A bright γ-ray flare interpreted as a giant magnetar flare in NGC 253.

Soft γ-ray repeaters exhibit bursting emission in hard X-rays and soft γ-rays. During the active phase, they emit random short (milliseconds to several seconds long), hard-X-ray bursts, with peak luminosities1 of 1036 to 1043 erg per second. Occasionally, a giant flare with an energy of around 1044 to 1046 erg is emitted2. These phenomena are thought to arise from neutron stars with extremely high magnetic fields (1014 to 1015 gauss), called magnetars1,3,4. A portion of the second-long initial pulse of a giant flare in some respects mimics short γ-ray bursts5,6, which have recently been identified as resulting from the merger of two neutron stars accompanied by gravitational-wave emission7. Two γ-ray bursts, GRB 051103 and GRB 070201, have been associated with giant flares2,8-11. Here we report observations of the γ-ray burst GRB 200415A, which we localized to a 20-square-arcmin region of the starburst galaxy NGC 253, located about 3.5 million parsecs away. The burst had a sharp, millisecond-scale hard spectrum in the initial pulse, which was followed by steady fading and softening over 0.2 seconds. The energy released (roughly 1.3 × 1046 erg) is similar to that of the superflare5,12,13 from the Galactic soft γ-ray repeater SGR 1806-20 (roughly 2.3 × 1046 erg). We argue that GRB 200415A is a giant flare from a magnetar in NGC 253.

Associations of stream geomorphic conditions and prevalence of alternative reproductive tactics among sockeye salmon populations.

In many species, males may exhibit alternative life histories to circumvent the costs of intrasexual competition and female courtship. While the evolution and underlying genetic and physiological mechanisms behind alternative reproductive tactics are well studied, there has been less consideration of the ecological factors that regulate their prevalence. Here, we examine six decades of age composition records from thirty-six populations of sockeye salmon (Oncorhynchus nerka) to quantify associations between spawning habitat characteristics and the prevalence of precocious sneakers known as 'jacks'. Jack prevalence was independent of neutral genetic structure among stream populations, but varied among habitat types and as a function of continuous geomorphic characteristics. Jacks were more common in streams relative to beaches and rivers, and their prevalence was negatively associated with stream width, depth, elevation, slope and area, but positively related to bank cover. Behavioural observations showed that jacks made greater use of banks, wood and shallows than guard males, indicating that their reproductive success depends on the availability of such refuges. Our results emphasize the role of the physical habitat in shaping reproductive tactic frequencies among populations, likely through local adaptation in response to variable fitness expectations under different geomorphic conditions.

An exceptionally bright flare from SGR 1806-20 and the origins of short-duration gamma-ray bursts.

Soft-gamma-ray repeaters (SGRs) are galactic X-ray stars that emit numerous short-duration (about 0.1 s) bursts of hard X-rays during sporadic active periods. They are thought to be magnetars: strongly magnetized neutron stars with emissions powered by the dissipation of magnetic energy. Here we report the detection of a long (380 s) giant flare from SGR 1806-20, which was much more luminous than any previous transient event observed in our Galaxy. (In the first 0.2 s, the flare released as much energy as the Sun radiates in a quarter of a million years.) Its power can be explained by a catastrophic instability involving global crust failure and magnetic reconnection on a magnetar, with possible large-scale untwisting of magnetic field lines outside the star. From a great distance this event would appear to be a short-duration, hard-spectrum cosmic gamma-ray burst. At least a significant fraction of the mysterious short-duration gamma-ray bursts may therefore come from extragalactic magnetars.

Molecular nature of the Drosophila sex determination signal and its link to neurogenesis.

