Person:

Stern, Linda

Bacterial flagellar filaments grow at their distal ends, from flagellin that travels through a central channel (\sim 2 nm) in diameter. The flagellin is extruded from the cytoplasm by a pump powered by a proton motive force (PMF). We measured filament growth in cells near the mid-exponential-phase with flagellin bearing a specific cysteine-for-serine substitution, allowing filaments to be labeled with sulfhydryl-specific fluorescent dyes. We labeled filaments first with a green maleimide dye and then, following an additional period of growth, with a red maleimide dye. The contour lengths of the green and red segments were measured. The average lengths of red segments ((2.3 \mu m)) were the same regardless of the lengths of the green segments from which they grew (ranging from less than 1 to more than (9 \mu m) in length). Thus, flagellar filaments do not grow at a rate that decreases exponentially with length, as formerly supposed. If flagellar filaments were broken by viscous shear, the broken filaments continued to grow. Identical results were obtained whether flagellin was expressed from fliC on the chromosome under the control of its native promoter or on a plasmid under the control of the arabinose promoter.

Genetic variation in Avpr1a, the locus encoding the arginine vasopressin receptor 1A (V1aR), has been implicated in pair-bonding behavior in voles (genus Microtus) and humans, raising the possibility that this gene may contribute commonly to mating-system variation in mammals. In voles, differential expression of V1aR in the brain is associated with male partner–preference behavior in a comparison of a monogamous (Microtus ochrogaster) and promiscuous (Microtus montanus) species. This expression difference is correlated, in turn, with a difference in length of a 5′ regulatory microsatellite in Avpr1a. Here, we use a combination of comparative sequencing of coding and regulatory regions, analysis of neural expression patterns, and signaling assays to test for differences in V1aR expression and function among eight species of deer mice (genus Peromyscus). Despite well-documented variation in Peromyscus social behavior, we find no association between mating system and length variation in the microsatellite locus linked to V1aR expression in voles. Further, there are no consistent differences in V1aR expression pattern between monogamous and promiscuous species in regions of the brain known to influence mating behavior. We do find statistical evidence for positive selection on the V1aR coding sequence including several derived amino acid substitutions in a monogamous Peromyscus lineage, yet these substitutions have no measurable effect on V1aR signaling activity. Together, these results suggest that mating-system variation in rodents is mediated by multiple genetic mechanisms.