Age dependency of the metabolic conversion of polyamines into amino acids in IMR-90 human embryonic lung diploid fibroblasts

Phagocytosis and remodeling of collagen matrices

The biodegradation of collagen and the deposition of new collagen-based extracellular matrices are of central importance in tissue remodeling and function. Similarly, for collagen-based biomaterials used in tissue engineering, the degradation of collagen scaffolds with accompanying cellular infiltration and generation of new extracellular matrix is critical for the integration of in vitro grown tissues in vivo. In earlier studies we observed significant impact of collagen structure on primary lung fibroblast behavior in vitro in terms of collagen uptake and matrix remodeling. Therefore, in the present work, the response of human fibroblasts (IMR-90) to the structural state of collagen was studied with respect to phagocytosis in the presence and absence of inhibitors. Protein content and transcript levels for collagen I (Col-1), matrix metalloproteinase 1 (MMP-1), matrix metalloproteinase 2 (MMP-2), tissue inhibitor of matrix metalloproteinase 1 (TIMP-1), tissue inhibitor of matrix metalloproteinase 2 (TIMP-2), and heat shock protein 70 (HSP-70) were characterized as a function of collagen matrix concentration, structure and cell culture time to assess effects on cellular collagen matrix remodeling processes. Phagocytosis of collagen was assessed quantitatively by the uptake of collagen-coated fluorescent beads incorporated into the collagen matrices. Significantly higher levels of collagen phagocytosis were observed for the cells grown on the denatured collagen versus native collagen matrices. Significant reduction in collagen phagocytosis was observed by blocking several phagocytosis pathways when the cells were grown on denatured collagen versus non-denatured collagen. Collagen phagocytosis inhibition effects were significantly greater for PDL57 IMR-90 cells versus PDL48 cells, reflecting a reduced number of collagen processing pathways available to the older cells. Transcript levels related to the deposition of new extracellular matrix proteins varied as a function of the structure of the collagen matrix presented to the cells. A four-fold increase in transcript level of Col-1 and a higher level of collagen matrix incorporation were observed for cells grown on denatured collagen versus cells grown on non-denatured collagen. The data suggest that biomaterial matrices incorporating denatured collagen may promote more active remodeling toward new extracellular matrices in comparison to cells grown on non-denatured collagen. A similar effect of cellular action toward denatured (wound-related) collagen in the remodeling of tissues in vivo may have significant impact on tissue regeneration as well as the progression of collagen-related diseases.

Extracellular matrix remodeling--methods to quantify cell-matrix interactions

Tissue turnover during wound healing, regeneration or integration of biomedical materials depends on the rate and extent of materials trafficking into and out of cells involved in extracellular matrix (ECM) remodeling. To exploit these processes, we report the first model for matrix trafficking in which these issues are quantitatively assessed for cells grown on both native collagen (normal tissue) and denatured collagen (wound state) substrates. Human fibroblasts more rapidly remodeled denatured versus normal collagen type I to form new ECM. Fluxes to and from the cells from the collagen substrates and the formation of new ECM were quantified using radioactively labeled substrates. The model can be employed for the systematic and quantitative study of the impact of a broad range of physiological factors and disease states on tissue remodeling, integrating extracellular matrix structures and cell biology.

Changes in hepatic polyamine catabolism in elderly rats

AIMS/BACKGROUND

Given the important role of polyamines (putrescine, spermidine, spermine) in the modulation of macromolecular syntheses, gene expression and proteolysis, alterations in their metabolic pathways could be relevant during senescence. Since the few existing data address mainly polyamine biosynthesis, we studied the oxidative catabolism of polyamines in the liver of rats 3-36 months of age.

METHODS

Polyamine oxidase activity was fluorimetrically measured using N1-acetylspermine as substrate. Spermidine/spermine N1-acetyltransferase and diamine oxidase were measured by radiochemical methods using labeled acetyl-coenzyme A and putrescine, respectively, as substrate. Polyamines were separated by HPLC and fluorimetrically quantified after post-column derivatization with o-phthaldialdehyde.

