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果蝇缺口基因 giant 通过调节产生 PTTH 的神经元来调节蜕皮激素的产生。

The Drosophila gap gene giant regulates ecdysone production through specification of the PTTH-producing neurons.

机构信息

Department of Genetics, Cell Biology and Development, University of Minnesota, Minneapolis, MN 55455, USA.

出版信息

Dev Biol. 2010 Nov 15;347(2):271-8. doi: 10.1016/j.ydbio.2010.08.011. Epub 2010 Sep 9.

Abstract

In Drosophila melanogaster, hypomorphic mutations in the gap gene giant (gt) have long been known to affect ecdysone titers resulting in developmental delay and the production of large (giant) larvae, pupae and adults. However, the mechanism by which gt regulates ecdysone production has remained elusive. Here we show that hypomorphic gt mutations lead to ecdysone deficiency and developmental delay by affecting the specification of the PG neurons that produce prothoracicotropic hormone (PTTH). The gt¹ hypomorphic mutation leads to random loss of PTTH production in one or more of the 4 PG neurons in the larval brain. In cases where PTTH production is lost in all four PG neurons, delayed development and giant larvae are produced. Since immunostaining shows no evidence for Gt expression in the PG neurons once PTTH production is detectable, it is unlikely that Gt directly regulates PTTH expression. Instead, we find that innervation of the prothoracic gland by the PG neurons is absent in gt hypomorphic larvae that do not express PTTH. In addition, PG neuron axon fasciculation is abnormal in many gt hypomorphic larvae. Since several other anteriorly expressed gap genes such as tailless and orthodenticle have previously been found to affect the fate of the cerebral labrum, a region of the brain that gives rise to the neuroendocrine cells that innervate the ring gland, we conclude that gt likely controls ecdysone production indirectly by contributing the peptidergic phenotype of the PTTH-producing neurons in the embryo.

摘要

在黑腹果蝇中,缺口基因 giant(gt)的功能缺失突变早已被证实会影响蜕皮激素的水平,导致发育迟缓,并产生体型较大(巨型)的幼虫、蛹和成虫。然而,gt 调节蜕皮激素产生的机制仍不清楚。在这里,我们表明,gt 的功能缺失突变通过影响产生促前胸腺激素(PTTH)的 PG 神经元的特化,导致蜕皮激素缺乏和发育迟缓。gt¹ 功能缺失突变导致幼虫大脑中的 4 个 PG 神经元中的一个或多个中 PTTH 产生随机丢失。在所有四个 PG 神经元中丢失 PTTH 产生的情况下,会产生发育迟缓的巨型幼虫。由于免疫染色显示,一旦可检测到 PTTH 产生,PG 神经元中就没有 Gt 的表达证据,因此 Gt 不太可能直接调节 PTTH 的表达。相反,我们发现,在不表达 PTTH 的 gt 功能缺失突变幼虫中,PG 神经元对前胸腺的神经支配缺失。此外,在许多 gt 功能缺失突变幼虫中,PG 神经元轴突的聚集是异常的。由于先前已经发现其他几个前表达的缺口基因,如 tailless 和 orthodenticle,会影响脑唇的命运,脑唇是产生支配环腺的神经内分泌细胞的大脑区域,因此我们得出结论,gt 可能通过控制产生 PTTH 的神经元的肽表型来间接控制蜕皮激素的产生。

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