Abstract
The propulsion of sperm cells via movement of the flagellum is of vital importance for successful fertilization. While the exact mechanism of energy production for this movement varies between species, in avian species energy is thought to come predominantly from the mitochondria located in the sperm midpiece. Larger midpieces may contain more mitochondria, which should enhance the energetic capacity and possibly promote mobility. Due to an inversion polymorphism on their sex chromosome TguZ, zebra finches (Taeniopygia guttata castanotis) exhibit large within-species variation in sperm midpiece length, and those sperm with the longest midpieces swim the fastest. Here, we test through quantitative real-time PCR in zebra finch ejaculates whether the inversion genotype has an effect on the copy number of mitochondrial DNA (mtDNA). We find that zebra finches carrying the derived allele (correlated with longer sperm midpieces) have more copies of the mtDNA in their ejaculates than those homozygous for the ancestral allele (shorter midpieces). We suggest downstream effects of mtDNA copy number variation on the rate of adenosine triphosphate production, which in turn may influence sperm swimming speed and fertilization success. Central components of gamete energy metabolism may thus be the proximate cause for a fitness-relevant genetic polymorphism, stabilizing a megabase-scale inversion at an intermediate allele frequency in the wild.
Highlights
The propulsion of sperm cells via movement of the flagellum is of vital importance for successful fertilization
A negative relationship between mitochondrial DNA copy number and sperm velocity has been observed across mammalian species, which may be due to increased reactive oxygen species (ROS) production [11,13,19,20,21,22,23,24]
Because sperm midpiece length correlates with adenosine triphosphate (ATP) content in whole ejaculates across songbirds, it has been hypothesized that a larger number of mitochondria contributes to the syncytium in longer midpieces [28]
Summary
The propulsion of sperm cells via movement of the flagellum is of vital importance for successful fertilization. A negative relationship between mitochondrial DNA (mtDNA) copy number and sperm velocity has been observed across mammalian species, which may be due to increased reactive oxygen species (ROS) production [11,13,19,20,21,22,23,24] Avian species use both OXPHOS and glycolysis for energy production in sperm cells (studied in Galliformes [25,26]). The intermediate allele frequency of the ancestral inversion haplotype in a wild Australian population (59.6%; [35]) might be explained by this heterotic effect Taken together, this makes the zebra finch a suitable model to study the link between sperm design and swimming speed and unravel the mechanism behind the relationship between inversion genotype, midpiece length and sperm velocity.
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