RESULTS

Spermidine/spermine N1-acetyltransferase activity increased in 36-month-old rats and polyamine oxidase activity in 24- and 36-month-old rats. A decline in spermine and increases in spermidine and putrescine in elderly rats suggested an activation of the interconversion pathway of higher into lower polyamines. The activity of diamine oxidase, which degrades putrescine, was enhanced starting from 12 months of age.

CONCLUSION

In the liver of aged rats, an increase in the catabolic enzymes leads to a reconversion of the higher polyamines to putrescine. This increased catabolism may represent an important age-related change and may contribute to impairment of the expression of growth-related genes in senescence.

Dramatic attenuation of hypusine formation on eukaryotic initiation factor 5A during senescence of IMR-90 human diploid fibroblasts

Deoxyhypusine synthase catalyzes the conversion of lysine to deoxyhypusine residue on the eukaryotic initiation factor 5A (elF-5A) precursor using spermidine as the substrate. Subsequent hydroxylation of the deoxyhypusine residue completes hypusine formation on elF-5A. Hypusine formation is one of the most specific polyamine-dependent biochemical events in eukaryotic cells. Although changes in polyamine metabolism have been demonstrated in human diploid fibroblasts during senescence (Chen and Chang, 1986, J. Cell. Physiol., 128:27-32.), it is unclear whether or not polyamine-dependent hypusine formation itself is an age-dependent biochemical event. In the present study, hypusine-forming activity was measured by a radiolabeling assay in cells whose polyamines have been depleted by prior treatment of alpha-difluoromethyl ornithine (DFMO). In addition, an in vitro cross-labeling assay was developed for simultaneous measurement of the deoxyhypusine synthase activity and protein substrate (elF-5A precursor) amount. We showed that the hypusine-forming activity in low-passage presenescent IMR-90 cells [population doubling level (PDL) = 15-23, termed young cells] was prominently induced by serum whereas little or no hypusine-forming activity could be detected in late-passage senescent cells (PDL = 46-54, termed old cells). The striking difference in hypusine-forming activity between young and old cells was due to changes in both deoxyhypusine synthase activity and elF-5A precursor amount in IMR-90 cells during senescence. However, Northern blot analysis showed no significant difference in the elF-5A messenger RNA (mRNA) between young and old cells, suggesting that the age-dependent attenuation of elF-5A precursor protein may be regulated at either translational or post-translational level.

The age-dependent binding of CBP/tk, a CCAAT binding protein, is deregulated in transformed and immortalized mammalian cells but absent in premature aging cells

CBP/tk, CCAAT Binding Protein for thymidine kinase, has been shown to bind to the distal and proximal CCAAT elements in human TK gene at G1/S boundary in normal human IMR-90 cells after serum stimulation (Pang and Chen, 1993). We now show that the serum-induced binding activity of CBP/tk was inversely related to the population doubling level (PDL) of the normal IMR-90 cells. However, little or almost no CBP/tk binding activity was observed in cells derived from patients with premature aging syndromes (e.g., Werner, Hutchinson-Gilford, and Cockayne syndrome). In contrast, CBP/tk binding activity in SV-40 virus-transformed human cells and in HeLa cells was overexpressed at levels 5- to 15-fold higher than that in normal cells and appeared to be deregulated. The half-life of CBP/tk binding activity in SV-40 transformed cells was at least 10 times longer than that in normal IMR-90 cells, suggesting that posttranslational control may contribute to the deregulation. CBP/tk binding activity detected in other mammalian cells such as murine NIH3T3, an immortal cell line, did not reveal any cell cycle dependence either. Further characterization of CBP/tk binding complex indicates that the binding complex may contain NF-YA and NF-YB and that the binding activity was sensitive to oxidizing reagents. Taken together, our data showed that the age- and cell cycle-dependent nature of CBP/tk is a function of cell types and that CBP/tk binding activity may be subjected to posttranslational and redox regulation.

