Additional taxonomic coverage of the doubly uniparental inheritance in bivalves: Evidence of sex-linked heteroplasmy in the razor clam Solen marginatus Pulteney, 1799, but not in the lagoon cockle Cerastoderma glaucum (Bruguière, 1789)

In animals, doubly uniparental inheritance (DUI) is a major exception to the common strict maternal inheritance of mitochondria. To date, DUI has only been found in many bivalve species, but its distribution is still unclear. Given the great species richness of the class, much effort is needed to further investigate the occurrence of DUI in unsampled species. A compelling evidence of DUI is generally the presence of a sex-linked heteroplasmy, where two divergent mitochondrial lineages are found: One is isolated from the male germline, and the other one is isolated from the female germline and, normally, from the soma of both sexes. In the present study, we investigated the sex-linked heteroplasmy in the razor clam Solen marginatus Pulteney, 1799 and in the lagoon cockle Cerastoderma glaucum (Bruguière, 1789) using two mitochondrial markers (cox1 and rrnL). We found evidence of DUI in the species S. marginatus, with a divergence up to 21% for the rrnL gene, but not in C. glaucum. Moreover, our phylogenetic reconstruction includes all the available data for heterodont species with sex-linked heteroplasmy and suggests multiple origins of DUI in this subclass, as well as the presence of DUI in other species of the genus Solen.     

Genetic Structure of Japanese Scallop Population in Hokkaido, Analyzed by Mitochondrial Haplotype Distribution

To examine the genetic structure of Japanese scallop populations (Mizuhopecten yessoensis) in Hokkaido prefecture, Japan, and compare it with those in the Aomori prefecture, we applied a method for lineage analysis based on sequence variation in a mitochondrial DNA segment (NcR2). After showing that there was a low probability of doubly uniparental inheritance of mitochondrial DNA in the scallop, we sequenced the NcR2 regions of 914 individuals from 15 populations (13 in Hokkaido and 2 in Aomori). In total, 103 different haplotypes were detected. Results of homogeneity tests for pairwise populations and the fixation indices indicated that significant heterogeneity (P < 0.0005) and structuring (pairwise fixation index F_ST = 0.1606–0.4444, P = 0.0000; fixation index among groups F_CT = 0.1549, P = 0.0078) could be inferred between the Hokkaido and Aomori groups, but not among populations within the groups. Moreover, heterogeneity of the haplotype distribution between populations of the 1980s and 1990s or 2000s at the 4 culturing areas was not observed (P > 0.05), and the haplotype diversity between them was not significant (P = 0.05), suggesting that the culture operations had not imparted a significant effect on the genetic structure during these periods.     

Mitochondrial membrane potential: a trait involved in organelle inheritance?

Which mitochondria are inherited across generations? Are transmitted mitochondria functionally silenced to preserve the integrity of their genetic information, or rather are those mitochondria with the highest levels of function (as indicated by membrane potential Δψm) preferentially transmitted? Based on observations of the unusual system of doubly uniparental inheritance of mitochondria and of the common strictly maternal inheritance mode, I formulate a general hypothesis to explain which mitochondria reach the primordial germ cells (PGCs), and how this happens. Several studies indicate that mitochondrial movements are driven by microtubules and that mitochondria with high Δψm are preferentially transported. This can be applied also to the mitochondria that eventually populate embryonic PGCs, so I propose that Δψm may be a trait that allows for the preferential transmission of the most active (and healthy) mitochondria. The topics discussed here are fundamental in cell biology and genetics but remain controversial and a subject of heated debate; I propose an explanation for how a Δψm-dependent mechanism can cause the observed differences in mitochondrial transmission.