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Microbial pathways for the mobilization of Mercury as Hg(0) in anoxic subsurface environments
Yap1 Accumulates in the Nucleus in Response to Carbon Stress in Saccharomyces cerevisiae
Yap1 is a transcription factor of the AP-1 family that is required for the adaptive response to oxidative stress in Saccharomyces cerevisiae. We recovered Yap1 in a two-hybrid screen for proteins that interact with the Sip2 subunit of the Snf1 protein kinase, which is required for the adaptation of cells to glucose limitation. Yap1 becomes enriched in the nucleus when cells are subjected to oxidative stress. We show that the localization of Yap1 is similarly sensitive to carbon stress. When glucose-grown cells were shifted to medium containing glycerol or no added carbon source, green fluorescent protein (GFP)-Yap1 accumulated in the nucleus. After adaptation to growth in glycerol, GFP-Yap1 was again primarily cytoplasmic. Nuclear accumulation was independent of respiration and of the Snf1, PKA, TOR, and Yak1 pathways, and the mechanism is distinct from that involved in the response to hydrogen peroxide. Addition of glutathione to the medium inhibited nuclear accumulation of GFP-Yap1 in response to carbon stress but did not affect the relocalization of Gal83 or Mig1. Other stresses such as increased temperature, acidic pH, and ionic stress did not cause nuclear enrichment of GFP-Yap1. These findings suggest a role for Yap1 in the response to carbon stress
Mutations in the Gal83 Glycogen-Binding Domain Activate the Snf1/Gal83 Kinase Pathway by a Glycogen-Independent Mechanism
The yeast Snf1 kinase and its mammalian ortholog, AMP-activated protein kinase (AMPK), regulate responses to metabolic stress. Previous studies identified a glycogen-binding domain in the AMPK β1 subunit, and the sequence is conserved in the Snf1 kinase β subunits Gal83 and Sip2. Here we use genetic analysis to assess the role of this domain in vivo. Alteration of Gal83 at residues that are important for glycogen binding of AMPK β1 abolished glycogen binding in vitro and caused diverse phenotypes in vivo. Various Snf1/Gal83-dependent processes were upregulated, including glycogen accumulation, expression of RNAs encoding glycogen synthase, haploid invasive growth, the transcriptional activator function of Sip4, and activation of the carbon source-responsive promoter element. Moreover, the glycogen-binding domain mutations conferred transcriptional regulatory phenotypes even in the absence of glycogen, as determined by analysis of a mutant strain lacking glycogen synthase. Thus, mutation of the glycogen-binding domain of Gal83 positively affects Snf1/Gal83 kinase function by a mechanism that is independent of glycogen binding
Mercury Speciation and Mobilization in a Wastewater-Contaminated Groundwater Plume
We measured the concentration and
speciation of mercury (Hg) in
groundwater down-gradient from the site of wastewater infiltration
beds operated by the Massachusetts Military Reservation, western Cape
Cod, Massachusetts. Total mercury concentrations in oxic, mildly acidic,
uncontaminated groundwater are 0.5–1 pM, and aquifer sediments
have 0.5–1 ppb mercury. The plume of impacted groundwater created
by the wastewater disposal is still evident, although inputs ceased
in 1995, as indicated by anoxia extending at least 3 km down-gradient
from the disposal site. Solutes indicative of a progression of anaerobic
metabolisms are observed vertically and horizontally within the plume,
with elevated nitrate concentrations and nitrate reduction surrounding
a region with elevated iron concentrations indicating iron reduction.
Mercury concentrations up to 800 pM were observed in shallow groundwater
directly under the former infiltration beds, but concentrations decreased
with depth and with distance down-gradient. Mercury speciation showed
significant connections to the redox and metabolic state of the groundwater,
with relatively little methylated Hg within the iron reducing sector
of the plume, and dominance of this form within the higher nitrate/ammonium
zone. Furthermore, substantial reduction of HgÂ(II) to Hg<sup>0</sup> within the core of the anoxic zone was observed when iron reduction
was evident. These trends not only provide insight into the biogeochemical
factors controlling the interplay of Hg species in natural waters,
but also support hypotheses that anoxia and eutrophication in groundwater
facilitate the mobilization of natural and anthropogenic Hg from watersheds/aquifers,
which can be transported down-gradient to freshwaters and the coastal
zone