In 1921 it was discovered that the sexual fate of Drosophila is determined by the ratio of X chromosomes to sets of autosomes. Only recently has it been found that the X chromosome to autosome (X:A) ratio is communicated in part by the dose of sisterless-b (sis-b), an X-linked genetic element located within the achaete-scute complex of genes involved in neurogenesis. In this report, the molecular nature of the primary sex determination signal and its relation to these proneural genes was determined by analysis of sis-b+ germline transformants. The sis-b+ function is confered by protein T4, a member of the helix-loop-helix family of transcription factors. Although T4 is shared by sis-b and scute-alpha, the regulatory regions of sis-b, which control T4 expression in sex determination, are both separable from and simpler than those of scute-alpha, which control T4 expression in neurogenesis. Dose-sensitive cooperative interactions in the assembly or binding of sis-dependent transcription factors may directly determine the activity of the female-specific promoter of Sex-lethal, the master regulator of sexual development. In this model there is no need to invoke the existence of analogous autosomal negative regulators of Sex-lethal.

The Drosophila sex determination signal: how do flies count to two?

Seventy years after the discovery that sex in Drosophila melanogaster is determined by the balance between X chromosomes and autosomes, we can finally identify some of the specific genes whose relative dosage is responsible for the male/female decision in somatic cells and study how they act at the molecular level. Discovery of these sex determination genes was delayed because their mutant phenotypes were unanticipated. It now seems appropriate to consider how the concept of the X/A balance may have limited thinking about the fruit fly sex determination signal.

The complex set of late transcripts from the Drosophila sex determination gene sex-lethal encodes multiple related polypeptides.

Sex-lethal (Sxl), a key sex determination gene in Drosophila melanogaster, is known to express a set of three early transcripts arising during early embryogenesis and a set of seven late transcripts occurring from midembryogenesis through adulthood. Among the late transcripts, male-specific mRNAs were distinguished from their female counterparts by the presence of an extra exon interrupting an otherwise long open reading frame (ORF). We have now analyzed the structures of the late Sxl transcripts by cDNA sequencing, Northern (RNA) blotting, primer extension, and RNase protection. The late transcripts appear to use a common 5' end but differ at their 3' ends by the use of alternative polyadenylation sites. Two of these sites lack canonical AATAAA sequences, and their use correlates in females with the presence of a functional germ line, suggesting possible tissue-specific polyadenylation. Besides the presence of the male-specific exon, no additional sex-specific splicing events were detected, although a number of non-sex-specific splicing variants were observed. In females, the various forms of late Sxl transcript potentially encode up to six slightly different polypeptides. All of the protein-coding differences occur outside the previously defined ribonucleoprotein motifs. One class of Sxl mRNAs also includes a second long ORF in the same frame as the first ORF but separated from it by a single ochre codon. The function of this second ORF is unknown. Significant amounts of apparently partially processed Sxl RNAs were observed, consistent with the hypothesis that the regulated Sxl splices occur relatively slowly.

Maternal and zygotic sex-specific gene interactions in Drosophila melanogaster.

Sex-lethal (Sxl) is a vital, X-chromosome gene involved in Drosophila sex determination. The most striking aspect of the phenotype of daughterless (da), an autosomal maternal-effect mutation, may be explained by effects on the functioning of the Sxl gene in the zygote. In this paper, new aspects of interactions between various combinations of Sxl and da alleles are explored in order to understand better the complex da phenotype. The study focuses on the relationship between maternal and zygotic da+ gene functions, and on the relationship between aspects of the da phenotype that are sex-specific and aspects that are not. The SxlM#1 allele, which counteracts the female-specific maternal effect of da, is shown to have no effect on two other aspects of the da phenotype (one maternal, one primarily zygotic) that are not sex-specific. The female-lethal da maternal effect is shown to kill daughters even when the progeny are entirely wild-type with respect to da. Recessive mutant alleles of the two genes can interact synergistically when both are heterozygous with their wild-type alleles, disrupting the development of most of the daughters. Surprisingly, even a deficiency of the da+ locus can produce a dominant, temperature-sensitive, female-lethal maternal effect. A new class of subliminal Sxlf alleles is described. These spontaneous mutations can confuse analysis of both da and Sxl if their presence is not appreciated. Finally, conditions are described that facilitate the study of the Enhancer of daughterless mutation.

Evidence that sisterless-a and sisterless-b are two of several discrete "numerator elements" of the X/A sex determination signal in Drosophila that switch Sxl between two alternative stable expression states.

