Toshiyuki Takano-Shimizu

Roles of jumonji and jumonji family genes in chromatin regulation and development

The jumonji (jmj) gene was identified by a mouse gene trap approach and has essential roles in the development of multiple tissues. The Jmj protein has a DNA binding domain, ARID, and two conserved jmj domains (jmjN and jmjC). In many diverse species including bacteria, fungi, plants, and animals, there are many jumonji family proteins that have only the jmjC domain or both jmj domains. Recently, Jmj protein was found to be a transcriptional repressor. Several proteins in the jumonji family are involved in transcriptional repression and/or chromatin regulation. Most recently, one of the human members has been shown to be a histone demethylase, and the jmjC domain is essential for the demethylase activity. Meanwhile, more and more evidence indicating that the jumonji family proteins play important roles during development is accumulating. Many proteins in the jumonji family may regulate chromatin and gene expression, and control development through various signaling pathways. Here, we highlight the roles of jmj and jumonji family proteins in chromatin regulation and development. Developmental Dynamics 235:2449–2459, 2006.

Effects of small Hsp genes on developmental stability and microenvironmental canalization

BackgroundProgression of development has to be insulated from the damaging impacts of environmental and genetic perturbations to produce highly predictable phenotypes. Molecular chaperones, such as the heat shock proteins (HSPs), are known to buffer various environmental stresses, and are deeply involved in protein homeostasis. These characteristics of HSPs imply that they might affect developmental buffering and canalization.ResultsWe examined the role of nine Hsp genes using the GAL4/UAS-RNAi system on phenotypic variation of various morphological traits in Drosophila melanogaster. The stability of bristle number, wing size and wing shape was characterized through fluctuating asymmetry (FA) and the coefficient of variation (CV), or among-individual variation. Progeny of the GAL4/Hsp-RNAi crosses tended to have reduced trait means for both wing size and wing shape. Transcriptional knockdown of Hsp67Bc and Hsp22 significantly increased FA of bristle number, while knockdown of Hsp67Ba significantly increased FA and among-individual variation of wing shape but only in males. Suppression of Hsp67Bb expression significantly increased among-individual variation of bristle number. The knockdown of gene expression was confirmed for Hsp67Ba, Hsp67Bc, Hsp22, and Hsp67Bb. Correlation between FA and CV or among-individual variation of each trait is weak and not significant except for the case of male wing shape.ConclusionFour small Hsp genes (Hsp22, Hsp67Ba, Hsp67Bb and Hsp67Bc) showed involvement in the processes of morphogenesis and developmental stability. Due to possible different functions in terms of developmental buffering of these small Hsps, phenotypic stability of an organism is probably maintained by multiple mechanisms triggered by different environmental and genetic stresses on different traits. This novel finding may lead to a better understanding of non-Hsp90 molecular mechanisms controlling variability in morphological traits.

Characteristics of genes up-regulated and down-regulated after 24 h starvation in the head of Drosophila

Starvation is a common experience under fluctuating food conditions in nature, and response to it is vital for many organisms. Many studies have investigated the response at physiological and behavioral level, whereas the studies on starvation-induced transcriptional changes in the brain and the surrounding tissues are still limited. We here investigated global changes in transcript abundance in the head after 24 h starvation by microarray expression profiling of 2 wild-derived inbred strains of Drosophila melanogaster, and identified a core set of 65 up-regulated and 48 down-regulated genes upon starvation. Among these up-regulated genes, 22 genes were circadian oscillating genes previously identified in the head of Drosophila. Interestingly, most (86%) of these circadian genes show their expression peak in a narrow time range of ZT7.0-12.0, when flies are relatively restless and less feeding in the normal condition. Among the down-regulated genes, 2 genes with highest fold-differences, fit and CG8147, are known to have female-biased expression in the head, and 1 gene, Obp99b, is known to be male-biased. Together with the realtime qPCR experiments on female and male transcripts, our data suggest that these sex-specific genes are candidate genes mediating a possible trade-off between starvation resistance and reproduction. Eleven down-regulated genes are known to be involved in the immune response. These changes in head transcriptome upon starvation reflect modulation of expression in some normally oscillating rhythmic genes and reduction in the resource allocation toward sexual activity and immunity.

Natural Variation of ebony Gene Controlling Thoracic Pigmentation in Drosophila melanogaster

We identified the causal genetic variation for the difference in the thoracic trident pigmentation intensity between two wild-derived strains of Drosophila melanogaster. It was found to be the difference in expression level of ebony, which codes for an enzyme in the melanin-synthesis pathway and has pleiotropic effects on vision and behavior.

Environmental Stress-Dependent Effects of Deletions Encompassing Hsp70Ba on Canalization and Quantitative Trait Asymmetry in Drosophila melanogaster

Hsp70 genes may influence the expression of wing abnormalities in Drosophila melanogaster but their effects on variability in quantitative characters and developmental instability are unclear. In this study, we focused on one of the six Hsp70 genes, Hsp70Ba, and investigated its effects on within-and among-individual variability in orbital bristle number, sternopleural bristle number, wing size and wing shape under different environmental conditions. To do this, we studied a newly constructed deletion, Df(3R)ED5579, which encompasses Hsp70Ba and nine non-Hsp genes, in the heterozygous condition and another, Hsp70Ba304, which deletes only Hsp70Ba, in the homozygous condition. We found no significant effect of both deletions on within-individual variation quantified by fluctuating asymmetry (FA) of morphological traits. On the other hand, the Hsp70Ba304/Hsp70Ba304 genotype significantly increased among-individual variation quantified by coefficient of variation (CV) of bristle number and wing size in female, while the Df(3R)ED5579 heterozygote showed no significant effect. The expression level of Hsp70Ba in the deletion heterozygote was 6 to 20 times higher than in control homozygotes, suggesting that the overexpression of Hsp70Ba did not influence developmental stability or canalization significantly. These findings suggest that the absence of expression of Hsp70Ba increases CV of some morphological traits and that HSP70Ba may buffer against environmental perturbations on some quantitative traits.

