Abstract
The sperm’s crucial function is to locate and fuse with a mature oocyte. Under laboratory conditions, Caenorhabditis elegans sperm are very efficient at navigating the hermaphrodite reproductive tract and locating oocytes. Here, we identify chemosensory and oxygen-sensing circuits that affect the sperm’s navigational capacity. Multiple Serpentine Receptor B (SRB) chemosensory receptors regulate Gα pathways in gustatory sensory neurons that extend cilia through the male nose. SRB signaling is necessary and sufficient in these sensory neurons to influence sperm motility parameters. The neuropeptide Y pathway acts together with SRB-13 to antagonize negative effects of the GCY-35 hyperoxia sensor on spermatogenesis. SRB chemoreceptors are not essential for sperm navigation under low oxygen conditions that C. elegans prefers. In ambient oxygen environments, SRB-13 signaling impacts gene expression during spermatogenesis and the sperm’s mitochondria, thereby increasing migration velocity and inhibiting reversals within the hermaphrodite uterus. The SRB-13 transcriptome is highly enriched in genes implicated in pathogen defense, many of which are expressed in diverse tissues. We show that the critical time period for SRB-13 signaling is prior to spermatocyte differentiation. Our results support the model that young C. elegans males sense external environment and oxygen tension, triggering long-lasting downstream signaling events with effects on the sperm’s mitochondria and navigational capacity. Environmental exposures early in male life may alter sperm function and fertility.
Highlights
Animals employ sexual reproduction to increase genetic diversity critical for adapting to changing environments [1,2,3]
The nematode C. elegans is a powerful genetic model to investigate the relationship between environment and male fertility
We identified multiple serpentine receptor B (SRB) chemosensory receptors that are expressed in amphid sensory neurons, which extend cilia through the male nose
Summary
Animals employ sexual reproduction to increase genetic diversity critical for adapting to changing environments [1,2,3]. An essential process is fertilization, the merging of sperm and oocyte [4, 5]. The motile spermatozoa (referred to as sperm) is a highly specialized cell built for finding and fusing with a competent oocyte. This task is difficult in female animals where fertilization occurs internally, due to the reproductive tract’s convoluted architecture [6, 7]. Sperm must successfully navigate through the tract in coordination with oocyte meiotic progression and compete with other sperm [8, 9]. Sperm motility is critical for navigation and competitive performance, yet varies extensively between, and within, species [12, 13]. Beyond sperm competition forces, what drives these performance differences is not clear [9]
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