Nuclear import of serum response factor in airway smooth muscle.

We have previously shown that the transcription-promoting activity of serum response factor (SRF) is partially regulated by its extranuclear redistribution. In this study, we examined the cellular mechanisms that facilitate SRF nuclear entry in canine tracheal smooth muscle cells. We used in vitro pull-down assays to determine which karyopherin proteins bound SRF and found that SRF binds KPNA1 and KPNB1 through its nuclear localization sequence. Immunoprecipitation studies also demonstrated direct SRF-KPNA1 interaction in HEK293 cells. Import assays demonstrated that KPNA1 and KPNB1 together were sufficient to mediate rapid nuclear import of SRF-GFP. Our studies also suggest that SRF is able to gain nuclear entry through an auxiliary, nuclear localization sequence-independent mechanism.

Gene-environment interactions in a mutant mouse kindred with native airway constrictor hyperresponsiveness.

We mutagenized male BTBR mice with N-ethyl-N-nitrosourea and screened 1315 of their G3 offspring for airway hyperresponsiveness. A phenovariant G3 mouse with exaggerated methacholine bronchoconstrictor response was identified and his progeny bred in a nonspecific-pathogen-free (SPF) facility where sentinels tested positive for minute virus of mice and mouse parvovirus and where softwood bedding was used. The mutant phenotype was inherited through G11 as a single autosomal semidominant mutation with marked gender restriction, with males exhibiting almost full penetrance and very few females phenotypically abnormal. Between G11 and G12, facility infection eradication was undertaken and bedding was changed to hardwood. We could no longer detect airway hyperresponsiveness in more than 37 G12 offspring of 26 hyperresponsive G11 males. Also, we could not identify the mutant phenotype among offspring of hyperresponsive G8-G10 sires rederived into an SPF facility despite 21 attempts. These two observations suggest that both genetic and environmental factors were needed for phenotype expression. We suspect that rederivation into an SPF facility or altered exposure to pathogens or other unidentified substances modified environmental interactions with the mutant allele, and so resulted in disappearance of the hyperresponsive phenotype. Our experience suggests that future searches for genes that confer susceptibility for airway hyperresponsiveness might not be able to identify some genes that confer susceptibility if the searches are performed in SPF facilities. Experimenters are advised to arrange for multigeneration constancy of mouse care in order to clone mutant genes. Indeed, we were not able to map the mutation before losing the phenotype.