New Possibilities for Evaluating the Development of Age-Related Pathologies Using the Dynamical Network Biomarkers Theory.

Aging is the slowest process in a living organism. During this process, mortality rate increases exponentially due to the accumulation of damage at the cellular level. Cellular senescence is a well-established hallmark of aging, as well as a promising target for preventing aging and age-related diseases.

Musashi expression in intestinal stem cells attenuates radiation-induced decline in intestinal permeability and survival in Drosophila.

Exposure to genotoxic stress by environmental agents or treatments, such as radiation therapy, can diminish healthspan and accelerate aging. We have developed a Drosophila melanogaster model to study the molecular effects of radiation-induced damage and repair. Utilizing a quantitative intestinal permeability assay, we performed an unbiased GWAS screen (using 156 strains from the Drosophila Genetic Reference Panel) to search for natural genetic variants that regulate radiation-induced gut permeability in adult D.

Dietary restriction improves intestinal cellular fitness to enhance gut barrier function and lifespan in D. melanogaster.

Loss of gut integrity is linked to various human diseases including inflammatory bowel disease. However, the mechanisms that lead to loss of barrier function remain poorly understood. Using D.

Proteasome activity determines pupation timing through the degradation speed of timer molecule Blimp-1.

The transcriptional repressor Blimp-1 is a labile protein. This characteristic is key for determining pupation timing because the timing of the disappearance of Blimp-1 affects pupation timing by regulating the expression of its target βftz-f1. However, the molecular mechanisms that regulate the protein turnover of Blimp-1 are still unclear.

A biological timer in the fat body comprising Blimp-1, βFtz-f1 and Shade regulates pupation timing in Drosophila melanogaster.

During the development of multicellular organisms, many events occur with precise timing. In Drosophila melanogaster, pupation occurs about 12 h after puparium formation and its timing is believed to be determined by the release of a steroid hormone, ecdysone (E), from the prothoracic gland. Here, we demonstrate that the ecdysone-20-monooxygenase Shade determines pupation timing by converting E to 20-hydroxyecdysone (20E) in the fat body, which is the organ that senses nutritional status.

Peripheral Circadian Clocks Mediate Dietary Restriction-Dependent Changes in Lifespan and Fat Metabolism in Drosophila.

Endogenous circadian clocks orchestrate several metabolic and signaling pathways that are known to modulate lifespan, suggesting clocks as potential targets for manipulation of metabolism and lifespan. We report here that the core circadian clock genes, timeless (tim) and period (per), are required for the metabolic and lifespan responses to DR in Drosophila. Consistent with the involvement of a circadian mechanism, DR enhances the amplitude of cycling of most circadian clock genes, including tim, in peripheral tissues.

Autocrine regulation of ecdysone synthesis by β3-octopamine receptor in the prothoracic gland is essential for Drosophila metamorphosis.

In Drosophila, pulsed production of the steroid hormone ecdysone plays a pivotal role in developmental transitions such as metamorphosis. Ecdysone production is regulated in the prothoracic gland (PG) by prothoracicotropic hormone (PTTH) and insulin-like peptides (Ilps). Here, we show that monoaminergic autocrine regulation of ecdysone biosynthesis in the PG is essential for metamorphosis.

The binding of multiple nuclear receptors to a single regulatory region is important for the proper expression of EDG84A in Drosophila melanogaster.

Nuclear receptor transcription factor family members share target sequence similarity; however, little is known about how these factors exert their specific regulatory control. Here, we examine the mechanism regulating the expression of the Drosophila EDG84A gene, a target gene of the orphan nuclear receptor βFTZ-F1, as a model to study the cooperative behavior among nuclear receptors. We show that the three nuclear receptors βFTZ-F1, DHR3, and DHR39 bind to a common element in the EDG84A promoter.

Regulatory mechanisms of ecdysone-inducible Blimp-1 encoding a transcriptional repressor that is important for the prepupal development in Drosophila.

Blimp-1 is an ecdysone-inducible transcription factor that is expressed in the early stage of the prepupal period. The timing of its disappearance determines expression timing of the FTZ-F1 gene, whose temporally restricted expression is essential for the prepupal development. To elucidate the termination mechanism of Blimp-1 gene expression, we examined the regulation of the Blimp-1 gene using an organ culture system.

Drosophila Blimp-1 is a transient transcriptional repressor that controls timing of the ecdysone-induced developmental pathway.

Regulatory mechanisms controlling the timing of developmental events are crucial for proper development to occur. ftz-f1 is expressed in a temporally regulated manner following pulses of ecdysteroid and this precise expression is necessary for the development of Drosophila melanogaster. To understand how insect hormone ecdysteroids regulate the timing of FTZ-F1 expression, we purified a DNA binding regulator of ftz-f1.