Effect of sterol metabolism in the yeast-Drosophila system on the frequency of radiation-induced aneuploidy in Drosophila melanogaster oocytes

The influence of sterol metabolism upon mutagenesis in Drosophila melanogaster was investigated using ecological-genetic yeast - drosophila system. Sterol deficiency in the organism of Drosophila was caused by using the strain of Saccharomyces cerevisiae 9-2P712 with a mutation in the nysr1 locus which blocks synthesis of ergosterol as a nutrition substrate for flies. It was concluded that maintenance of females on the mutant yeast strain causes an increase of radiation-induced X-chromosome loss in mature oocytes. Resistance of oocytes to X-ray irradiation is restored, reaching the control level, when 0,1% cholesterol solution in 10% ethanol is added to the yeast biomass. The possible membrane and hormonal mechanisms of elevation of induced aneuploidy and the role of sterol metabolism in ensuring resistance of insects to damaging factors are discussed.     

Pyridine nucleotide metabolism in imaginal discs of Drosophila melanogaster

The pyridine nucleotide metabolism of imaginal discs of Drosophila melanogaster has been studied in vitro by incubating discs with labeled nicotinic acid in the presence and absence of ecdysterone. The major labeled compounds found within the discs are NAD, NADP, and nicotinic acid. There is preferential uptake of nicotinamide over nicotinic acid, although the Priess-Handler pathway is used exclusively. The presence of ecdysterone produces a small increase in the NADP/NAD ratio, and an increase in NAD synthesis, probably to compensate for increased NAD turnover.Supported by Grant GB 43569 from the National Science Foundation.     

Effect of sterol composition on the activity of the yeast G-protein-coupled receptor Ste2

The main sterol of the human cell membrane is cholesterol, whereas in yeast it is ergosterol. In this study, we constructed a cholesterol-producing yeast strain by disrupting the genes related to ergosterol synthesis and inserting the genes related to cholesterol synthesis. The total sterols of the mutant yeast were extracted and the sterol composition was analyzed by GC-MS. We confirmed that cholesterol was produced instead of ergosterol in yeast and subsequently examined the activity of the yeast G-protein-coupled receptor (GPCR) Ste2p. Ste2p signaling was assessed in wild type (WT) with ergosterol and the cholesterol-producing yeast instead of ergosterol to determine whether sterol composition affects the activity of the yeast GPCR. Our results demonstrated that Ste2p could transduce a signal even in the cholesterol-rich membrane, but the maximum signal intensity was weaker than that transduced in the ergosterol-rich original (WT) membrane. This result indicates that sterol composition affects the activity of yeast GPCRs, and thus, this provides new insight into GPCR-mediated transduction using yeast for future fundamental and applied studies on GPCRs from yeast to other organisms.     

Effect of ecdysterone contact period on development of wing disks of the fleshfly, Sarcophaga peregrina, in vitro

The ecdysterone contact period required for pupal development of Sarcophaga wing disks was studied in vitro. When the disks were cultured in a medium with 1 × 10^?6 M ecdysterone for about 21 hr, evagination of wing disks occurred independent of a later transfer into a hormone-free medium. The contact period required for wing evagination was dependent on the concentration of ecdysterone.When the disks cultured in the ecdysterone-containing medium were subjected to an intervening ecdysterone-free condition, evagination of the wing occurred if the period of the hormone contact before and after the ecdysterone-free period totalled a certain length. The total period required for wing evagination was altered both by the duration of the intervening hormone-free culture and duration of the first culture with ecdysterone.The morphogenetic effect of ecdysterone is discussed in relation to RNA synthesis in vitro.     

DO MALES MATTER? TESTING THE EFFECTS OF MALE GENETIC BACKGROUND ON FEMALE MEIOTIC CROSSOVER RATES IN DROSOPHILA MELANOGASTER

Meiotic recombination is a critical genetic process as well as a pivotal evolutionary force. Rates of crossing over are highly variable within and between species, due to both genetic and environmental factors. Early studies in Drosophila implicated female genetic background as a major determinant of crossover rate and recent work has highlighted male genetic background as a possible mediator as well. Our study employed classical genetics to address how female and male genetic backgrounds individually and jointly affect crossover rates. We measured rates of crossing over in a 33 cM region of the Drosophila melanogaster X chromosome using a two‐step crossing scheme exploiting visible markers. In total, we measured crossover rates of 10 inbred lines in a full diallel cross. Our experimental design facilitates measuring the contributions of female genetic background, male genetic background, and female by male genetic background interaction effects on rates of crossing over in females. Our results indicate that although female genetic background significantly affects female meiotic crossover rates in Drosophila, male genetic background and the interaction of female and male genetic backgrounds have no significant effect. These findings thus suggest that male‐mediated effects are unlikely to contribute greatly to variation in recombination rates in natural populations of Drosophila.     

