Benjamin Timakov scite author profile

Benjamin Timakov

5Publications

82Citation Statements Received

84Citation Statements Given

How they've been cited

126

How they cite others

165

Affiliations

University of Connecticut

Publications

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The hsp60B gene of Drosophila melanogaster is essential for the spermatid individualization process

Timakov

Zhang²

2001

Cell Stress Chaper

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The 60-kDa heat shock protein family (Hsp60) is found in prokaryotes, mitochondria, and chloroplasts. The Hsp60 proteins promote proper protein folding by preventing aggregation. In Drosophila melanogaster, the hsp60 gene is essential for a variety of developmental processes, beginning at early embryogenesis. In this study we show that an additional member of the Drosophila hsp60 gene family, hsp60B, is essential in male fertility. In males homozygous for a mutation of the hsp60B gene, developmental processes appeared normal throughout most of spermatogenesis, including spermatocyte growth, meiosis, and spermatid elongation. At these stages, mitochondria also displayed a differentiation process similar to wild-types. However, we found that the mutation disrupted a late stage of spermatogenesis, the spermatid individualization process. In this process, the individualization complex is assembled at spermatid nuclear heads, traverses along spermatid tails, and generates membranes for each of the spermatids in a cyst. Our analysis further shows that the individualization complex in sterile males displayed abnormal morphology as it was traveling along the spermatid tails. The Drosophila Hsp60 proteins are believed to be exclusively localized in the mitochondria. Our observation that the hsp60B mutation displayed no apparent defect in mitochondrial differentiation during spermatogenesis suggests that the Hsp60B protein may operate in a nonmitochondrial location.

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The Hsp27 gene is not required for Drosophila development but its activity is associated with starvation resistance

et al. 2007

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The Hsp27 gene is not required for Drosophila development but its activity is associated with starvation resistance

Hao¹,

Zhang²,

Timakov³

et al. 2005

Cell Stress Chaper

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Untitled

Zhang

Timakov

Stankiewicz

et al. 2000

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The Y chromosome of Drosophila melanogaster accounts for approximately 13% of a normal male genome and is entirely heterochromatic. It carries six genes required exclusively for spermatogenesis. Here we report a novel activity of the Y chromosome that regulates gene expression in primary spermatocytes. By examining the expression of a reporter gene in X/Y and X/O males, we show that a specific region of the Y long arm carries a trans-activator that regulates transcription in spermatogenesis. In the absence of the Y trans-activator, the level of the reporter expression is greatly reduced in primary spermatocytes and the expression pattern is restricted to young primary spermatocytes. Further analysis shows that the Y trans-activator is dispersed in the h1-h10 region on the Y long arm and is functionally redundant, indicating involvement of the repetitive sequences on the Y chromosome. In addition, the Y trans-activator appears to act in a tissue-specific manner, functioning only in the male germ line. We propose that the Y trans-activator plays an important role in regulating gene expression during spermatogenesis.

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Genetic Analysis of a Y-Chromosome Region That Induces Triplosterile Phenotypes and Is Essential for Spermatid Individualization in Drosophila melanogaster

Timakov

Zhang²

2000

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The heterochromatic Y chromosome of Drosophila melanogaster contains ~40 Mb of DNA but has only six loci mutable to male sterility. Region h1-h9 on YL, which carries the kl-3 and kl-5 loci, induces male sterility when present in three copies. We show that three separate segments within the region are responsible for the triplosterility and have an additive effect on male fertility. The triplosterile males displayed pleiotropic defects, beginning at early postmeiotic stages. However, the triplosterility was unaffected by kl-3 or kl-5 alleles. These data suggest that region h1-h9 is complex and may contain novel functions in addition to those of the previously identified kl-3 and kl-5 loci. The kl-3 and kl-5 mutations as well as deficiencies within region h1-h9 result in loss of the spermatid axonemal outer dynein arms. Examination using fluorescent probes showed that males deficient for h1-h3 or h4-h9 displayed a postmeiotic lesion with disrupted individualization complexes scattered along the spermatid bundle. In contrast, the kl-3 and kl-5 mutations had no effect on spermatid individualization despite the defect in the axonemes. These results demonstrate that region h1-h9 carries genetically separable functions: one required for spermatid individualization and the other essential for assembling the axonemal dynein arms.

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