The primary signal for Drosophila sex determination is the number of X chromosomes relative to the number of sets of autosomes. The present report shows that the numerator of this X/A signal appears to be determined by the cumulative dose of a relatively limited number of discrete X-linked genetic elements, two of which are sisterless-a and sisterless-b. This discovery regarding the nature of the sex determination signal grew out of previous studies of both the likely X/A signal target (the feminizing switch gene, Sex-lethal) and two positive regulators of that target gene (sis-a and daughterless). Combinations of genetic perturbations in these three genes had been shown to have synergistic effects. A model proposed in part to account for these interactions generated a large variety of strong predictions for sex-specific synergistic interactions that would be diagnostic for X/A numerator elements and could distinguish them from other components of the sex determination system. All these predictions, as well as other predictions for X/A numerator elements, are shown here to be fulfilled. The most compelling observations involve sexually reciprocal viability effects of duplications of wild-type genes: combinations of sis-a+, sis-b+ and/or Sxl+ duplications are lethal to males but rescue females from the otherwise lethal effects of changes in other components of the sex determination machinery. The many interactions described here illustrate an important principle that may seem counter-intuitive: perturbations of the sex determination signal for Drosophila generally will not appear to affect adult sexual phenotype. This principle follows from the fact that Sxl is involved in dosage compensation as well as sex determination, and from important aspects of the nature and timing of Sxl's regulation both by the X/A signal and by Sxl's own products (positive autoregulation). These factors mask potential effects on adult sexual differentiation by causing the premature death of cells and/or individuals. The fact that the vast array of results presented here conform to this principle is strong evidence in favor of a "binary state" model for Sxl regulation by the X/A signal. This model is favored over an alternative "multiple state" hypothesis that was proposed by others in a different study of the X/A signal. In that same study it was concluded that region 3E8-4F11 of the X chromosome contained especially potent X/A numerator elements.(ABSTRACT TRUNCATED AT 400 WORDS)

A female-specific lethal lesion in an X-linked positive regulator of the Drosophila sex determination gene, Sex-lethal.

Characterization of a partial-loss-of-function, female-specific lethal mutation has identified an X-linked genetic element (1-34.3; 10B4) that functions as a positive regulator of Sxl, a central gene controlling sex determination in Drosophila melanogaster. The name, sisterless-a, was chosen both to suggest functional similarities that exist between this gene and another positive regulator of Sxl, the maternally acting gene daughterless (da), and also to highlight an important difference; namely, that in contrast to da, it is the zygotic rather than maternal functioning of sis-a that is involved in its interaction with Sxl. As with da, the female-specific lethal phenotype of sis-a is suppressed both by SxlM#1, a gain-of-function mutant allele of the target gene, and, to a lesser extent, by a duplication of Sxl+. Mutations at sis-a, da and Sxl display female-specific dominant synergism, each enhancing the others' lethal effects. The allele specificity with respect to Sxl of these dominant interactions indicates that sis-a and da affect the same aspect of Sxl regulation. As with previous studies of da and Sxl, the masculinizing effects of loss of sis-a function are generally obscured by lethal effects, presumably related to upsets in dosage compensation. The masculinizing effects can be dissociated from lethal effects by analysis of triploid intersexes (XX AAA) or by analysis of diploid females who are also mutant for autosomal genes known to be required for the transcriptional hyperactivation associated with dosage compensation in males. Analysis of foreleg development shows that intersexuality generated by sis-a is of the mosaic type: At the level of individual cells, only male or female development is observed, never an intermediate sexual phenotype characteristic of true intersexes. Sexual development of diplo-X germline and somatic clones of sis-a tissue generated by mitotic recombination during larval stages is normal, as is the sexual phenotype of homozygous sis-a escapers. Considered in their totality, these results indicate that sis-a functions early in development to help establish the activity state of Sxl and thereby initiate the sexual pathway commitment, rather than functioning later in the processes by which Sxl maintains and expresses the sex determination decision.

A sex-specific, temperature-sensitive maternal effect of the daughterless mutation of Drosophila melanogaster.