Genetico-ecological aspects of the use of nystatin-resistant yeast mutants in the yeast-Drosophila system

Nystatin-resistant strains of Saccharomyces cerevisiae with mutations in final steps of ergosterol biosynthesis have been studied in the ecologo-genetic yeast--drosophila system. It has been shown that yeast strains which belong to the Petersghoff genetic yeast stock collection, with mutations in NYSX, NYS2 and NYS3 genes, provide the development of Drosophila melanogaster. In the process of nutrition with yeasts having mutations in the NYS2 gene, the development of drosophila larvae takes place, due to ergosterol accumulated in the yeast cells. Drosophila melanogaster was shown to be unable to utilize the sterols with 8(9) and 24(25) double bonds.     

Ecdysterone selectively stimulates the expression of a 23000-Da heat-shock protein-beta-galactosidase hybrid gene in cultured Drosophila cells

To study the regulated expression of cloned heat-shock genes in homologous cells, hybrid Drosophila heat-shock-Escherichia coli beta-galactosidase genes were constructed. Segments of the ecdysterone-inducible 23,000-Da heat-shock protein (hsp23) gene and of two other hsp genes (hsp84 and 70), which are not hormone regulated, were functionally linked to the bacterial coding sequence, and the resulting hybrid genes were introduced into cultured, hormone-responsive Drosophila cells by transfection. All hybrid genes directed the synthesis of E. coli-specific beta-galactosidase in heat-treated cells. hsp23 hybrid gene expression was stimulated strongly by ecdysterone, while the activities of the other hybrid genes were not affected at all by the hormone. A hybrid gene with only 147 bp of hsp23 promoter sequence could not be activated by either heat or ecdysterone treatment. Thus, far upstream sequences contain signals required for the regulated expression of the hsp23 gene in Drosophila cells.     

Ecdysterone induced protein synthesis in salivary glands and in fat body of Drosophila melanogaster larvae

Salivary glands of 3rd instar larvae of Drosophila melanogaster were labeled with ³H-leucine in the presence and absence of ecdysterone. Twentysix ecdysterone inducible proteins were detected. Their induction was correlated with puff stage. Synthesis of fifteen proteins commenced during early puff stage (PS2); synthesis of seven others at late puff stages (PS8–10). Synthesis of four proteins was induced between puff stage 3/4 and 7/8. Thus, the hormonal induction of protein synthesis generally reflected the appearance of early and of late puffs as described by Ashburner (1972). Eleven ecdysterone inducible proteins were detected in larval fat body in vitro. Comparison of the fat body to the salivary gland proteins revealed that one of the ecdysterone induced fat body proteins was identical in molecular weight and charge to one of the proteins induced by ecdysterone in salivary glands.     

Termination of vitellogenin synthesis by mosquito fat body, a programmed response to ecdysterone

ABSTRACT. In the blood-fed mosquito, peak vitellogenin synthesis occurs 24–32 h after the meal, dropping to resting levels by 40 h. Challenging fat body with ecdysterone in vitro at various times after a blood meal demonstrated a refractory period at about 50 h, when there was also a drastic decrease in mitochondria, rough endoplasmic reticulum, ribosomes, and glycogen in fat body cells. When fat bodies from sugar-fed females were incubated with continuous ecdysterone in vitro , vitellogenin synthesis reached a peak at 30 h, but then declined even in the presence of ecdysteroné. This was not due to the in vitro conditions since fat bodies were responsive, even if first exposed to ecdysterone, after 80 h in vitro. If ecdysterone was removed, vitellogenin synthesis ceased. If it was replaced, the fat body responded again only if the initial removal was done during the first 30 h. It is proposed that the falling ecdysterone titre is the major cause of cessation of vitellogenin synthesis, but that synthesis is programmed to decline even if exposure to ecdysterone is abnormally prolonged.     

