A large proportion of precipitation formation is governed by the cold cloud processes associated with cloud ice, snow, graupel and hail particles. Heterogeneous ice nucleation occurs through a subset of the atmospheric aerosols called ice nuclei (IN), which are generally insoluble particles, such as certain mineral dusts, soot, as well as some biological materials that include bacteria, pollen, sport etc. Many laboratory and observational studies demonstrate that bio-aerosols have the unique capability of catalyzing ice formation at relatively warm environment by means of heterogeneous nucleation processes. In this endeavor, sensitivity of cold cloud microphysical processes to bio-aerosols has been tested for one rainfall event. A non-hydrostatic mesoscale cloud model (MM5) has been used for this simulation. This model is modified by including the two-moment warm-cloud parameterization of Chen and Liu (2004; hereafter as the “CL-scheme”) which considers the effect of condensation nuclei (CN) and explicitly predicts the masses and numbers of cloud drops and raindrops (Cheng et al., 2007a). The warm cloud scheme is further coupled with the ice-phase processes of Reisner et al. (1998) by Cheng et al. (2007b), here denoted as the “CLR-scheme,” to examine the importance of ice processes on precipitation formation. Furthermore, the diagnostic formula of heterogeneous ice nucleation in the Reisner scheme is replaced with new prognostic formulas to allow the inclusion of different types of ice nuclei, such as biological aerosols and mineral dust, and their conversion into ice particles. The simulation results indicate that ice nucleation intensity is limited by available water vapor, and precipitation enhancement varies nonlinearly with IN concentration. As they can be nucleated at higher temperature, bio-aerosols increase the total ice and rain water mixing ratio and contribute to precipitation more efficiently than dust or other natural IN. Thus, bio-aerosols play a key role in precipitation process especially over densely vegetated area.