Salamander abundance along road edges and within abandoned logging roads in Appalachian forests.

Roads may be one of the most common disturbances in otherwise continuous forested habitat in the southern Appalachian Mountains. Despite their obvious presence on the landscape, there is limited data on the ecological effects along a road edge or the size of the "road-effect zone." We sampled salamanders at current and abandoned road sites within the Nantahala National Forest, North Carolina (U.S.A.) to determine the road-effect zone for an assemblage of woodland salamanders. Salamander abundance near the road was reduced significantly, and salamanders along the edges were predominantly large individuals. These results indicate that the road-effect zone for these salamanders extended 35 m on either side of the relatively narrow, low-use forest roads along which we sampled. Furthermore, salamander abundance was significantly lower on old, abandoned logging roads compared with the adjacent upslope sites. These results indicate that forest roads and abandoned logging roads have negative effects on forest-dependent species such as plethodontid salamanders. Our results may apply to other protected forests in the southern Appalachians and may exemplify a problem created by current and past land use activities in all forested regions, especially those related to road building for natural-resource extraction. Our results show that the effect of roads reached well beyond their boundary and that abandonment or the decommissioning of roads did not reverse detrimental ecological effects; rather, our results indicate that management decisions have significant repercussions for generations to come. Furthermore, the quantity of suitable forested habitat in the protected areas we studied was significantly reduced: between 28.6% and 36.9% of the area was affected by roads. Management and policy decisions must use current and historical data on land use to understand cumulative impacts on forest-dependent species and to fully protect biodiversity on national lands.

Mutual interdependence of MSI1 (CAC3) and YAK1 in Saccharomyces cerevisiae.

The MSI1 (CAC3) gene of Saccharomyces cerevisiae has been implicated in diverse cellular functions, including suppression of the RAS/cAMP/protein kinase A signaling pathway, chromatin assembly and transcriptional co-repression. Seeking to identify the molecular mechanisms by which Msi1p carries out these distinct activities, a novel genetic interaction was uncovered with YAK1, which encodes a kinase that antagonizes the RAS/cAMP pathway. MSI1 was capable of efficiently suppressing the heat shock sensitivity caused by deletion of yak1. Surprisingly, the YAK1 gene is required for Msi1p to associate with Cac1p in the yeast two-hybrid system. A new activity of Msi1p was identified: the ability to activate transcription of a reporter gene when tethered near the promoter, but only in the absence of fermentable carbon sources. This transcriptional activation function was diminished substantially by the loss of YAK1. Furthermore, MSI1 influences YAK1 function; over-expression of YAK1 decreased the growth rate, but only in the presence of a functional MSI1 gene. Finally, it is shown that YAK1 antagonizes nuclear accumulation of Msi1p in non-fermenting cells. Taken together, these data demonstrate a novel interaction between Msi1p and Yak1p in which each protein influences the activity of the other.