Suchita Das

A role of the Drosophila homeless gene in repression of Stellate in male meiosis

Abstract. The homeless gene of Drosophila melanogaster encodes a member of the DE-H family of ATPase and RNA helicase proteins. Loss-of-function homeless mutations were previously found to cause female sterility with numerous defects in oogenesis, including improper formation of both the anterior-posterior and dorsal-ventral axes and failure to transport and localize key RNAs required for axis formation. One homeless mutation was also found to affect male meiosis, causing elevated X-Y nondisjunction. Here we further analyze the role of homeless in male meiosis. We show that homeless mutations cause a variety of defects in male meiosis including nondisjunction of the X-Y and 2-2 pair, Y chromosome marker loss, meiotic drive, chromosome fragmentation, chromatin bridges at anaphase, and tripolar meiosis. In addition, homeless mutations interact with an X chromosomal factor to cause complete male sterility. These phenotypes are similar to those caused by deletion of the Suppressor of Stellate [Su(Ste)] locus. Like Su(Ste) deficiencies, homeless mutants also exhibit crystals in primary spermatocytes and derepression of the X-linked Stellate locus. To determine whether the regulatory role of hls is specific for Stellate or includes other repeated sequences as well, we compared testis RNA levels for nine transposable elements and found that all but one, copia, were expressed at the same levels in hls mutants and wild type. Copia, however, was strongly derepressed in hls mutant males. We conclude that hls functions along with Su(Ste) and other recently described genes to repress the Stellate locus in spermatocytes, and that it may also play a role in repressing certain other repeated sequences.

Transcriptomic and metabolomic profiling of chicken adipose tissue in response to insulin neutralization and fasting

BackgroundDomestic broiler chickens rapidly accumulate adipose tissue due to intensive genetic selection for rapid growth and are naturally hyperglycemic and insulin resistant, making them an attractive addition to the suite of rodent models used for studies of obesity and type 2 diabetes in humans. Furthermore, chicken adipose tissue is considered as poorly sensitive to insulin and lipolysis is under glucagon control. Excessive fat accumulation is also an economic and environmental concern for the broiler industry due to the loss of feed efficiency and excessive nitrogen wasting, as well as a negative trait for consumers who are increasingly conscious of dietary fat intake. Understanding the control of avian adipose tissue metabolism would both enhance the utility of chicken as a model organism for human obesity and insulin resistance and highlight new approaches to reduce fat deposition in commercial chickens.ResultsWe combined transcriptomics and metabolomics to characterize the response of chicken adipose tissue to two energy manipulations, fasting and insulin deprivation in the fed state. Sixteen to 17 day-old commercial broiler chickens (ISA915) were fed ad libitum, fasted for five hours, or fed but deprived of insulin by injections of anti-insulin serum. Pair-wise contrasts of expression data identified a total of 2016 genes that were differentially expressed after correction for multiple testing, with the vast majority of differences due to fasting (1780 genes). Gene Ontology and KEGG pathway analyses indicated that a short term fast impacted expression of genes in a broad selection of pathways related to metabolism, signaling and adipogenesis. The effects of insulin neutralization largely overlapped with the response to fasting, but with more modest effects on adipose tissue metabolism. Tissue metabolomics indicated unique effects of insulin on amino acid metabolism.ConclusionsCollectively, these data provide a foundation for further study into the molecular basis for adipose expansion in commercial poultry and identify potential pathways through which fat accretion may be attenuated in the future through genetic selection or management practices. They also highlight chicken as a useful model organism in which to study the dynamic relationship between food intake, metabolism, and adipose tissue biology.

