Project description:Cellular desiccation - the loss of nearly all water from the cell - is a recurring stress in an increasing number of ecosystems that can drive proteome-wide protein unfolding and aggregation. For cells to survive this stress, at least some of the proteome must disaggregate and resume function upon rehydration. The molecular determinants that underlie the ability of proteins to do this remain largely unknown. Here, we apply quantitative and structural proteomic mass spectrometry to desiccated and rehydrated yeast extracts to show that some proteins possess an innate capacity to survive extreme water loss. Structural analysis correlates the ability of proteins to tolerate desiccation with their surface chemistry. We find that highly tolerant proteins are responsible for the production of the cell’s building blocks - amino acids, metabolites, and sugars. Conversely, those proteins that are most desiccation-sensitive are involved in ribosome biogenesis and other energy consuming processes. As a result, the rehydrated proteome is preferentially enriched with metabolite and small molecule producers and depleted of some of the cell’s heaviest consumers. We propose this functional bias enables cells to kickstart their metabolism and promote cell survival following desiccation and rehydration.

Project description:The desiccation-tolerant bryophyte Bryum argenteum was subjected to desiccation and followed by rehydration. The purpose of this study was to quantify the proteome changes upon early rehydration (rehydrated 2 h after desiccation) and 24 h of rehydration.

Project description:The moss Racomitrium canescens has strong desiccation tolerance; it can remain almost completely desiccated for years and yet recover within minutes of rehydration. Dissecting the mechanisms underlying such desiccation tolerance in bryophytes could identify candidate proteins that improve plant drought tolerance. The mechanisms involved in recovery from desiccation was explored using label-free-quantitative proteomics comparing desiccated Racomitrium canescens samples rehydrated for 1 min or 6 h.

Project description:Microbes inhabiting soils experience periodic water deprivation. The effects of desiccation on DNA, protein, and membrane integrity are well-described. However, the effects of drying and rehydration on the composition of cellular RNA and metabolites are still poorly understood. Here, we describe how slow drying and rehydration with water vapor influence the composition of RNAs and metabolites in a soil Arthrobacter. Drying reduced cultivability relative to hydrated controls, but rehydration of dried cells with water vapor restored cultivability. The fraction of 16S and 23S rRNA to the total RNA pool was constant throughout the experiment, irrespective of treatment. mRNA profiles were invariant in desiccated cells, changing only in response to drying or rehydration. Six transcriptional modules were identified that showed distinct expression patterns in desiccated-rehydrated samples, relative to hydrated controls, including desiccation-responsive and rehydration-specific profiles. Targeted metabolomics also showed a static metabolic state during desiccation. A cluster of metabolites enriched in ribonucleosides and nucleobases was responsive to desiccation and rehydration. Collectively, these results are consistent with the relative stability of mRNA and metabolite profiles in desiccated Arthrobacter. These results imply that stable mRNA in dry dormant cells and intracellular RNA recycling may obscure interpretations of RNA-based environmental analyses that use RNA as a marker of microbial activity.

Project description:This series represents Experiment 1 of the yeast desiccation / rehydration time course analysis. Samples include Control, 50% dry, Dry, 15 min. post rehydration, 45 min. post rehydration, 90 min. post rehydration, and 360 min. post rehydration.

Project description:This series represents Experiment 3 of the yeast desiccation / rehydration time course analysis. Samples include Control, 50% dry, Dry, 15 min. post rehydration, 45 min. post rehydration, 90 min. post rehydration, and 360 min. post rehydration.

Project description:This series represents Experiment 2 of the yeast desiccation / rehydration time course analysis. Samples include Control, 50% dry, Dry, 15 min. post rehydration, 45 min. post rehydration, 90 min. post rehydration, and 360 min. post rehydration.

Project description:This series represents the rehydration series of the human 293h media depleted storage on agarose / rehydration condition course analysis. Samples include Control Monolayer, 0 hr desiccation, 0 hr rehydration, 6 hr rehydration, 24 hr rehydration, and 72 hr rehydration. Keywords = 293h cells Keywords = desiccation Keywords = rehydration Keywords = spheroid Keywords = stabilization Keywords = ambient temperature Keywords: other

Project description:This series represents Experiment 3 of the yeast desiccation / rehydration time course analysis. Samples include Control, 50% dry, Dry, 15 min. post rehydration, 45 min. post rehydration, 90 min. post rehydration, and 360 min. post rehydration. Keywords = BY4743 Keywords = desiccation Keywords = glucose-limited Keywords = rehydration Keywords = yeast Keywords: time-course

Project description:This series represents Experiment 2 of the yeast desiccation / rehydration time course analysis. Samples include Control, 50% dry, Dry, 15 min. post rehydration, 45 min. post rehydration, 90 min. post rehydration, and 360 min. post rehydration. Keywords = BY4743 Keywords = desiccation Keywords = glucose-limited Keywords = rehydration Keywords = yeast Keywords: time-course