Although successful fertilization depends on timely encounters between sperm and egg, the decoupling of mating and fertilization often confers reproductive advantages to internally fertilizing animals. In several vertebrate groups, postcopulatory sperm viability is prolonged by storage in specialized organs within the female reproductive tract. In birds, ejaculated sperm can be stored in a quiescent state within oviductal sperm storage tubules (SSTs), thereby retaining fertilizability for up to 15 weeks at body temperature (41 °C); however, the mechanism by which motile sperm become quiescent within SSTs is unknown. Here, we show that low oxygen and high lactic acid concentrations are established in quail SSTs. Flagellar quiescence was induced by lactic acid in the concentration range found in SSTs through flagellar dynein ATPase inactivation following cytoplasmic acidification (
This study was conducted to investigate the role of a sperm-borne compound in oocyte activation in special reference to the time when oocyte activation is required by testicular cells during spermatogenesis in quail. First, effects of a microinjection of quail sperm extract (SE) and quail phospholipase Czeta (PLCzeta) cRNA into quail oocytes were assessed by observation of pronuclear formation and cytoplasmic segmentation, respectively. Secondly, the effects of a microinjection of round spermatids with or without PLCzeta cRNA into quail oocytes were studied by observation of development. When the oocytes were injected with SE at 0.13 mg protein/ml, both pronuclear formation and cytoplasmic segmentation were optimally induced. However, pronuclear formation was blocked when SE was pretreated with heat or when the oocyte was pretreated with BAPTA (a Ca(2+) chelator) before SE injection. On the other hand, when the oocytes were injected with PLCzeta cRNA at 60 microg/ml, not only pronuclear formation but also cytoplasmic segmentation were optimally induced. However, PLCzeta cRNA-induced pronuclear formation was blocked by pretreatment with cycloheximide (an inhibitor of protein synthesis) or with BAPTA. Most interestingly, round spermatids alone cannot induce blastodermal development but microinjection of a round spermatid with PLCzeta cRNA can induce development. In addition, RT-PCR revealed that PLCzeta mRNA is expressed in elongated spermatids and testicular sperm but not in round spermatids. It is concluded that PLCzeta is a functional sperm factor for oocyte activation to initiate resumption of meiotic division in quail and its potency is acquired after elongated spermatid formation during the spermatogenesis.
The aim of the present study was to improve the efficiency of endogenous primordial germ cell (PGC) depletion and to increase the ratio of donor PGCs in the gonads of recipient chicken embryos. A sustained-release emulsion was prepared by emulsifying equal amounts of Ca(2+)- and Mg(2+)-free phosphate-buffered saline containing 10% busulfan solubilised in N,N-dimethylformamide and sesame oil, using a filter. Then, 75 microg per 50 microL busulfan sustained-release emulsion was injected into the yolk. To determine the depletion and repopulation of PGCs in the gonads after 6 days incubation, whole-mount immunostaining was performed. The busulfan sustained-release emulsion significantly reduced the number of endogenous PGCs compared with control (P < 0.05). Moreover, the busulfan sustained-release emulsion significantly depleted endogenous PGCs compared with other previously reported busulfan delivery systems (P < 0.05), but with less variation, suggesting that the sustained-release emulsion delivered a consistent amount of busulfan to the developing chicken embryos. The PGC transfer study showed that the proportion of donor PGCs in the gonads of busulfan sustained-release emulsion-treated embryos after 6 days incubation increased 28-fold compared with control. In conclusion, the results demonstrate that exogenous PGCs are capable of migrating and settling in gonads from which endogenous PGCs have been removed using a busulfan sustained-release emulsion.
In temperate zones, animals restrict breeding to specific seasons to maximize the survival of their offspring. Birds have evolved highly sophisticated mechanisms of seasonal regulation, and their testicular mass can change 100-fold within a few weeks. Recent studies on Japanese quail revealed that seasonal gonadal development is regulated by central thyroid hormone activation within the hypothalamus, depending on the photoperiodic changes. By contrast, the mechanisms underlying seasonal testicular regression remain unclear. Here we show the effects of short day and low temperature on testicular regression in quail. Low temperature stimulus accelerated short day-induced testicular regression by shutting down the hypothalamus-pituitary-gonadal axis and inducing meiotic arrest and germ cell apoptosis. Induction of T3 coincided with the climax of testicular regression. Temporal gene expression analysis over the course of apoptosis revealed the suppression of LH response genes and activation of T3 response genes involved in amphibian metamorphosis within the testis. Daily ip administration of T3 mimicked the effects of low temperature stimulus on germ cell apoptosis and testicular mass. Although type 2 deiodinase, a thyroid hormone-activating enzyme, in the brown adipose tissue generates circulating T3 under low-temperature conditions in mammals, there is no distinct brown adipose tissue in birds. In birds, type 2 deiodinase is induced by low temperature exclusively in the liver, which appears to be caused by increased food consumption. We conclude that birds use low temperature-induced circulating T3 not only for adaptive thermoregulation but also to trigger apoptosis to accelerate seasonal testicular regression.
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