Regulation of intracellular protein degradation in IMR-90 human diploid fibroblasts

Human diploid fibroblasts (IMR-90) regulate their overall rates of proteolysis in response to the composition of the culture medium and the ambient temperature. The magnitude and, in some cases, the direction of the response depend on the half-lives of the cellular proteins that are radioactively labeled and the time chosen for measurements of protein degradation. Fetal calf serum, insulin, fibroblast growth factor, epidermal growth factor, and amino acids selectively regulate catabolism of long-lived proteins without affecting degradation of short-lived proteins. Fetal calf serum reduces degradative rates of long-lived proteins and is maximally effective at a concentration of 20%, but the effect of serum on proteolysis is evident only for the first 24 hr. Insulin inhibits degradation of long-lived proteins in the presence or absence of glucose and amino acids in the medium, but is maximally effective only at high concentrations (10(-5) M). Amino acid deprivation increases degradative rates of long-lived proteins for the first 6 hr, but then decreases their catabolism for the subsequent 20 hr. Lowered temperature is the only condition tested that significantly alters degradative rates of short-lived proteins. Although cells incubated at 27 degrees C have reduced rates of degradation for both short-lived and long-lived proteins compared to cells at 37 degrees C, lowered temperature reduces catabolism of long-lived proteins to a greater extent.     

Kinetics of histone hyperacetylation and deacetylation in human diploid fibroblasts

We have utilized sodium butyrate-treated normal human diploid fibroblasts to study core histone hyperacetylation kinetics. We report a small, distinct population of core histone characterized by a very rapid rate of hyperacetylation ($\text{t}{}_{\mathrm{<mtext>1</mtext><mtext>2</mtext>}}\text{≈10–15}\text{min}$ for monoacetylated histone H4) compared to the slower rate ($\text{t}{}_{\mathrm{<mtext>1</mtext><mtext>2</mtext>}}\text{≈140–200}\text{min}$ for monoacetylated H4) observed for bulk histone. Two rates of core histone deacetylation were also detected and we demonstrated that the rapidly hypermodified histone H4 population was also rapidly deacetylated. The kinetics of histone H4 hyperacetylation and deacetylation in these cells were not significantly altered, regardless of whether cultures were exponentially growing, confluent or arrested in an essentially non-mitotic state.     

Tritium-arrested human diploid fibroblasts maintain balanced RNA and protein metabolism

Incorporation of ³H precursors into the protein or RNA of exponentially growing human diploid fibroblasts (WI38) inhibited DNA synthesis and cell division for a dose-related period. During this period of “tritium-arrest”, which can last for at least a month, the cells remain viable by morphologic criteria and maintain balanced RNA and protein metabolism. The cultures are eventually overgrown by a dose-related fraction of the population which retains DNA synthetic capacity. Tritium-arrested cell populations are suggested as a possible model for the study of metabolism in non-dividing cells.     

Intracellular protein degradation in serum-deprived human fibroblasts.

IMR90 human fibroblasts were labelled by incubation of cells for 48 h in medium containing 10% serum and [3H]leucine. The labelled protein was degraded at a rate of 1%/h during a subsequent incubation in medium with 10% serum. Incubation in medium without serum caused a transient enhancement of the degradation of endogenous protein, which was also found in cells labelled in medium without serum. The degradation of micro-injected haemoglobin was enhanced by serum deprivation in a non-transient manner. These results suggest that enhanced degradation in serum-free medium occurs only for a subpopulation of cell proteins and that it appears transient because the major part of the pool of susceptible endogenous proteins is being degraded during the first 20-30 h in serum-free unlabelled medium. Protein turnover in various cell compartments was measured by a double-labelling technique. Most of the enhanced degradation in serum-deprived cultures (73-83%) was due to breakdown of cytosolic proteins. The enhanced degradation of cytosolic proteins seemed to affect several proteins irrespective of their molecular mass or metabolic stability.     