Elevated levels of glycoprotein gp200 in progeria fibroblasts

The glycosylation of proteins in fibroblasts from people with the premature ageing disease Hutchinson-Gilford Progeria Syndrome (progeria) was investigated. Protein was prepared from fibroblast cell lines established from skin biopsy taken from progeria patients and control donors. Glycoproteins were labelled by the covalent attachment of the steroid hapten digoxygenin to the sugar group. After separation of total protein by SDS-PAGE and electroblotting onto Immobilon-PTM, glycoproteins were detected by enzyme immunoassay. We have observed a glycoprotein of M(r) 200 kDa which is consistently present in protein preparations from progeria fibroblasts and which is absent, or markedly reduced, in preparations from control fibroblasts. This suggests that it may be useful as a marker for progeria. Similar analysis of progeria lymphoblast and control lymphoblast cultures did not show this altered pattern of glycosylated proteins, indicating that it may be cell-type specific. Glycoproteins were also detected by labelling fibroblasts in vitro with D-[6-3H]glucosamine hydrochloride followed by SDS-PAGE of isolated protein and subsequent fluorography. Profiles of glycoproteins from progeria and control fibroblasts were consistent with those obtained from labelling of carbohydrate groups with digoxygenin. Protease digestion of cell protein verified that the band at M(r) 200 kDa contains a protein core. Characteristic features of progeria primarily involve the connective tissue and include wrinkled and loose skin, loss of soft tissue, thin limbs and stiff joints. Death of progeria patients is usually a result of cardiovascular abnormalities. The most consistent manifestations thus involve the connective tissue. The glycoprotein of M(r) 200 kDa which we have observed in progeria fibroblasts in vitro could reflect a perturbation in glycosylation which may underly the connective tissue defects seen in progeria.

Characterization and reconstitution of a cell free system for NAD(+)-dependent deoxyhypusine formation on the 18 kDa eIF-4D precursor

Deoxyhypusine formation on the 18 kDa eIF-4D precursor is due to a covalent linkage between a lysine residue of the protein and the aminobutyl moiety derived from spermidine. The deoxyhypusine is then hydroxylated to form hypusine. This post-translational modification represents one of the most specific spermidine-dependent biochemical events in eukaryotic cells. Deoxyhypusine formation can be performed in vitro at pH 9.5 and is greatly stimulated by NAD+. Using the labeling of the 18 kDa protein by [3H]spermidine as an assay for deoxyhypusine formation, we found that (i) significant deoxyhypusine formation can be demonstrated in vitro at pH 7.2 only if NAD+ is present, (ii) deoxyhypusine formation was sensitive to buffer composition; buffers made of basic amino acids and Tris were inhibitory, (iii) sulfhydryl reagents and metal ions such as Cu2+ and Fe3+ were potent inhibitors of deoxyhypusine formation and (iv) the 18 kDa protein substrate was heat-stable. The in vitro activity of deoxyhypusine formation, which depends on the presence of both enzyme and protein substrate, can be separated from the product, eIF-4D, by a one-step Cibacron blue dye affinity column. Taking advantage of this finding, we have developed a simple procedure, based on the use of Cibacron blue dye, for partially purifying both the deoxyhypusine-forming enzyme and the 18 kDa protein substrate. When the partially purified enzyme and protein substrate were mixed in the presence of 1 mM NAD+ and [3H]spermidine, the 18 kDa protein was radiolabeled, no labeling could be detected if any one component was absent. Using partially purified enzyme, we have also determined the half-life of the protein substrate in alpha-difluoromethyl ornithine (DFMO)-treated NB-15 cells and found it to be longer than 10 h.

Repression of c-fos transcription and an altered genetic program in senescent human fibroblasts

Normal cells in culture invariably undergo senescence, whereby they cease proliferation after a finite number of doublings. Irreversible changes in gene expression occurred in senescent human fetal lung fibroblasts: a non-cell cycle-regulated mRNA was partially repressed; an unusual polyadenylated histone mRNA was expressed; although serum induced c-H-ras, c-myc, and ornithine decarboxylase mRNA normally, ornithine decarboxylase activity was deficient; and serum did not induce mRNA for a replication-dependent histone and for the c-fos proto-oncogene. The loss of c-fos inducibility was the result of a specific, transcriptional block. The results suggest that senescent fibroblasts were unable to proliferate because of, at least in part, selective repression of c-fos; moreover, the multiple changes in gene expression support the view that cellular senescence is a process of terminal differentiation.

