The molecular mechanisms that enable yeast cells to detect and transmit cold signals and their physiological significance in the adaptive response to low temperatures are unknown. Here, we have demonstrated that the MAPK Hog1p is specifically activated in response to cold. Phosphorylation of Hog1p was dependent on Pbs2p, the MAPK kinase (MAPKK) of the high osmolarity glycerol (HOG) pathway, and Ssk1p, the response regulator of the two-component system Sln1p-Ypd1p. However, Sho1p was not required. Interestingly, phosphorylation of Hog1p was stimulated at 30°C in cells exposed to the membrane rigidifier agent dimethyl sulfoxide. Moreover, Hog1p activation occurred specifically through the Sln1 branch. This suggests that Sln1p monitors changes in membrane fluidity caused by cold. Quite remarkably, activation of Hog1p at low temperatures affected the transcriptional response to cold shock. Indeed, the absence of Hog1p impaired the cold-instigated expression of genes for trehalose-and glycerol-synthesizing enzymes and small chaperones. Moreover, a downward transfer to 12 or 4°C stimulated the overproduction of glycerol in a Hog1p-dependent manner. However, hog1⌬ mutant cells showed no growth defects at 12°C as compared with the wild type. On the contrary, deletion of HOG1 or GPD1 decreased tolerance to freezing of wildtype cells preincubated at a low temperature, whereas no differences could be detected in cells shifted directly from 30 to ؊20°C. Thus, exposure to low temperatures triggered a Hog1p-dependent accumulation of glycerol, which is essential for freeze protection.Variations in the surrounding temperature are probably the most common stress for all living organisms. In particular, a downshift in temperature leads to a reduction in membrane fluidity, impaired protein biosynthesis, and stabilization of secondary structures of DNA and RNA (1). Consequently, the adaptive response to cold shock in most organisms, studied so far, includes a change in the lipid composition of membranes and the remodeling of the transcriptional and translational machinery. These changes are mainly triggered by a drastic variation in the gene expression program, which leads to both survival and adaptation to low temperatures.Unlike other stress conditions, the biochemical mechanisms by which eukaryotic cells sense changes and respond to a downshift in temperature are poorly understood. Using the cyanobacteria Synechocystis as an experimental model, Murata and Los (2) suggested that a phase transition of the plasma membrane upon cold shock would trigger a conformational change of a putative cold sensor, this being the primary event in the transduction of the temperature signal. According to this hypothesis, a membrane-bound histidine kinase, Hik33, has been identified as a cold sensor in this organism, which is able to detect changes in the physical state of the membrane and regulate the expression of most cold-induced genes (3, 4). Other putative cold sensors, such as DesK in Bacillus subtilis (5) and transient receptor potential (T...
