Biodiversity responses to Lateglacial climate change in the subdecadally-resolved record of Lake Hämelsee (Germany)

Anthropogenically-driven climate warming and land use change are the main causes of an ongoing decrease in global biodiversity. It is unclear how ecosystems, particularly freshwater habitats, will respond to such continuous and potentially intensifying disruptions. Here we analyse how different components of terrestrial and aquatic ecosystems responded to natural climate change during the Lateglacial. By applying a range of analytical techniques (sedimentology, palaeoecology, geochemistry) to the well-dated sediment archive from Lake Hämelsee (Germany), we show evidence for vegetation development, landscape dynamics and aquatic ecosystem change typical for northwest Europe during the Lateglacial. By particularly focussing on periods of abrupt climate change, we determine the timing and duration of changes in biodiversity in response to external forcing. We show that onsets of changes in biodiversity indicators (e.g. diatom composition, Pediastrum concentrations) lag changes in environmental records (e.g. loss-on-ignition) by a few decades, particularly at the Allerød/ Younger Dryas transition. Most biodiversity indicators showed transition times of 10–50 years, whereas environmental records typically showed a 50–100 year long transition. In some cases, transition times observed for the compositional turnover or productivity records were up to 185 years, which could have been the result of the combined effects of direct (e.g. climate) and indirect (e.g. lake stratification) drivers of ecosystem change. Our results show differences in timing and duration of biodiversity responses to external disturbances, suggesting that a multi-decadal view needs to be taken when designing effective conservation management of freshwater ecosystems under current global warming

The Cdc25 protein of Saccharomyces cerevisiae is required for normal glucose transport

The essential CDC25 gene product of Saccharomyces cerevisiae is the most upstream known component of the RAS/adenylate cyclase pathway. Cdc25 is a GTP-exchange protein involved in activating RAS in response to fermentable carbon sources. In this paper it is reported that the Cdc25 protein, in addition to its stimulatory role in the RAS/adenylate cyclase pathway, regulates glucose transport. Continuous culture studies and glucose uptake experiments showed that the cdc25-1 and the cdc25-5 temperature-sensitive mutants exhibit decreased glucose uptake activity at the restrictive temperature under both repressed and derepressed conditions as compared to the wild-type strain. Because the cdc25-1 mutant is not impaired in its cAMP metabolism, it is concluded that this effect on glucose transport is independent of cAMP levels. Furthermore, it is shown that the decrease in glucose uptake activity is not due to a decrease in protein synthesis or to an arrest in the G1 phase of the cell cycle. In addition to a defect in glucose uptake, the cdc25-5 mutant strain exhibited differences in glucose metabolism, probably due to the decreased cAMP level and hence decreased protein kinase A activity. Because the Cdc25 protein is localized at the membrane, these results indicate that Cdc25 is directly involved in glucose transport and may be in direct contact with the glucose transporters

Effects of different carbon fluxes on G1 phase duration, cyclin expression, and reserve carbohydrate metabolism in Saccharomyces cerevisiae.

By controlled addition of galactose to synchronized galactose-limited Saccharomyces cerevisiae cultures, the growth rate could be regulated while external conditions were kept constant. By using this method, the G1 phase duration was modulated and expression of cell cycle-regulated genes was investigated. The expression of the cyclin genes CLN1 and CLN2 was always induced just before bud emergence, indicating that this event marks the decision to pass Start. Thus, G1 phase elongation was not due to a slower accumulation of the CLN1 and CLN2 mRNA levels. Only small differences in CLN3 expression levels were observed. The maximal SWI4 expression preceded maximal CLN1 and CLN2 expression under all conditions, as expected for a transcriptional activator. But whereas SWI4 was expressed at about 10 to 20 min, before CLN1 and CLN2 expression at high growth rates, this time increased to about 300 min below a particular consumption rate at which the G1 phase strongly elongated. In the slower-growing cultures, also an increase in SWI6 expression was observed in the G1 phase. The increase in G1 phase duration below a particular consumption rate was accompanied by a strong increase in the reserve carbohydrate levels. These carbohydrates were metabolized again before bud emergence, indicating that below this consumption rate, a transient increase in ATP flux is required for progression through the cell cycle. Since Start occurred at different cell sizes under different growth conditions, it is not just a certain cell size that triggers passage through Start

Function of Trehalose and Glycogen in Cell Cycle Progression and Cell Viability in Saccharomyces cerevisiae

Trehalose and glycogen accumulate in Saccharomyces cerevisiae when growth conditions deteriorate. It has been suggested that aside from functioning as storage factors and stress protectants, these carbohydrates may be required for cell cycle progression at low growth rates under carbon limitation. By using a mutant unable to synthesize trehalose and glycogen, we have investigated this requirement of trehalose and glycogen under carbon-limited conditions in continuous cultures. Trehalose and glycogen levels increased with decreasing growth rates in the wild-type strain, whereas no trehalose or glycogen was detected in the mutant. However, the mutant was still able to grow and divide at low growth rates with doubling times similar to those for the wild-type strain, indicating that trehalose and glycogen are not essential for cell cycle progression. Nevertheless, upon a slight increase of extracellular carbohydrates, the wild-type strain degraded its reserve carbohydrates and was able to enter a cell division cycle faster than the mutant. In addition, wild-type cells survived much longer than the mutant cells when extracellular carbon was exhausted. Thus, trehalose and glycogen have a dual role under these conditions, serving as storage factors during carbon starvation and providing quickly a higher carbon and ATP flux when conditions improve. Interestingly, the CO(2) production rate and hence the ATP flux were higher in the mutant than in the wild-type strain at low growth rates. The possibility that the mutant strain requires this steady higher glycolytic flux at low growth rates for passage through Start is discussed