Initiation of anaerobic growth of Saccharomyces cerevisiae by amino acids or nucleic acid bases: ergosterol and unsaturated fatty acids cannot replace oxygen in minimal media

Nine out of ten industrially important strains of Saccharomyces cerevisiae did not grow in minimal media under anaerobic conditions even when ergosterol and unsaturated fatty acids were provided. Anaerobiosis was maintained either by flushing the culture flasks with prepurified nitrogen or by incubating the flasks in an anaerobic chamber. Traces of oxygen present in ‘prepurified nitrogen gas’ were sufficient to initiate yeast growth and on removal of the oxygen by catalytic means the yeasts failed to grow. The yeast grew very well anaerobically if the medium was supplemented with a mixture of amino acids or with a mixture of purines and pyrimidines. The growth initiated by including a mixture of amino acids was further enhanced when the medium was supplemented with ergosterol and an unsaturated fatty acid. Since no oxygen requirement for the synthesis of amino acids or purines and pyrimidines has been demonstrated, growth promotion by these compounds under anaerobic conditions is most likely not by eliminating the need for oxygen for their synthesis. We suggest that the amino acids and the nucleic acid bases yielded, through some hitherto unknown reactions, small amounts of a molecular or usable form of oxygen which allowed key reactions essential for ‘anaerobic’ growth to proceed. Received 16 July 1998/ Accepted in revised form 8 October 1998     

Actin gene expression is modulated by ecdysterone in a Drosophila cell line

The steroid hormone ecdysterone induced characteristic and specific changes of morphology, enzymatic activities and protein synthesis in a Kc 0% Drosophila melanogaster cell line. To study the ecdysterone action at a molecular level, a Drosophila genomic library was screened by differential hybridization to poly(A)+ RNA from control and ecdysterone-treated cells. Two recombinant phages were selected for hybridizing very intensively with poly(A)+ RNA of ecdysterone-treated cells and very weakly with poly(A)+ RNA of untreated ones. These two clones (lambda Dm 1632 and lambda Dm A5A1) mapped at the 5 C locus on polytene chromosomes; they overlap for a 9000 base-pair sequence that contains an abundantly transcribed region in ecdysterone-treated cells of about 2000 base-pairs. This region permits the selection of mRNA that gives, after translation in vitro, two polypeptides identified as cytoplasmic actin II and III. We demonstrated that these two recombinant phages, hybridizing preferentially with poly(A)+ RNA of ecdysterone-treated cells, contain the 5 C actin gene. Poly(A)+ RNA prepared from various times of treatment of cells were electrophoresed on agarose gels, transferred to nitrocellulose paper and then hybridized with the cloned actin probe. Results of these experiments indicate that there is a sharp increase in the level of RNA coding for actin after ecdysterone treatment of the cell, and that there are two forms of actin-specific RNA in the D. melanogaster cells. Using genomic blots with specific probes derived from lambda Dm 1632, we show that there are six actin genes per haploid Drosophila cell genome contained on six EcoRI fragments, as in Drosophila embryos, indicating that there is no rearrangement of these sequences in cultured cells. Our results suggest that the expression of actin genes in D. melanogaster Kc 0% cells is modulated by ecdysterone.     

Ecdysterone induction of actin synthesis and polymerization in a Drosophila melanogaster cultured cell line

Actin pools have been evaluated in Drosophila melanogaster Kc 0% cells, through an actin assay based on differential inhibition of DNase I by globular (G) and filamentous (F) actin. Total actin represents about 4 % of total proteins and 54 % is G-actin. In ecdysterone treated cells (0.1 μM), the total actin content increases up to 9 % of total proteins after 3 days of treatment. Ecdysterone induces increase of G-actin as well as F-actin. Increase of both actins, detectable after only 24 hrs of treatment, is roughly parallel during the first two days of treatment. For longer hormonal treatment, actin polymerization is more important than accumulation of G-actin. Indirect immunofluorescence microscopy with antibodies to exogeneous DNase I suggests that actin is widely distributed in the whole cytoplasm before and after ecdysterone treatment. These results suggest that ecdysterone induces actin synthesis and polymerization in Drosophila melanogaster cells.     

The effect of ecdysterone and juvenile hormones on protein synthesis and development of imaginal wing discs ofDrosophila melanogaster

The effect of ecdysterone and juvenile hormone on protein synthesis and development of imaginal wing discs ofDrosophila melanogaster has been studied. It is found that juvenile hormone apparently does not inhibit the synthesis of the ecdysterone-inducible proteins, although wing disc development is inhibited to various extent by different juvenile hormones. It is suggested that the ecdysterone-inducible proteins are not involved directly in the initiation of wing disc evagination, it is possible that some of these proteins are involved in the maintenance of chromatin activities or they are involved in gene activation.     

