The effects of atrazine on the microbiome of the eastern oyster: Crassostrea virginica.

Long-standing evidence supports the importance of maintaining healthy populations of microbiota for the survival, homeostasis, and complete development of marine mollusks. However, the long-term ecological effects of agricultural runoff on these populations remains largely unknown. Atrazine (6-Chloro-n-ethyl-n'-(1-methylethyl)-triazine-2,4-diamine), a prevalent herbicide in the United States, is often used along tributaries of the Chesapeake Bay where oyster breeding programs are concentrated. To investigate any potential effects atrazine maybe having on mollusk-prokaryote interactions, we used 16S rRNA gene amplicons to evaluate how microbial compositions shift in response to exposure of environmentally relevant concentrations of atrazine previously found within the Chesapeake Bay. The dominant bacterial genera found within all groups included those belonging to Pseudoalteromonas, Burkholderia, Bacteroides, Lactobacillis, Acetobacter, Allobaculum, Ruminococcus, and Nocardia. Our results support previously published findings of a possible core microbial community in Crassostrea virginica. We also report a novel finding: oysters exposed to atrazine concentrations as low as 3 µg/L saw a significant loss of a key mutualistic microbial species and a subsequent colonization of a pathogenic bacteria Nocardia. We conclude that exposure to atrazine in the Chesapeake Bay may be contributing to a significant shift in the microbiomes of juvenile oysters that reduces fitness and impedes natural and artificial repopulation of the oyster species within the Bay.

Spontaneous mobilization of integrated recombinant adenoassociated virus in a cell culture model of virus latency.

A cell line containing integrated recombinant adenoassociated virus (AAV) was investigated for spontaneous mobilization of vector sequence. Detection of these rare events was facilitated by using a vector design that allowed the circular rescue product (cAAV) to be individually scored by bacterial transformation. Restriction and sequence analysis of captured clones revealed five highly ordered classes of cAAV, each of which contained a defined segment of the integrated vector locus. A common feature of all cAAV classes was the presence of a modified inverted terminal repeat that joined the ends of the liberated sequence. Assembly of extrachromosomal vector genomes was accompanied by deletions in the integration locus that could be mapped to one of the five cAAV classes, suggesting an excision-type mechanism. We propose that the spontaneous deletion and mobilization of vector sequence from the recombinant adenoassociated virus (rAAV) integration locus is mediated by a recombination event between the inverted terminal repeats that define the boundaries of the individual genome subunits.