Dual control of heat shock response: involvement of a constitutive heat shock element-binding factor

Heat shock factor (HSF) has been implicated as the key regulatory protein in the heat shock response. Our studies on the response of rodent cells to heat shock or sodium arsenite indicate that a high level of HSF-DNA-binding activity, by itself, is not sufficient for the induction of hsp70 mRNA synthesis; furthermore, a high level of HSF binding is also not necessary for this induction. Analysis of the binding of protein factors to the heat shock element (HSE) in extracts of stressed rodent cells indicates that the regulation of heat shock response involves the heat-inducible HSF and a constitutive HSE-binding factor. Our results also suggest that overexpression of human hsp70 may decrease the level of heat-induced HSF-HSE-binding activity in rat cells.     

Insulin-like growth factor binding protein-3 is overexpressed in senescent and quiescent human fibroblasts

Cellular insulin-like growth factor binding protein-3 (IGFBP-3) mRNA and IGFBP-3 levels in conditioned medium were consistently higher in cultures of late passage normal (old) fibroblasts and prematurely senescent fibroblasts derived from Werner syndrome (WS) during quiescence induced by serum depletion and during the renewed growth ensuing after serum repletion, compared to cultures of early passage normal (young) fibroblasts. Molar ratios of IGFBP-3/IGF-II were always higher in senescent cultures and maintained a hierarchy of old > WS > young human diploid fibroblasts. Transfection into fibroblasts of the normal full-length IGFBP-3 cDNA in an expression vector resulted in a significant reduction in colony formation compared to cells transfected with an empty expression vector (no cDNA) or with IGFBP-3 cDNA altered by a 273 base pair (bp) deletion. Addition to old and young cultures of recombinant human IGFBP-3 and IGF-I at 1:1 or 5:1 molar ratios inhibited IGF-I-mediated DNA synthesis by approximately 70-80%. These data indicate that IGFBP-3 may play an important role in the quiescent and senescent growth arrest of HDF.     

Differential regulation of collagenase and stromelysin mRNA in late passage cultures of human fibroblasts

Nontransformed human fibroblast cell cultures have been extensively studied as an in vitro model for cellular senescence. Recently there has been considerable interest in using the human fibroblast in the identification of genes relevant to the process of replicative senescence. We demonstrated that in comparison with early passage cultures the expression of collagenase and stromelysin mRNAs and proteins was increased > 8 x in late passage cultures of human fibroblasts and, in addition, expression of Il-1 alpha, a cytokine that regulates collagenase and stromelysin expression, was also significantly increased in late passage cell cultures. These findings suggested the hypothesis that constitutive Il-1 alpha expression in late passage cells may coordinately regulate the age-associated increase in the expression of collagenase and stromelysin. To test this hypothesis we examined the effects of long-term Il-1 alpha treatment, serum starvation, and cycloheximide inhibition on collagenase and stromelysin mRNA levels in early and late passage human fibroblast cell cultures. Here we report that in late passage cell cultures, collagenase and stromelysin mRNAs respond differentially to Il-1 alpha, serum starvation, and cycloheximide addition. Continuous exposure to Il-1 alpha reduced the half-life of stromelysin mRNA but had little effect on the half-life of collagenase mRNA. In contrast to stromelysin, the collagenase mRNA level is dependent on serum factors. Collagenase is induced during recovery from cycloheximide inhibition, but stromelysin expression is not affected. These results establish that collagenase and stromelysin mRNAs are differentially regulated in both early and late passage human fibroblasts and suggest that the mechanisms responsible for the age-associated increase in the two mRNAs are different. In addition, these studies support the conclusion that continuous long-term exposure to Il-1 alpha, a condition that is characteristic of late passage cells, is not the factor responsible for the high levels of collagenase expression, but may be critical for stromelysin expression.     

Altered protein metabolism in arrested populations of aging human diploid fibroblasts

Protein synthesis and turnover were measured in human diploid fibroblasts which were arrested in an essentially nonmitotic state by reducing the serum concentration in the incubation medium to 0.5%. Through the first 4 days of the arrested period both early and late passage cells lost about 20% of their cellular protein. There was a reduction in the rate of protein synthesis at both passage levels during this period, but there was no significant age-related difference in the synthetic rate or the rate of protein turnover. After day 4 both early and late passage cells maintained a constant protein content, but late passage cells did this while processing more protein through faster rates of both synthesis and turnover than did early passage cells. These results support those theories of cellular senescence which predict altered protein metabolism as a major consequence of the aging process.     

