Quantify environmental effects in shaping the genetic diversification pattern of Oncomelania hupensis and its implications in surveillance of human susceptibility to Schistosomiasis

The transmission and distribution of schistomiasis, one of the most serious infectious diseases in East and Southeast Asia, tied closely to its unique intermediate snail host Oncomelania hupensis. The coevolved relationships of O. hupensis populations with its parasite Schistosoma japonisum are important in understanding the mechanism of disease spread. The genetic diversification pattern within population is supposed to influence the amount of parasite loads, and the susceptibility of snails determined the chance for human or mammals to get infected. Meanwhile, intervening environmental features had been long suggested to affect snail population dynamics and evolutionary trajectories of species. However, no comprehensive study referring to the above topics has been carried out on O.hupensis populations before. In this study, we reanalyzed published data in mainland China to evaluate whether human infection rate and genetic diversification patterns are related under natural environment. Besides that, we used an array of remotely sensed image derived environmental variables to quantify the amount of variation in population genetic structure that could be explained by those factors by landscape genetic analysis. We found that human schistosomiasis infection rate is positively correlated with intra-population genetic diversification and inter-population genetic exchange, which is contradictory with the Red Queen hypothesis. The patterns of genetic diversification are better revealed when non-Euclidean, environmentally determined distance measures or features are used in large heterogeneous landscape. The impact of stream connectivity on the snail inter-population genetic distances does not so evident unless taking wetlands into calculation, and thus control activities planned solely along river systems may be suboptimal. Climate features have a stronger impact on genetic structure of snails than topology, and precipitation seasonality dominates the highest proportion of explanation in genetic diversification. Different types of genes respond different to landscape effects, and it is suspected to be related with their evolution rate. Our study raises an important opportunity for public health decision making by combining geo-informatics and bio-informatics technology. Since the schistomiasis disease persistence, establishment, and intervention optimization are dependent on the genetic diversification pattern of O.hupensis populations, and that pattern is strongly environmentally determined, then certain key environmental features or landscape distances have the potential to inform public health decisions such as where to focus surveillance efforts, or disrupt the connection to stop the gene exchange. This is especially useful for Yangze River basin region under both extensive anthropogenic activities and climate change.