Introgression of Drosophila Simulans Nuclear Pore Protein 160 in Drosophila Melanogaster Alone Does Not Cause Inviability but Does Cause Female Sterility

We have been analyzing genes for reproductive isolation by replacing Drosophila melanogaster genes with homologs from Drosophila simulans by interspecific backcrossing. Among the introgressions established, we found that a segment of the left arm of chromosome 2, Int(2L)S, carried recessive genes for hybrid sterility and inviability. That nuclear pore protein 160 (Nup160) in the introgression region is involved in hybrid inviability, as suggested by others, was confirmed by the present analysis. Male hybrids carrying an X chromosome of D. melanogaster were not rescued by the Lethal hybrid rescue (Lhr) mutation when the D. simulans Nup160 allele was made homozygous or hemizygous. Furthermore, we uniquely found that Nup160 is also responsible for hybrid sterility. Females were sterile when D. simulans Nup160 was made homozygous or hemizygous in the D. melanogaster genetic background. Genetic analyses indicated that the D. simulans Nup160 introgression into D. melanogaster was sufficient to cause female sterility but that other autosomal genes of D. simulans were also necessary to cause lethality. The involvement of Nup160 in hybrid inviability and female sterility was confirmed by transgene experiment.

QTL analyses of spontaneous activity by using mouse strains from Mishima battery

We reported previously that spontaneous activity in the home cage is highly variable among the Mishima battery of mouse strains. In that study, NJL and KJR were found to be hyperactive strains in contrast to BLG2, which showed one of the lowest activity levels. To unravel the genetic loci involved in this behavioral phenotype, we conducted QTL analyses on backcross populations of crosses between either NJL or KJR and BLG2 strains. In the backcross of NJL to BLG2, no single locus was associated with increased spontaneous activity. In the backcross of KJR to BLG2, linkage analysis showed that a locus on the most telomeric region of Chromosome (Chr) 3 was involved in the spontaneous activity, thus named Loco1. Further linkage analysis using selected progeny carrying the allele from KJR at the Loco1 locus suggested the presence of another locus, Loco2, on Chr 17. An analysis showed that Loco1 and Loco2 interacted epistatically.

Molecular spectrum of spontaneous de novo mutations in male and female germline cells of Drosophila melanogaster.

We carried out mutation screen experiments to understand the rate and molecular nature of spontaneous de novo mutations in Drosophila melanogaster, which are crucial for many evolutionary issues, but still poorly understood. We screened for eye-color and body-color mutations that occurred in the germline cells of the first generation offspring of wild-caught females. The offspring were from matings that had occurred in the field and therefore had a genetic composition close to that of flies in natural populations. We employed 1554 F1 individuals from 374 wild-caught females for the experiments to avoid biased contributions of any particular genotype. From ∼8.6 million alleles screened, we obtained 10 independent mutants: two point mutations (one for each sex), a single deletion of ∼6 kb in a male, a single transposable element insertion in a female, five large deletions ranging in size from 40 to 500 kb in females, and a single mutation of unknown nature in a male. The five large deletions were presumably generated by nonallelic homologous recombination (NAHR) between transposable elements at different locations, illustrating the mutagenic nature of recombination. The high occurrence of NAHR that we observed has important consequences for genome evolution through the production of segmental duplications.

Genetic architecture of variation in sex-comb tooth number in Drosophila simulans

The sex comb on the forelegs of Drosophila males is a secondary sexual trait, and the number of teeth on these combs varies greatly within and between species. To understand the relationship between the intra- and interspecific variation, we performed quantitative trait locus (QTL) analyses of the intraspecific variation in sex-comb tooth number. We used five mapping populations derived from two inbred Drosophila simulans strains that were divergent in the number of sex-comb teeth. Although no QTLs were detected on the X chromosome, we identified four QTLs on the second chromosome and three QTLs on the third chromosome. While identification and estimated effects of the second-chromosome QTLs depend on genetic backgrounds, significant and consistent effects of the two third-chromosome QTLs were found in two genetic backgrounds. There were significant epistatic interactions between a second-chromosome QTL and a third-chromosome QTL, as well as between two second-chromosome QTLs. The third-chromosome QTLs are concordant with the locations of the QTLs responsible for the previously observed differences in sex-comb tooth number between D. simulans and D. mauritiana.

Starvation-Induced Elevation of Taste Responsiveness and Expression of a Sugar Taste Receptor Gene in Drosophila melanogaster

Abstract: Animals increase their feeding motivation under starved conditions. Here the authors test if the starvation-induced increase of feeding motivation is different among wild-derived strains of Drosophila melanogaster. In behavioral experiments comparing the feeding behaviors of the strains Mel6 and TW1, only TW1 exhibited a decreased feeding threshold to sucrose following a 24-h starvation period. Starved TW1 preferably ingested a low concentration of sucrose. Starved TW1 also exhibited significant elevation of taste responsiveness to low concentrations of sucrose and enhanced expression of the Gr64a sucrose sugar receptor gene. TW1 survived longer than Mel6 when provided a less nutritious food (10 mM sucrose). Thus, the starvation-induced decrease in the behavioral and the sensory thresholds could be an advantage in searching for and utilizing less nutritious foods. These results show that the starvation-induced functional change in the taste sensory system is a possible strategy for survival during starvation or suboptimal nutrient periods.