Dispersal, density dependence, and population dynamics of a fungal microbe on leaf surfaces.

Despite the ubiquity and importance of microbes in nature, little is known about their natural population dynamics, especially for those that occupy terrestrial habitats. Here we investigate the dynamics of the yeast-like fungus Aureobasidium pullulans (Ap) on apple leaves in an orchard. We asked three questions.

The WiscDsLox T-DNA collection: an arabidopsis community resource generated by using an improved high-throughput T-DNA sequencing pipeline.

We have developed a new community resource, called the WiscDsLox collection, for performing reverse-genetic analysis in arabidopsis. This resource is composed of 10,459 T-DNA lines generated using the Arabidopsis thaliana ecotype Columbia. The flanking sequence tag for each T-DNA insertion has been deposited in public databases, and seed for each line is currently available from the Arabidopsis Biological Resource Center.

The synergistic effects of stochasticity and dispersal on population densities.

Using laboratory experiments, simulation models, and analytical techniques, we examined the impact of dispersal on the mean densities of patchily distributed populations. Even when dispersal leads to no net additions or removals of individuals from a population, it may nonetheless increase mean population densities if the net immigration rate is positive when populations are growing and negative when they are declining. As a model system for exploring this phenomenon, we used the yeastlike fungus Aureobasidium pullulans.

Single-leaf resolution of the temporal population dynamics of Aureobasidium pullulans on apple leaves.

The abundance of phylloplane microorganisms typically varies over several orders of magnitude among leaves sampled concurrently. Because the methods traditionally used to sample leaves are destructive, it has remained unclear whether this high variability is due to fixed differences in habitat quality among leaves or to asynchronous temporal variation in the microbial population density on individual leaves. We developed a novel semidestructive assay to repeatedly sample the same apple leaves from orchard trees over time by removing progressively more proximal approximately 1-cm-wide transverse segments.