Fine-scale genetic structure and dispersal distance in the harvester ant Pogonomyrmex barbatus.

Dispersal has important genetic and evolutionary consequences. It is notoriously difficult to study in some ant species, because reproductives fly from parent nests to mating aggregations and then to new nest sites. We used genetic techniques to measure dispersal distance and characterize patterns of genetic variation in a population of the harvester ant Pogonomyrmex barbatus. This population consists of two interdependent yet genetically distinct mitochondrial lineages, each associated with specific alleles at nuclear loci. We found moderate levels of genetic structure for both lineages and a significant pattern of isolation by distance when individual colonies were the operational unit of study. Dispersal distances calculated from the slope of the regression of genetic on geographic distance were 65.3 m for J1 and 85.8 m for J2. These results are consistent with previous observations of many mating aggregations over small geographic areas. In dependent-lineage populations like our study population, females must mate with males of the opposite lineage to produce workers, and with males of the same lineage to produce female reproductives. Because lineage ratios differ from 1:1 throughout the southwestern United States, restricted dispersal between sites with different lineage ratios could have important effects on dependent-lineage population dynamics. Our results suggest that it is unlikely that many individuals disperse from areas dominated by one lineage to areas dominated by another. Short dispersal distances lead to low gene flow, giving local populations evolutionary independence.

Microbially treated peat-cellulose fabric as a biodegradable oil-collection cloth.

The aim of this work was to study the use of a fully biodegradable peat-cellulose fabric as a first aid in collecting and removing spilled oil. The fabric itself was made from entirely biodegradable natural components. Another aspect investigated was whether drying microbial suspension--specifically enriched for the degradation of oil hydrocarbons while maintaining a high survival rate and rapid initial growth--to the fabric would improve the degradation of absorbed oil along with the fabric. The results show that the oil absorption capacity of the biodegradable fabric was comparable to commercial products, and that the oil absorbed to the fabric degraded readily when incubated at various conditions. The microbial inoculum enhanced the degradation rate to some degree in sand, but in garden soil no significant difference existed. It was concluded that an oily fabric can be disposed of by biodegradation, e.g., by composting, but that a microbial inoculum is not essential for this purpose.

Use of a by-product of peat excavation, cotton grass fibre, as a sorbent for oil-spills.

The sorbents used to collect oil in case of oil-spills are mostly synthetic, which limits the possibilities of their disposal. We studied the absorption capacities and rates of cotton grass fibre, a by-product of peat excavation, and cotton grass mats for several oil types and compared them with a synthetic, commercially available oil sorbent. We found cotton grass fibre to have superior absorption properties: Cotton grass sorbent absorbed oil approximately two to three times as much, and two to three times as fast as the synthetic one. Cotton grass fibre absorbed no measurable amount of water in the conditions used in the tests making it ideal for absorbing oil from the surface of water. In removing diesel oil from the surface of water, the efficiency was over 99% up to an absorbing factor of 20 times its own weight. The biodegradable cotton grass fibre proved to be an effective oil sorbent with low raw-material costs.