特定的突触前功能需要不同的果蝇Cav2剪接异构体。

IF 6.4 1区生物学 Q1 BIOLOGY

eLife Pub Date : 2025-02-14 DOI:10.7554/eLife.100394

Christopher Bell, Lukas Kilo, Daniel Gottschalk, Jashar Arian, Lea Deneke, Hanna Kern, Christof Rickert, Oliver Kobler, Julia Strauß, Martin Heine, Carsten Duch, Stefanie Ryglewski

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引用次数: 0

摘要

在许多脊椎动物突触中，突触前功能是通过不同的Cav2通道的表达来调节的。大多数无脊椎动物的基因组只包含一个Cav2基因。果蝇Cav2同源物cacophony （cac）诱导突触前活性区（AZs）的突触囊泡释放。我们假设果蝇的cac功能多样性是由两个相互排斥的外显子对增强的，这两个外显子对在脊椎动物中不保守，一个在电压传感器中，一个在环结合Caβ和Gβγ亚基。我们发现在电压传感器中选择剪接会影响通道激活电压。只有具有较高激活电压的异构体定位于谷氨酸能果蝇幼虫神经肌肉连接处的AZs，并且对正常的突触功能是必需的。相比之下，另一对外显子的选择性剪接调节了突触前功能的多个方面。当一个外显子的表达产生正常传输时，另一个外显子的表达减少了AZ中的通道数，从而减少了释放概率。这也消除了突触前的内稳态可塑性。此外，通道数的减少影响了短期塑性，可通过增加外部钙浓度来匹配释放概率来控制。总之，在果蝇中，选择性剪接提供了一种仅通过一个Cav2基因调节突触前功能不同方面的机制。

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Specific presynaptic functions require distinct Drosophila Ca_v2 splice isoforms.

At many vertebrate synapses, presynaptic functions are tuned by expression of different Ca_v2 channels. Most invertebrate genomes contain only one Ca_v2 gene. The Drosophila Ca_v2 homolog, cacophony (cac), induces synaptic vesicle release at presynaptic active zones (AZs). We hypothesize that Drosophila cac functional diversity is enhanced by two mutually exclusive exon pairs that are not conserved in vertebrates, one in the voltage sensor and one in the loop binding Ca_β and G_βγ subunits. We find that alternative splicing in the voltage sensor affects channel activation voltage. Only the isoform with the higher activation voltage localizes to AZs at the glutamatergic Drosophila larval neuromuscular junction and is imperative for normal synapse function. By contrast, alternative splicing at the other alternative exon pair tunes multiple aspects of presynaptic function. While expression of one exon yields normal transmission, expression of the other reduces channel number in the AZ and thus release probability. This also abolishes presynaptic homeostatic plasticity. Moreover, reduced channel number affects short-term plasticity, which is rescued by increasing the external calcium concentration to match release probability to control. In sum, in Drosophila alternative splicing provides a mechanism to regulate different aspects of presynaptic functions with only one Ca_v2 gene.

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来源期刊

eLife BIOLOGY-

CiteScore

12.90

自引率

3.90%

发文量

3122

审稿时长

17 weeks

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