We have developed new models of microbial adaptation focusing mostly on resource acquisition. Microorganisms need to acquire resources to grow, but by doing so they deplete their own source of substrate. Moreover, resource acquisition is costly for the microorganisms because they have to synthesize extra-cellular enzymes and maintain them. As a result, the amount of enzyme produced and the timing of enzyme production need to be tuned so that microorganisms get as much substrate as possible while avoiding unnecessary costs. Besides enzyme production, microbes can also recycle nutrients if they feed on nutrient poor substrates, such as some plant residues. We have developed mathematical models to describe microbial resource acquisition and how they tune both enzyme production and nutrient recycling in a way to provides them the highest benefit, ensuring sustained growth. While developing these new models, we have collected literature data on microbial growth and respiration after drying and rewetting, and found that fungal growth recovers faster than bacterial growth, and that in general recovery is slower in more acidic soil and after a longer dry period. This new data also uncovered a general recovery pattern—after it rains on a dry soil, microbes first face stressful conditions and thus focus on resisting stress, but then they shift their behavior towards resource acquisition and growth. A new dataset of soil carbon and nitrogen in fractions with different levels of accessibility to microorganisms has also been developed, and a new diagnostic model is used to interpret this data. We have also classified eco-evolutionary models of soil processes according to the way they conceptualize microbial processes, and used that to promote an agenda for developing soil and ecosystem models where microbial adaptations as well as ecological processes are taken into account.