Every aspect of the phenotype of the daughterless (2-41.5) maternal effect mutation was found to be strongly temperature sensitive. Above 22 degrees, da/da mothers produced no daughters; however female progeny did survive the da maternal effect if the last 60 hours of oogenesis and the first three hours of embryonic development took place at 18 degrees. The females which survived under these conditions displayed morphological abnormalities in a variety of adult cuticular structures, characterisitc of cell death during development. In contrast, their male siblings were morphologically normal. Upon prolonged exposure to 29 degrees, da/da females became sterile but continued to lay eggs. Some sexually mosaic progeny from da/da mothers survived even at 25 degrees, but the distribution and development of the female tissue in these mosaics were abnormal. It is suggested that there are multiple functions of the da+ gene during oogenesis, one of which may be required specifically for the subsequent survival of female cells throughout the embryo. In addition to and distinct from its effect during oogenesis, the da mutation acted in both sexes of progeny as a recessive temperature-sensitive lethal mutation with a TSP during the first half of embryonic development.

Two closely linked mutations in Drosophila melanogaster that are lethal to opposite sexes and interact with daughterless.

A new spontaneous mutation named Sex-lethal, Male-specific No. 1 (SxlM1) is described that is lethal to males, even in the presence of an Sxl+ duplication. Females homozygous for SxlM1 are fully viable. This dominant, male-specific lethal mutation is on the X chromosome approximately 0.007 map units to the right of a previously isolated female-specific mutation, Female-lethal, here renamed Sex-lethal, Female-specific No. 1 (SxlF1). SxlM1 and SxlF1 are opposite in nearly every repect, particularly with regard to their interaction with maternal effect of the autosomal mutation, daughterless (da). Females that are homozygous for da produce defective eggs that cannot support female (XX) development. A single dose of SxlM1 enables daughters to survive this da female-specific lethal maternal effect. A duplication of the Sxl locus weakly mimics this action of SxlM1. In contrast, SxlF1 and a deficiency for Sxl, strongly enhance the female-lethal effects of da. The actions of SxlM1 and SxlF1 are explained by a model in which expression of the Sxl locus is essential for females, lethal for males, and under the control of a product of the da locus. It is suggested that SxlM1 is a constitutive mutation at the Sxl locus.

Autoregulatory functioning of a Drosophila gene product that establish es and maintains the sexually determined state.

Sxl appears to head a regulatory gene hierarchy that controls Drosophila sexual dimorphism in response to the X chromosome/autosome balance. Only XXAA cells normally have Sxl(+) activity. It maintains both the female morphogenetic sequence and a level of X-linked dosage-compensated gene expression compatible with diplo-X cell survival. In the absence of this activity, male sexual development and dosage-compensated gene hyperactivation ensure. Loss-of-function Sxl mutations generally have female-specific lethal effects caused by upsets in dosage compensation. New female-viable Sxl mutant alleles and combinations which lack Sxl's female sex determination function, yet still provide sufficient dosage compensation function for diplo-X survival, are described here. Consequently, such mutants cause genotypic females to develop as phenotypic males. Some of these sex-transforming Sxl mutants do not require the maternally produced da(+) activity that is normally essential for the functioning of zygotic Sxl alleles. In this paper, products of these unusual alleles are shown to act in trans to induce the expression of zygotic Sxl(+) alleles that would otherwise be unable to function due to a lack of maternal da(+) activity. This result indicates a third function for Sxl(+) product: a positive autoregulatory role. Controls for the autoregulation experiments demonstrated the sex-trans-forming epigenetic effect of the da mutation for the first time in diploids. In these experiments the female-specific zygotic lethal effects that normally would have accompanied loss of maternal da(+) activity were suppressed by mutations known to block dosage-compensation gene hyperactivation-the autosomal, male-specific lethals. Three types of abnormal sexual phenotypes were produced in the experiments described here, each with important implications for the mechanism of sex determination: (1) a true intersex phenotype produced by one particular Sxl allele shows that Sxl(+) must be involved in the cellular response to the X/A balance rather than in its establishment; (2) a maternally induced, female-sterile phenotype indicates that either the process of autoregulation or the mutants used to demonstrate it are tissue specific and (3) a mosaic intersexual phenotype whose character implies that the Sxl(+ ) activity level is set early in development, both by the da( +)-mediated X/A balance signal and by autoregulation, and is maintained subsequently in a cell autonomous fashion, independent of the initiating X/A balance signal. Thus, this study supports the view that sex determination is truly determinative in the standard developmental sense, and that Sxl is the carrier of the sexually determined state.

