Meiotic drivers are genetic variants that selfishly manipulate the production of gametes to increase their own rate of transmission, often to the detriment of the rest of the genome and the individual that carries them. This genomic conflict potentially occurs whenever a diploid organism produces a haploid stage, and can have profound evolutionary impacts on gametogenesis, fertility, individual behaviour, mating system, population survival, and reproductive isolation. Multiple research teams are developing artificial drive systems for pest control, utilising the transmission advantage of drive to alter or exterminate target species. Here, we review current knowledge of how natural drive systems function, how drivers spread through natural populations, and the factors that limit their invasion. Trends Box Both naturally occurring and synthetic "meiotic drivers" violate Mendel's law of equal segregation and can rapidly spread through populations even when they reduce the fitness of individuals carrying them. Synthetic drivers are being developed to spread desirable genes in natural populations of target species. How ecology influences the population dynamics of meiotic drivers is important for predicting the success of synthetic drive elements. An enduring puzzle concerns why some meiotic drivers persist at stable, intermediate frequencies rather than sweeping to fixation. Drivers can have a wide range of consequences from extinction to changes in mating system. preferentially associating with and moving toward the egg pole at Meiosis I) will be 75 transmitted to more than half of the maturing eggs. Although this bias does not necessarily 76 reduce the production of eggs (as only one egg matures per meiosis), the fitness of other 77 alleles at the same locus, that do not bias transmission, and alleles linked to them, is 78 reduced. Such meiotic drivers could reduce the fitness of individuals that carry them, if the 79 driving variant is genetically linked to deleterious mutations or has deleterious pleiotropic 80 effects. 81Male meiotic drive takes multiple forms -some at least partially meiotic, some entirely 82 post-meiotic -but all involve a driving element that prevents maturation or function of 83 sperm that do not contain it. Because haploid sperm within a single ejaculate compete to 84 fertilize the same pool of eggs, disabling non-carrier sperm results in transmission of the 85 driving element to more than half of the functional gametes and resulting offspring ([5], Box 86 1). However, disabling non-carrier sperm often reduces fertility [6]. 87Spore drive in fungi, in which the products of meiosis are packaged together in an ascus, 88 operates via similar mechanisms. Spores with one haploid genotype will kill or disable 89 spores of the alternative haplotype ([7], Box 1). If spores disperse long distances sibling 90 spores are unlikely to compete and killing them will not increase the killer's fitness. 91However, spore killing can be beneficial if there is local resource competition. 92Excit...
Drosophila melanogaster and its close relatives have been extremely important model species in the development of population genetic models that serve to explain patterns of diversity in natural populations, a major goal of evolutionary biology. A detailed picture of the evolutionary history of these species is beginning to emerge, as the relative importance of forces including demographic changes and natural selection is established. A continuing aim is to characterise levels of genetic diversity in a large number of populations of these species, covering a wide geographic area. We have used collections from five previously un-sampled wild populations of D. melanogaster and two of D. simulans, across three continents. We estimated levels of genetic diversity within, and divergence between, these populations, and looked for evidence of genetic structure both between ancestral and derived populations, and amongst derived populations. We also investigated the prevalence of infection with the bacterial endosymbiont Wolbachia. We found that D. melanogaster populations from Sub-Saharan Africa are the most diverse, and that divergence is highest between these and non-Sub-Saharan populations. There is strong evidence for structuring of populations between Sub-Saharan Africa and the rest of the world, and some evidence for weak structure amongst derived populations. Populations from Sub-Saharan Africa also differ in the prevalence of Wolbachia infection, with very low levels of infection compared to populations from the rest of the world.
Food security is a critical issue for many lowincome countries, particularly in Sub-Saharan Africa. Appropriately identifying and utilising local resources can provide sustainable solutions to food security problems. Insects, which are traditionally consumed in many regions of the world, represent one such resource. Insects can be nutritionally rich and therefore could be used to address issues of malnutrition. A first step towards utilising insects as a resource is identifying which ones are traditionally consumed. We present data collected between 2005 and 2012 on insects eaten by communities across Benin, West Africa. A combination of literature research, field collections, community focus groups and targeted interviews were employed. Data on four ethnic groups is presented: the Anii, Fon, Nagot and Waama. Twenty-nine arthropods species are eaten across Benin. The predominant orders are Orthoptera (48 %) and Coleoptera (41 %). New families of edible arthropods in West Africa include: Bradyporidae (Orthoptera), Coreidae (Hemiptera), Dytiscidae (Coleoptera), Ixodidae (Acari). Insect collection is an ancestral tradition in all the described communities: however, there are considerable differences in preferences and collection methods among ethnic groups. Currently there is little valorisation of insects as a food product in Benin, in contrast to neighbouring countries. In light of considerable malnutrition in Benin among young children, promoting this tradition and implementing small scale captive rearing of selected species could improve food security.
Selfish genetic elements such as selfish chromosomes increase their transmission rate relative to the rest of the genome and can generate substantial cost to the organisms that carry them. Such segregation distorters are predicted to either reach fixation (potentially causing population extinction) or, more commonly, promote the evolution of genetic suppression to restore transmission to equality. Many populations show rapid spread of segregation distorters, followed by the rapid evolution of suppression. However, not all drivers display such flux, some instead persisting at stable frequencies in natural populations for decades, perhaps hundreds of thousands of years, with no sign of suppression evolving or the driver spreading to fixation. This represents a major evolutionary paradox. How can drivers be maintained in the long term at stable frequencies? And why has suppression not evolved as in many other gene drive systems? Here, we explore potential factors that may explain the persistence of drive systems, focusing on the ancient sex-ratio driver in the fly Drosophila pseudoobscura . We discuss potential solutions to the evolutionary mystery of why suppression does not appear to have evolved in this system, and address how long-term stable frequencies of gene drive can be maintained. Finally, we speculate whether ancient drivers may be functionally and evolutionarily distinct to young drive systems.
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