Humans are not immune to evolution:

A recent symposium on evolution in Montreal posed to high-school students and university professors the following question: “Do you think that humans are still evolving?” Approximately 80% of the audience answered “no.” Indeed, there is an almost universal belief that, with multifaceted cultures and intricate technology, humans have freed themselves from the pressures of natural selection.
 
Findings, however, show otherwise. Far from providing immunity against evolutionary pressures, culture often creates new ones. For example, the genes associated with digestion of lactose are more prevalent in populations that have traditionally bred cattle and consumed milk.
 
Scientific reviews in Nature Genetics and Proceedings of the National Academy of Sciences of the United States of America, the evolutionary biologist Stephen Stearns and his colleagues set out to demonstrate that natural selection operates on contemporary humans. Supported by extensive genealogies, including centuries of church and national health registries, their argument is convincing.
 
Indeed, contrary to the widely held assumption that evolution takes millennia to manifest itself, recent evidence suggests that its effects can become visible as quickly as in a few generations. Rapid evolutionary change, or “contemporary evolution,” is not drastic; humans are not likely to sprout wings a few generations down the road. Rather, these evolutionary effects are difficult to detect, as they are reflected in a population’s genetic composition.
 
Contemporary evolution requires a specific set of conditions. First, the population must comprise individuals with varying characteristics, or traits. Moreover, members of the population must differ in terms of survival rates, including, most important, lifetime reproductive success (LRS) – the total number of offspring that they produce over a lifetime. These conditions are fundamentally linked: different values for a particular trait translate into diverse survival rates.
 
This crucial link facilitates change in a trait’s average value over successive generations. For example, if larger individuals produce more children than smaller ones, the number of larger individuals would grow, thereby increasing the average size of individuals in the population. The most significant changes occur when individuals at one end of a trait’s value are heavily favored, pushing the entire population in that direction.