Demonstration of cellular aging and senescence in serially passaged long-term cultures of human trabecular osteoblasts

The proliferative capacity and cellular and biochemical characteristics of human trabecular bone osteoblasts were analysed throughout their replicative lifespan in vitro. Like several other cell types, human osteoblasts demonstrated a typical Hayflick phenomenon of cellular aging comprising a period of rapid proliferation until cumulative population doubling level (CPDL) 22 to 24, followed by a phase of slow growth and the final cessation of cell division at CPDL 32 to 34. Comparing young cells (less than 20% lifespan completed) and old cells (more than 90% lifespan completed) revealed a progressive increase in population doubling (PD) time, a decrease in attachment frequency, a decrease in the number of S-phase positive cells, a decrease in the rates of DNA, RNA and protein synthesis, an increase in the protein content per cell and an increased proportion of senescence-specific beta-galactosidase positive cells. While osteoblastic production of collagen type I decreased progressively during aging, alkaline phosphatase activity dropped rapidly after the first few passages and then remained constant during the rest of the proliferative lifespan, Significant morphological changes from thin and spindle-shaped early passage young cells to large, flattened and irregularly shaped late passage old cells full of intracellular debris were observed. In comparison, osteoblasts established from an osteoporotic bone sample showed a maximum CPDL of less than 5, had a longer PD time and exhibited abnormal senescent morphology. Thus, we have demonstrated for the first time that human osteoblasts, like several other diploid cell types, have a limited proliferative capacity in vitro and undergo aging and senescence as measured by various cellular and biochemical markers. In addition, preliminary studies show that cells from osteoporotic bone have a severely reduced proliferative capacity. This model of bone cell aging facilitates study of the molecular mechanisms of osteoblast senescence as well as factors related to osteoblast dysfunction in patients with osteoporosis.     

Hsp110 protects heat-denatured proteins and confers cellular thermoresistance

The 110-kDa heat shock protein (hsp110) has long been recognized as one of the primary heat shock proteins in mammalian cells. It belongs to a recently described protein family that is a significantly diverged subgroup of the hsp70 family and has been found in organisms as diverse as yeast and mammals. We describe here the first analysis of the ability of hsp110 to protect cellular and molecular targets from heat damage. It was observed that the overexpression in vivo of hsp110 conferred substantial heat resistance to both Rat-1 and HeLa cells. In vitro heat denaturation and refolding assays demonstrate that hsp110 is highly efficient in selectively recognizing denatured proteins and maintaining them in a soluble, folding-competent state and is significantly more efficient in performing this function than is hsc70. hsp110-bound proteins can then be refolded by the addition of rabbit reticulocyte lysate or hsc70 and Hdj-1, whereas Hdj-1 does not itself function as a co-chaperone in folding with hsp110. hsp110 is one of the principal molecular chaperones of mammalian cells and represents a newly identified component of the primary protection/repair pathway for denatured proteins and thermotolerance expression in vivo.     

Thermosensitivity of nuclear RNA polymerase during the in vitro senescence of mouse fibroblasts

Embryonic mouse fibroblasts divide approximately twelve times in vitro prior to cessation of mitotic activity. During this period of cellular senescence the thermosensitivity of the RNA polymerase activity of isolated nuclei has been examined as a means of detecting the possible accumulation of defective enzyme molecules, as has been found by other workers for several cytoplasmic enzymes during the ageing of human fibroblasts in vitro. The total RNA polymerase activity of nuclei isolated from old (10th generation) cells is more thermoresistant than that of young (2nd generation) cells. However, the net RNA polymerase activity of nuclei from non-dividing (confluent) cells is more thermoresistant than that of exponentially growing cells of the same age. When allowance is made for the state of growth of the cultures, little difference is seens in the thermosensitivity of the activities of nuclei from old and young cells. Neither is there any difference between the thermosensitivity of the net activity of an established line of murine fibroblasts (L-cells) and cells in primary culture. Preheating nuclei increases the inhibition of their total RNA polymerase activity by alpha-amanitin, indicating that RNA polymerase II is the most heat resistance species present. There appears to be no difference between the thermosensitivity of the alpha-amanitin sensitive and resistance species of the enzyme in the nuclei of old and young cells. It is concluded that old cells resemble non-dividing young cells in containing a higher proportion of RNA polymerase II in their nuclei, resulting in greater thermoresistance of the total RNA polymerase activity over that of exponentially growing cells. However, there appears to be no increase in thermosensitivity of the enzymes with age.