Fine measurement of ergosterol requirements for growth of Saccharomyces cerevisiae during alcoholic fermentation

Yeasts can incorporate a wide variety of exogenous sterols under strict anaerobiosis. Yeasts normally require oxygen for growth when exogenous sterols are limiting, as this favours the synthesis of lipids (sterols and unsaturated fatty acids). Although much is known about the oxygen requirements of yeasts during anaerobic growth, little is known about their exact sterol requirements in such conditions. We developed a method to determine the amount of ergosterol required for the growth of several yeast strains. We found that pre-cultured yeast strains all contained similar amounts of stored sterols, but exhibited different ergosterol assimilation efficiencies in enological conditions [as measured by the ergosterol concentration required to sustain half the number of generations attributed to ergosterol assimilation (P₅₀)]. P₅₀ was correlated with the intensity of sterol synthesis. Active dry yeasts (ADYs) contained less stored sterols than their pre-cultured counterparts and displayed very different ergosterol assimilation efficiencies. We showed that five different batches of the same industrial Saccharomyces cerevisiae ADY exhibited significantly different ergosterol requirements for growth. These differences were mainly attributed to differences in initial sterol reserves. The method described here can therefore be used to quantify indirectly the sterol synthesis abilities of yeast strains and to estimate the size of sterol reserves.     

Effect on the fertility of female Drosophila of sterol metabolism in an ecological-genetic yeast-Drosophila system

The consequences of sterol deficiency in feeding of adult Drosophila females have been studied. Feeding of Drosophila on nys 1 mutant strain yeast leads to significant increase of non-developed eggs in Drosophila females. The effect of sterol deficiency on oogenesis in virgin and fertilized females has been estimated using different regimens of feeding. Possible mechanisms of arising of fertility defects are discussed.     

Small heat shock proteins in Drosophila may confer thermal tolerance

The four small heat shock proteins in Drosophila melanogaster are genetically linked and simultaneously synthesized, both in response to high temperature and, developmentally, during puparium formation. In tissue culture cells their synthesis is inducible by the molting hormone, ecdysterone. We show here that accompanying their induction and accumulation, the cells and animals acquire thermal tolerance.     

Effect of nitrogen limitation on the ergosterol production by fed-batch culture of Saccharomyces cerevisiae

The diversity and content of available nitrogen sources in the growth medium both are very important in the accumulation of ergosterol in the yeast cell membrane. Growth on the good nitrogen sources such as ammonia can harvest more yeast cells than on poor ones, but ergosterol content in those yeast cells is relatively lower. Ergosterol content, one of the most variable parameters in ergosterol production by yeast cultivation, is greatly influenced by nitrogen limitation. The aim of our work was to study how the nitrogen sources affected the membrane ergosterol content and increase the total ergosterol yield. On the premise of keeping high ergosterol content in yeast cell, the ergosterol yield was enhanced by increasing the yeast biomass. Direct feed back control of glucose using an on-line ethanol concentration monitor was introduced to achieve high cell density. Ammonia, which acted as nitrogen source, was added to adjust pH during fermentation process, but its addition needed careful control. Cultivation in 5 L bioreactor was carried out under following conditions: culture temperature 30+/-1 degrees C, pH 5.5+/-0.1, agitation speed 600 rpm, controlling ethanol concentration below 1% and controlling ammonium ion concentration below 0.1 mol/L. Under these conditions the yeast dry weight reached 95.0+/-2.6 g/L and the ergosterol yield reached 1981+/-34 mg/L.     

Production of lycopene by the food yeast, Candida utilis that does not naturally synthesize carotenoid

The Erwinia uredovora crtE, crtB, and crtI genes, which are responsible for the synthesis of carotenoid lycopene from farnesyl pyrophosphate, were expressed in Candida utilis under the control of the promoters and terminators derived from the C. utilis GAP, PGK, and PMA genes, respectively. The yeast transformant carrying the carotenoid biosynthesis genes produced 758 microg/g dry weight of lycopene along with 407 microg/g dry weight of phytoene in the stationary phase. It was observed in the C. utilis transformant that ergosterol content was decreased to 65% of that in the parent strain that accumulated 6.04 mg/g dry weight of ergosterol. It is therefore possible that the carbon flux for the ergosterol biosynthesis has been branched at farnesyl pyrophosphate to generate a new pathway for the lycopene production in this yeast transformant.