Messenger RNA regulation in human diploid fibroblasts

In resting, non-growing human diploid fibroblasts the amount of rRNA is reduced 1.8-fold, cytoplasmic polysomes are disaggregated, and the level of poly-A RNA (mRNA) is reduced 1.8-fold in relation to growing cells. The distribution of poly-A RNA is altered in resting, non-growing cells so that an average of 64% of the total cytoplasmic poly-A RNA sediments along with particles lighter than 80S (prepolysomal) in sucrose density gradients. By comparison, in growing cells only 30% of the cytoplasmic poly-A RNA sediments in the prepolysomal region. In SDS sucrose gradients, the sedimentation profile of the prepolysomal poly-A RNA from resting cells resembles that of polysomal poly-A RNA from those cells. In contrast, the average size of prepolysomal poly-A RNA from growing cells is much smaller than that of the polysomal poly-A RNA from those cells. These data are compatible with the possibility that resting cell prepolysomal poly-A is untranslated mRNA. Also consistent with this interpretation are experiments which demonstrate that one-quarter to one-third of the prepolysomal poly-A RNA of resting cells is recruited into polysomes in the presence of cycloheximide.     

Ultrastructural studies of the nucleoli in diploid and trisomic chickens

Chickens having a trisomic complement for the nucleolar organizer region (NOR) serve as a model for investigations on gene expression, molecular regulation, and physiological alterations resulting from extra genetic material. Of fundamental importance is the question of whether the extra set of ribosomal cistrons in trisomic chickens generates a morphologically and biochemically complete nucleolus. Ultrastructural and cytochemical studies of diploid and trisomic embryonic and adult cells were undertaken. All structures identified in trisomic cells as nucleoli by gross morphology were shown to be RNA rich by acridine orange fluorescence. At the ultrastructural level, the expected granular and fibrillar components were identified in all nucleoli of trisomic cells. Fibrillar centers, indicative of NOR's, were seen in all cases. These and other results from silver staining suggest full gene activity for each of the three chromosomes in the trisomic cell at all stages of development.     

Gene dosage effects in human diploid and tetraploid fibroblasts

The effects of cell ploidy on the biochemical characteristics of cultured cells were compared using human diploid vs tetraploid fibroblasts isolated with a non-selective method. Their DNA replication was compared by thymidine incorporation, and DNA content by Feulgen staining and quantitative analysis. Their RNA and protein content, cell sizes and the specific activities of glucose-6-phosphate dehydrogenase (G-6-PD) and 6-phosphogluconate dehydrogenase (6-PGD) were assayed quantitatively. With the exception of RNA content, all other parameters demonstrated a 2-fold increase reflecting the increase in cell ploidy. These direct gene dosage effects on the genetic material and functional expression of the human genome were in contrast to previous observations in other species and validate the use of human intraspecific euploid hybrids for biochemical and genetic studies.     

Imino acid transport in human diploid fibroblasts.

These studies describe the transport of proline and hydroxyproline in human diploid fibroblasts. Inhibition and kinetic analysis demonstrate that proline is actively transported by the “A” neutral amino acid carrier. Proline transport is Na⁺ dependent and is particularly sensitive to sulfhydryl inhibitors and ouabain. Hydroxyproline is also actively transported but its transport is mediated by a system different from those described previously for other neutral amino acids. Hydroxyproline transport requires the presence of Na⁺ and is sensitive to sulfhydryl inhibitors and ouabain. There is little inhibition of hydroxyproline transport in the presence of other amino acids with the exception of methionine. The methionine inhibition of hydroxyproline transport is of the non-competitive type. Little cross-reactivity was exhibited by the systems which transport proline and hydroxyproline. These studies indicate that human skin fibroblasts do not possess an iminoglycine transport system as has been described for many other tissues. The iminoglycine transport system has been identified as the genetic transport defect in iminoglycinuria. Consequently, skin fibroblasts are not an appropriate system for use in diagnosis of this disorder.     

Transport ofl-histidine by human diploid fibroblasts in culture

Summary The transport ofl-histidine has been characterized in skin derived diploid human fibroblasts, cultured under strictly controlled conditions. The transport measurements were made on cells grown to subconfluency after 60 to 90 min timed preincubation. The data, at substrate concentrations ranging from 0.050 to 10 mmol/l, were analyzed by a computer program. A saturable transport system (K _m =0.25 mmol/l, V _max =17 nmol/mg protein per min) and a nonsaturable component of influx (K _d =1.6±0.4 nmol/mg protein/min per mmol) were found.l-Histidine displayed no Na⁺ requirement at either low or high concentrations. Inhibition analysis demonstrated thatl-histidine uptake at low concentration was poorly inhibited by amino acids known to be effective inhibitors of system A. The largest fraction ofl-histidine uptake was inhibited by 2-amino-bicyclo (2,2,1)-heptane-2-carboxylic acid (BCH), leucine, and tryptophan. These results indicated thatl-histidine is transported in human fibroblasts, mainly by the Na⁺ independent system L. The differences between this cell type and others studied previously are discussed. This work was supported in part by Grant 773 from UER de Médecine, Université Paris XI (France).     