Differential effects of Sex-lethal mutations on dosage compensation early in Drosophila development.

In response to the primary sex determination signal, X chromosome dose, the Sex-lethal gene controls all aspects of somatic sex determination and differentiation, including X chromosome dosage compensation. Two complementary classes of mutations have been identified that differentially affect Sxl somatic functions: (1) those impairing the "early" function used to set developmental pathway choice in response to the sex determination signal and (2) those impairing "late" functions involved in maintaining the pathway choice independent of the initiating signal and/or in directing differentiation. This "early vs. late" distinction correlates with a switch in promoter utilization from SxlPe to SxlPm at the blastoderm stage and a corresponding switch from transcriptional to RNA splicing control. Here we characterize five partial-loss-of-function Sxl alleles to explore a distinction between "early vs. late" functioning of Sxl in dosage compensation. Assaying for dosage compensation during the blastoderm stage, we find that the earliest phase of the dosage compensation process is controlled by products of the early Sxl promoter, SxlPe. Hence, in addition to triggering the sexual pathway decision of cells, products derived from SxlPe also control early dosage compensation, the first manifestation of sexually dimorphic differentiation. The effects of mutant Sxl alleles on early dosage compensation are consistent with their previous categorization as early vs. late defective with respect to their effects on pathway initiation. Results reported here suggest that the dosage compensation regulatory genes currently known to function downstream of Sxl, genes known as the "male-specific lethals," do not control all aspects of dosage compensation either at the blastoderm stage or later in development. In the course of this study, we also discovered that the canonical early defective allele, Sxlf9, which is impaired in its ability to establish the female developmental pathway commitment, is likely to be defective in the stability and/or functioning of products derived from SxlPe, rather than in the ability of SxlPe to respond to the chromosomal sex determination signal.

Genetic and molecular analysis of the autosomal component of the primary sex determination signal of Drosophila melanogaster.

Drosophila sex is determined by the action of the X:A chromosome balance on transcription of Sex-lethal (Sxl), a feminizing switch gene. We obtained loss-of-function mutations in denominator elements of the X:A signal by selecting for dominant suppressors of a female-specific lethal mutation in the numerator element, sisterlessA (sisA). Ten suppressors were recovered in this extensive genome-wide selection. All were mutations in deadpan (dpn), a pleiotropic locus previously discovered to be a denominator element. Detailed genetic and molecular characterization is presented of this diverse set of new dpn alleles including their effects on Sxl. Although selected only for impairment of sex-specific functions, all were also impaired in nonsex-specific functions. Male-lethal effects were anticipated for mutations in a major denominator element, but we found that viability of males lacking dpn function was reduced no more than 50% relative to their dpn- sisters. Moreover, loss of dpn activity in males caused only a modest derepression of the Sxl "establishment" promoter (Sxlpe), the X:A target. By itself, dpn cannot account for the masculinizing effect of increased autosomal ploidy, the effect that gave rise to the concept of the X:A ratio; nevertheless, if there are other denominator elements, our results suggest that their individual contributions to the sex-determination signal are even less than that of dpn. The time course of expression of dpn and of Sxl in dpn mutant backgrounds suggests that dpn is required for sex determination only during the later stages of X:A signaling in males to prevent inappropriate expression of Sxlpe in the face of increasing sis gene product levels.

Vital Genes That Flank Sex-Lethal, an X-Linked Sex-Determining Gene of DROSOPHILA MELANOGASTER.