The distribution of male meiotic pairing sites on chromosome 2 of Drosophila melanogaster: meiotic pairing and segregation of 2-Y transpositions

The distribution of meiotic pairing sites on a Drosophila melanogaster autosome was studied by characterizing patterns of prophase pairing and anaphase segregation in males heterozygous for a number of 2-Y transpositions, collectively coveringall of chromosome arm 2R and one-fourth of chromosome arm 2L. It was found that all transpositions involving euchromatin from chromosome 2, even short stretches, increased the frequency of prophase I quadrivalents involving the sex and second chromosome bivalents above background levels. Quadrivalent frequencies were the same whether the males carried both elements of the transposition or just the Dp (2;Y) element along with two normal chromosome 2s, indicating that pairing is non-competitive. The frequency of quadrivalents was proportional to the size of the transposed region, suggesting that pairing sites are widely distributed on chromosome 2. Moreover, all but the smallest transpositions caused a detectable bias in the segregation ratio, in favor of alternate segregations, indicating that the prophase associations were effective in orienting centromeres to opposite poles. One transposition involving only heterochromatin of chromosome 2 had no effect on quadrivalent frequency, consistent with previous evidence that autosomal heterochromatin lacks meiotic pairing ability in males. One region at the base of chromosome arm 2L proved to be especially effective in stimulating quadrivalent formation and anaphase segregation, indicating the presence of a strong pairing site in this region. It is concluded that autosomal pairing in D. melanogaster males is based on general homology, despite the lack of homologous recombination.

Identifying genetic loci and spleen gene coexpression networks underlying immunophenotypes in BXD recombinant inbred mice

The immune system plays a pivotal role in the susceptibility to and progression of a variety of diseases. Due to a strong genetic basis, heritable differences in immune function may contribute to differential disease susceptibility between individuals. Genetic reference populations, such as the BXD (C57BL/6J × DBA/2J) panel of recombinant inbred (RI) mouse strains, provide unique models through which to integrate baseline phenotypes in healthy individuals with heritable risk for disease because of the ability to combine data collected from these populations across both multiple studies and time. We performed basic immunophenotyping (e.g., percentage of circulating B and T lymphocytes and CD4(+) and CD8(+) T cell subpopulations) in peripheral blood of healthy mice from 41 BXD RI strains to define the immunophenotypic variation in this strain panel and to characterize the genetic architecture that underlies these traits. Significant QTL models that explained the majority (50-77%) of phenotypic variance were derived for each trait and for the T:B cell and CD4(+):CD8(+) ratios. Combining QTL mapping with spleen gene expression data uncovered two quantitative trait transcripts, Ptprk and Acp1, as candidates for heritable differences in the relative abundance of helper and cytotoxic T cells. These data will be valuable in extracting genetic correlates of the immune system in the BXD panel. In addition, they will be a useful resource for prospective, phenotype-driven model selection to test hypotheses about differential disease or environmental susceptibility between individuals with baseline differences in the composition of the immune system.

On the Roles of Heterochromatin and Euchromatin in Meiosis in Drosophila: Mapping Chromosomal Pairing Sites and Testing Candidate Mutations for Effects on X–Y Nondisjunction and Meiotic Drive in Male Meiosis

Mapping of pairing sites involved in meiotic homolog disjunction in Drosophilahas led to conflicting hypotheses about the nature of such sites and the role of heterochromatin in meiotic pairing. In the female-specific distributive system, pairing regions appear to be exclusively heterochromatic and map to broad regions encompassing many different sequences. In male meiosis, autosomal pairing sites appear to be distributed broadly within euchromatin but to be absent from heterochromatin, whereas the X-pairing site maps in the centric heterochromatin. The X site has been shown to coincide with the intergenic spacer (IGS) repeats within the rDNA arrays shared between the X and Y. It has not been clear whether the heterochromatic location of this pairing site has any significance. A novel assay for genic modifiers of X–Y chromosome pairing was developed based on the intermediate nondisjunction levels observed in males whose X chromosome lacks the native pairing site but contains two transgenic insertions of single rDNA genes. This assay was used to test several mutations in Su(var)(Suppressor of position effect variegation), PcG(Polycomb-Group) recombination defective, and repair-defective genes. No strong effects on disjunction were seen. However, the tests did uncover several mutations that suppress or enhance the meiotic drive (distorted X-Y recovery ratio) that accompanies X–Y pairing failure.

