A mathematical model of the regulation process of the heat shock protein hsp70 in the cell is presented. The model describes the damaging effect of elevated temperature on proteins; the interaction of free hsp70 with injured proteins and its chaperone role in nascent protein translation; the relation between the amount of free hsp70 and the formation of the activated trimer form of the heat shock factor protein (HSF); the binding of activated HSF with the heat shock elements on the DNA; the transcription of mRNA of hsp70 and the synthesis of hsp70. The reaction of the model to a temporal rise in temperature shows an initial decline and a subsequent sharp rise to an ultimately increased level of free hsp70 in the cell. The response of the model to both a single and two consecutive heat shocks appears to closely resemble experimental data on hsp70 synthesis. This general agreement demonstrates the structure of the model to be sound and suitable as a basis for further modelling the complex tolerance mechanism of the cell.
1 A brief and moderate heat shock to Reuber H35 hepatoma cells causes a rapid increase in the synthesis of heat shock proteins (hsp) and initiates the development of thermotolerance, which results in an increased ability to survive exposure to otherwise lethal temperatures. 2 We now demonstrate that low doses of various chemical stressors (arsenite, cadmium, mercury, lead, copper, menadione and diethyldithiocarbamate (ddtc)), at concentrations that do not exert any effect in control cultures, are able to enhance the synthesis of hsps and to stimulate the development of thermotolerance when applied to cultures which were pretreated with a mild heat shock. 3 The degree of stimulation appears to be stressorspecific, which is not only observed in the ensuing development of thermotolerance but also in the enhancement of the heat shock-induced synthesis of stress proteins. 4 The different hsps that show an enhanced induction when heat shocked cultures are exposed to the various secondary applied low doses of chemical stressors, were found to resemble the hsp pattern that is characteristic for the secondary stressor and not for the initial heat shock. In other words, the nature of the post-treatment determines the observed pattern of enhanced synthesis of hsps. 5 In order to analyze the origin of the stimulation of survival capacity by low doses of the mentioned stressors, we studied whether the degree of stimulation is determined by the degree of similarity between the overall stress response to heat shock and to the second stress condition when applied singly. 6 The degree in which low doses of chemical stressors stimulate tolerance development and enhance the synthesis of hsps in cells that were previously heat shocked, appears to be related to the degree of similarity in the hsp pattern induced by both stressors. 7 Our results support the notion that low doses of toxic compounds may, under certain conditions, have beneficial effects related to a stimulation of endogenous cytoprotective mechanisms.
In the process of wound healing keratinocytes and fibroblasts play an important role, keratinocytes in the re-epithelization process and fibroblasts in the process of wound contraction. We have studied the role of human keratinocytes and fibroblasts in the rearrangement of collagen in a collagen lattice model system. Our results revealed that keratinocytes as well as fibroblasts rearrange the collagen lattice; this occurs in a cell number and collagen concentration dependent manner. The optimal gel contraction is obtained in the presence of keratinocytes on the top of and of fibroblasts in the collagen lattice, the situation most closely approaching the in vivo situation. Between the two types of cells, differences in morphologic behavior were observed: when incorporated into the gel the keratinocytes retained their spherical shape throughout the whole culture period, but fibroblasts became elongated and formed extensions. Our data suggest that not only fibroblasts but also keratinocytes may be involved in the process of wound contraction.
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