The X-chromosome:autosome balance in D. melanogaster appears to control both sex determination and dosage compensation through effects on a maternally influenced sex-linked gene called Sex-lethal (Sxl; 1-19.2). To facilitate molecular and genetic analysis of Sxl, we attempted to determine the locations of all ethyl methanesulfonate (EMS)-mutable genes vital to both sexes in the region between 6E1 and 7B1. This area includes approximately 1 cM of the genetic map on each side of Sxl and was reported by C. B. Bridges to contain 26 salivary gland polytene chromosome bands. The region appears rather sparsely populated with genes vital to both sexes, since the 122 recessive lethal mutations we recovered fell into only nine complementation groups. From one to 38 alleles of each gene were recovered. There was a preponderance of embryonic lethals in this area, although the lethal periods of loss-of-function mutations included larval, pupal and adult stages as well. Since the screen required that mutations be recessive and lethal to males, our failure to recover new Sxl alleles was the result expected for a gene with a female-specific function. An attempt was made to identify recessive male-specific lethals in this region, but none were found. Precise map positions were determined for eight of the nine vital genes. An interesting feature of the map is the location of Sxl in the middle of a 0.6- to 0.7-cM interval that appears to be devoid of genes vital to both sexes. The genetic location was determined of breakpoints near Sxl for all available chromosome rearrangements. Sxl is most likely located just to the left of band 7A1. We determined the relationship of our EMS-induced mutations in these nine genes to alleles induced by others. From this we conclude that the various genes appear to differ significantly from each other in their relative sensitivity to mutation by EMS vs. X rays.

Functional changes associated with structural alterations induced by mobilization of a P element inserted in the Sex-lethal gene of Drosophila.

Genetic analysis of rearrangements within the multifunctional sex determining gene Sex-lethal has allowed correlation of changes in specific functions with DNA alterations. Rearrangements were isolated by mobilization of a P element which is on the 5' side of the gene, at coordinate 0. Previous work has shown that rearrangements associated with alterations in Sxl gene function are found within an 11-kb region between coordinates-11 and 0. Here it is shown that insertion of foreign DNA, per se, at coordinate 0 is compatible with wild-type gene function. However, deletion of sequences on either side of this point generates a mutant phenotype. Deletions extending distally beyond coordinate -6.5 kb result in a null phenotype, whereas smaller distal deletions or proximal deletions eliminate only some Sxl functions.

Transposon insertions causing constitutive Sex-lethal activity in Drosophila melanogaster affect Sxl sex-specific transcript splicing.

Sex-lethal (Sxl) gene products induce female development in Drosophila melanogaster and suppress the transcriptional hyperactivation of X-linked genes responsible for male X-chromosome dosage compensation. Control of Sxl functioning by the dose of X-chromosomes normally ensures that the female-specific functions of this developmental switch gene are only expressed in diplo-X individuals. Although the immediate effect of X-chromosome dose is on Sxl transcription, during most of the life cycle "on" vs. "off" reflects alternative Sxl RNA splicing, with the female (productive) splicing mode maintained by a positive feedback activity of SXL protein on Sxl pre-mRNA splicing. "Male-lethal" (SxlM) gain-of-function alleles subvert Sxl control by X-chromosome dose, allowing female Sxl functions to be expressed independent of the positive regulators upstream of Sxl. As a consequence, SxlM haplo-X animals (chromosomal males) die because of improper dosage compensation, and SxlM chromosomal females survive the otherwise lethal effects of mutations in upstream positive regulators. Five independent spontaneous SxlM alleles were shown previously to be transposon insertions into what was subsequently found to be the region of regulated sex-specific Sxl RNA splicing. We show that these five alleles represent three different mutant types: SxlM1, SxlM3, and SxlM4. SxlM1 is an insertion of a roo element 674 bp downstream of the translation-terminating male-specific exon. SxlM3 is an insertion of a hobo transposon (not 297 as previously reported) into the 3' splice site of the male exon, and SxlM4 is an insertion of a novel transposon into the male-specific exon itself. We show that these three gain-of-function mutants differ considerably in their ability to bypass the sex determination signal, with SxlM4 being the strongest and SxlM1 the weakest. This difference is also reflected in effects of these mutations on sex-specific RNA splicing and on the rate of appearance of SXL protein in male embryos. Transcript analysis of double-mutant male-viable SxlM derivatives in which the SxlM insertion is cis to loss-of-function mutations, combined with other results reported here, indicates that the constitutive character of these SxlM alleles is a consequence of an alteration of the structure of the pre-mRNA that allows some level of female splicing to occur even in the absence of functional SXL protein. Surprisingly, however, most of the constitutive character of SxlM alleles appears to depend on the mutant alleles' responsiveness, perhaps greater than wild-type, to the autoregulatory splicing activity of the wild-type SXL proteins they produce.