Maternal consumption of fish oil programs reduced adiposity in broiler chicks

Maternal intake of eicosapentaenoic acid (EPA; 20:5 n-3) and docosahexaenoic acid (22:6 n-3) has been associated with reduced adiposity in children, suggesting the possibility to program adipose development through dietary fatty acids before birth. This study determined if enriching the maternal diet in fish oil, the primary source of EPA and DHA, affected adipose development in offspring. Broiler chickens were used because they are obesity-prone, and because fatty acids provided to the embryo can be manipulated through the hen diet. Hens were fed diets supplemented (2.8% wt:wt) with corn oil (CO; n-6) or fish oil (FO; n-3) for 28 d. Chicks from both maternal diet groups were fed the same diet after hatch. Maternal FO consumption enriched chick adipose tissue in EPA and DHA and reduced adiposity by promoting more, but smaller, adipocytes. This adipocyte profile was paralleled by lower expression of the adipogenic regulator PPARG and its co-activator PPARGC1B, and elevated expression of LPL. Proteomics identified 95 differentially abundant proteins between FO and CO adipose tissue, including components of glucose metabolism, lipid droplet trafficking, and cytoskeletal organization. These results demonstrate that the maternal dietary fatty acid profile programs offspring adipose development.

Enriching the Starter Diet in n–3 Polyunsaturated Fatty Acids Reduces Adipocyte Size in Broiler Chicks

Abstract Epidemiologic studies associate perinatal intake of eicosapentaenoic acid (EPA, 20:5n–3) and docosahexaenoic acid (DHA, 22:6n–3) with reduced adiposity in children, suggesting that these fatty acids may alter adipose tissue development. The objective of this study was to determine whether enriching the perinatal diet in EPA and DHA reduces fat deposition in young chicks. Cobb 500 broiler chicks were fed isocaloric diets containing fat (8% wt:wt) from fish oil (FO), lard, canola oil, or flaxseed oil from 7 to 30 d of age. Adiposity (abdominal fat pad weight/body weight) at 30 d was not significantly affected by diet, but FO significantly reduced adipocyte size, increasing the abundance of small adipocytes. Plasma nonesterified fatty acid concentrations suggest that reduced adipocyte size was due, in part, to enhanced mobilization of fatty acids from adipose tissue. Our work indicates that dietary EPA and DHA effectively reduce the size of developing adipocytes in juveniles, which may limit adipose deposition and provide metabolic benefits.

Sex- and Strain-dependent Effects of Bisphenol: A Consumption inJuvenile Mice

Children are directly exposed to bisphenol A (BPA) and other putative environmental obesogens through both diet and household products. The purpose of this study was to investigate sex- and genetic-dependent effects of BPA consumption on traits relevant to obesity and Type 2 diabetes in juveniles, using mice as models. Two strains of mice (C57BL/6J and DBA/2J) were chosen to represent distinct genetic backgrounds that differ in susceptibility to obesity and insulin resistance. Male and female mice of each strain consumed BPA at three doses in drinking water from four to eleven weeks of age. Male but not female mice of each strain consuming BPA were significantly fatter than controls. BPA induced corresponding changes in adipose tissue gene expression and metabolite abundance that indicate effects on adipogenesis and energy utilization. BPA consumption also altered the synthesis of adipokines, circulating factors that modulate insulin sensitivity and atherogenesis, in C57BL/6J but not DBA/2J males. Conversely, effects of BPA on plasma insulin were only observed in female mice, and with opposite effects in the two strains. These results suggest that dietary BPA may exacerbate childhood obesity and its consequences, and that sex and genetic background are important determinants of the physiological impact of BPA.