algae growing on sulfate nor in algae unable to utilize sulfonic acids for growth. The development of sulfonate transport was not caused by substrate induction, but by conditions of sulfate starvation. The presence of this uptake system was always correlated with an increased sulfate-uptake capacity. Enhanced sulfate uptake was found in all S-deficient and sulfonate-grown cultures tested, indicating sulfate limitation as the regulatory signal. A lag period of 2–2.5 h after transfer to sulfate deprivation was needed for expression of both enhanced sulfate uptake and ethanesulfonate uptake in case of the green alga Chlorella fusca. It is speculated that the availability of sulfate (pool size) or a metabolic product in equilibrium with oxidized sulfur compounds (sulfate ester? sulfolipids?) controls sulfate and sulfonate uptake systems. The principle of (coordinated) derepression by starvation is discussed as a general strategy in photosynthetic organisms.