Most of the world's fisheries are over-exploited and it seems inevitable that fish-farming will largely replace fishing, just as livestock arming has replaced hunting as the main source of food from land animals. Unfortunately, many farmed fish, such as salmon, are themselves predators and need to be fed on fish meal. Tilapia are tropical freshwater fish that can be grown largely on vegetable matter and agricultural waste and so promise much for future sustainable production. Global tilapia production grew 280 percent over the 10 years to 2012, with a harvest of ~4.5 million tonnes, more than 5 times greater than the entire UK fishery and aquaculture industry. Tilapia is now a $7.6 billion dollar industry. Most tilapia production is based on a handful of strains, but there are more than 50 wild species throughout Africa which could harbour valuable genes for growth, disease resistance, temperature & salt tolerance etc. Many tilapia will hybridize readily, so that the natural genetic traits could easily be bred into farmed strains without the need for GM technology. However, this feature also renders them vulnerable to genetic swamping by stocking with alien farmed strains into natural water bodies, a practice now widespread in Africa. At present, little is known of the status of wild tilapia strains, and international agencies seem to be largely unaware that widespread stocking is in progress, and there is little appreciation of its possible consequences. We propose to survey the natural tilapia diversity of Tanzania, a particular hotspot for wild tilapia strains. We will assess the effects of stocking at the molecular genetic level through sequencing the genomes of native and stocked forms. We will locate pure stocks of native forms and make recommendations for their conservation in-situ and ex-situ (e.g. in pond culture or sperm banks). We will estimate the growth rates of pure and hybrid forms in their natural habitats using scale rings and relate these to particular genetic traits, making predictions of the likely genetic consequences of stocking. We will also investigate the ecological niches of pure and hybrid strains from stable isotope ratios. It is possible that genetic material from native strains is actually helping hybrid forms to establish themselves, or indeed that the stocked forms may be failing to get established, perhaps in some habitats, if not supplemented by regular stocking programmes. We will develop quick molecular diagnostic tests of hybridization for the benefit of fishery managers in other locations, and use these to calibrate simple visual methods to identify hybrids in the field. The genome sequence information of all of these tilapia strains will be deposited in online public databases, where it will provide a major resource for future studies in tilapia strain development and conservation. We will also advise the government of Tanzanian and international agencies such as WorldFish about remaining pure populations of native strains to prioritise their conservation. This be backed up by depositing tissue/sperm samples for long-term deep-freeze storage, so that these unique and endangered genetic resources might be available to breeders seeking to improve tilapia strains in the future.