Increased glycolysis in ageing cultured human diploid fibroblasts

With increasing population doubling in vitro, human diploid fibroblasts exhibited a highly significant increase in glucose uptake from the growth medium and a corresponding increase in lactate production. The switch to glycolysis occurred prior to the onset of changes in intracellular glucose and lactate concentrations or in the specific activity of the glycolytic regulatory enzyme, pyruvate kinase, it also preceded the morphological alterations held to be characteristic of cellular senescence.     

The induction of apoptosis by daunorubicin and idarubicin in human trisomic and diabetic fibroblasts

In this study, we investigated apoptosis induced in human trisomic and diabetic fibroblasts by daunorubicin (DNR) and its derivative, idarubicin (IDA). The cells were incubated with DNR or IDA for 2 h and then cultured in a drug-free medium for a further 2–48 h. The apoptosis in the cultured cell lines was assessed by biochemical analysis. We found that both drugs induced a timedependent loss of mitochondrial membrane potential, and a significant increase in intracellular calcium and caspase-3 activity. Mitochondrial polarization and changes in the level of intracellular calcium were observed during the first 2–6 h after drug treatment. Caspase-3 activation occurred in the late stages of the apoptotic pathway. Our findings also demonstrated that idarubicin was more cytotoxic and more effective than daunorubicin in inducing apoptosis in trisomic and diabetic fibroblasts.     

Replication of wild-type and mutant human cytomegalovirus in life-extended human diploid fibroblasts

A cDNA encoding the catalytic subunit of human telomerase was used to generate life-extended derivatives of primary human diploid fibroblasts. The life-extended cells supported efficient human cytomegalovirus (HCMV) replication. A subclone of the life-extended cells was generated containing the HCMV UL82 gene and used to isolate and propagate a virus that exhibited a profound growth defect after infection at a low input multiplicity.     

Regulation of protein synthesis in human diploid fibroblasts: reduced initiation efficiency in resting cultures

The level of poly A+ RNA in growing cultures of human diploid fibroblasts is 1.8-fold times greater than in resting cultures. The level of functional ribosomes in growing cultures is 2.8 times that in resting cultures. Since transit times are similar in both types of cells, it can be concluded that the rate of protein synthesis in growing cultures is 2.8 times that in resting cultures. a reduced efficiency of mRNA translation at the level of initiation in resting cultures is proposed as a probable explanation for the fact that the decrease in protein synthesis rates is greater than the decrease in mRNA levels. This hypothesis is supported by the observations that: (a) poly A+ RNA is associated with smaller polysomes in resting than in growing cells, and (b) cycloheximide treatment of resting cells results in recruitment of nonpolysomal poly A+ RNA into polysomes and a shift of polysomal poly A+ RNA into larger polysomes.     

Up-regulation of PDCD4 in senescent human diploid fibroblasts

Programmed cell death 4 (PDCD4) has a common MI domain sharing with death associated protein 5 (DAP5) and a component of eukaryotic translation initiation factor (eIF4G) complex and it might also work as a tumor suppressor. We could find that the message and product of Pdcd4 gene were up-regulated in senescent human diploid fibroblasts. In yeast two hybrid analysis, the C-terminal region of PDCD4 interacted with ribosomal protein S13 (RPS13), ribosomal protein L5 (RPL5), and TI-227H. In in vitro binding assay, RPS13, a component of 40S ribosome was stably bound to PDCD4. We also found that PDCD4 was localized to polysome fractions. We could pull out eIF4G with GST-PDCD4, but eIF4E did not interact with PDCD4. From these results, we could assume that PDCD4 might regulate the eIF4G-dependent translation through direct interactions with eIF4G and RPS13 in senescent fibroblasts.