Cognitive-behavioral group intervention to assist substance-dependent adolescents in lowering HIV infection risk.

Substance dependent adolescents (N = 19), court referred into a residential drug treatment facility received a five-session HIV risk-reduction intervention that provided risk education, social competency skills (sexual assertion, partner negotiation, and communication skills), technical skills (condom use), and problem-solving training. Before and after the intervention, subjects completed measures of AIDS risk knowledge, health locus of control, social support, attitudes toward HIV prevention, attitudes toward condoms, self-efficacy, and perceptions of risk in addition to role-play assessments of behavioral skill resisting high-risk coercions. Postintervention, subjects exhibited increased knowledge about HIV/AIDS, more favorable attitudes toward prevention, greater internal and lower external locus of control scores, more favorable attitudes toward condom use, increased self-efficacy, and greater recognition of HIV vulnerability. Following intervention, the percentage of participants reporting sexual activity in high-risk contexts decreased, substantiating the intervention's effectiveness. Self-report data were corroborated by sexually transmitted disease treatment records. This uncontrolled demonstration effort suggests that skills training based on cognitive-behavioral principles may be a promising intervention strategy to lower vulnerable adolescents' risk of HIV infection.

Influence of the beta 2-adrenergic agonist clenbuterol on insulin-stimulated lipogenesis in mouse adipocytes.

Growing mice fed the beta 2-adrenergic agonist clenbuterol (CB; 20ppm) had increased rate of growth and altered composition of gain (greater protein and less fat). Adipocytes prepared from the epididymal fat pads of treated and untreated mice were used to examine the influence of CB on lipid metabolism. Using cells from untreated mice, CB stimulated lipolysis to an equivalent maximum rate as epinephrine (EPI), but CB was far less potent (EC50 (microM); CB = 5, EPI = 0.2). Both CB and EPI inhibited insulin-stimulated lipogenesis over the physiological range of insulin concentrations. This inhibition was expressed as a dose-dependent decrease in tissue sensitivity to insulin and a decrease in maximal lipogenic capacity. Inhibition of maximal rate, but not of insulin sensitivity, could be stimulated by the addition of palmitate without EPI or CB. Adipocytes isolated from CB-treated mice did not differ from controls in sensitivity to insulin or in activity of fatty acid synthetase. Increased lipolysis and reduced lipogenesis as observed in vitro with CB are consistent with reduced fat accretion in CB-treated mice. However, the absence of detectable changes in adipocyte lipogenesis from CB-fed mice leaves open the question of the relevance of altered lipid metabolism to the observed changes in body composition.

Influence of sulfate in drinking water on mouse reproduction during two parities.

Field studies have suggested that high levels of sulfate in drinking water may alter water consumption and have an adverse effect on animal reproduction. This study was conducted to determine whether sulfate in the drinking water affects the reproductive performance of female mice during gestation and lactation over two parities. Sixty random-bred albino mice were randomly assigned to six sulfate treatments. Sodium sulfate was added to deionized distilled water to give sulfate levels in ppm as follows: (1) 0 (control); (2) 0 (Na control); (3) 625; (4) 1,250; (5) 2,500 and (6) 5,000. Treatments 2 to 6 contained the same Na content (2,392 ppm) by varying Na bicarbonate content. Mice receiving only the deionized distilled water drank less (P less than .05) than mice receiving the other treatments at all times measured. Animals offered the 0 (Na control) water drank more (P less than .05) water than mice on the other sulfate treatments. There was no difference (P greater than .10) in litter size, litter weaning weight, or gestational and lactational weight gain of the dam among water treatments. Although levels of sulfate up to 5,000 ppm and 2,392 ppm Na in the drinking water cubicly altered water consumption, they did not affect litter size, litter weaning weight, or gestational and lactational weight gain of the dam when sulfate ingestion was continued over two parities.