Polyamine metabolism and cell-cycle-dependent gene expression in IMR-90 human diploid fibroblasts during senescence in culture

Aging of IMR-90 human diploid fibroblasts in culture is accompanied by specific changes of polyamine metabolism including: (a) a fivefold decrease of serum-induced activity of ornithine decarboxylase (ODC1 EC 4.1.1.17); (b) a six to tenfold increase of polyamine catabolism; and (c) a reduction of putrescine uptake. These changes apparently led to a significant reduction of putrescine accumulation in senescent cells following serum stimulation. Since the induction of ODC is a mid-G1 event, the change of polyamine metabolism may be related to changes of expression of other cell-cycle-dependent genes during cellular aging. In addition to ODC gene, we have examined the expression of two early G1 genes, c-erbB and c-myc, and one late G1/S gene thymidine kinase, at mRNA levels, in both young and old IMR-90 cells. We have also compared the enzyme activities of two late G1/S genes, thymidine kinase and thymidylate synthetase, in young and old cells following serum stimulation. We did not observe significant changes of c-erbB, c-myc, and ODC mRNA levels during cellular senescence. However, we found that serum-induced mRNA level of thymidine kinase gene in old IMR-90 cells was significantly reduced compared to that in the young cells. Results also demonstrate that aging of IMR-90 cells was accompanied by significant decrease of both thymidine kinase and thymidylate synthetase activities. In view of the recognized importance of polyamines in growth regulation, it is possible that alteration of polyamine metabolism may contribute to the impairment of expression of some key G1/S genes and such impairment may contribute to the ultimate loss of dividing potential in senescent cells.

Covalent incorporation of polyamines as gamma-glutamyl derivatives into CHO cell protein

The possible role of polyamines in the covalent modification of proteins in CHO cells was investigated by metabolic labeling with [3H]putrescine. A single radiolabeled protein band with an apparent relative molecular mass of 18,000 Da was observed by SDS-polyacrylamide gel electrophoresis. Almost all the radioactivity covalently linked to this protein was recovered as hypusine. The labeling of this protein was increased several-fold when cells were cultured with alpha-difluoromethylornithine (DFMO) or with this drug plus methylglyoxal bis(guanylhydrazone) (MGBG), as a result of increase in specific radioactivity of the hypusine immediate precursor, spermidine. Also labeled under the latter condition were other cellular proteins. These were aggregates on the top both of the stacking gel and of the running gel, and protein-like materials with relative molecular masses of 36 and 8 kDa. The radioactivity covalently associated with these proteins was recovered after acid hydrolysis as polyamines. The identification of gamma-glutamylputrescine and gamma-glutamylspermidines in proteolytic digests of the acid-insoluble fraction of treated cells indicates that polyamines are covalently linked to these cellular protein. Several possible cellular functions of gamma-glutamylpolyamine protein components are discussed.

A marked increase of fucosylation of glycoproteins in IMR-90 human diploid fibroblasts during senescence in vitro

Possible changes of glycoproteins in IMR-90 human embryonic lung fibroblasts during senescence in vitro were studied by the metabolic labeling technique using radioactive precursors for carbohydrate moieties of glycoproteins. IMR-90 fibroblasts at three different population doubling level (PDL) were incubated with [3H]fucose and [3H]glucosamine for various periods of time. The radioactively labeled glycoproteins were analyzed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) and fluorography. The results indicated a marked increase, by more than eight-fold on per mg protein basis, of labeling by [3H]fucose in old IMR-90 fibroblasts (PDL = 45) as compared to young (PDL = 22) and middle-age (PDL = 30) IMR-90 fibroblasts. In contrast, no significant difference in [3H]glucosamine labeling was observed in young and old IMR-90 cells.

Changes of serum-induced ornithine decarboxylase activity and putrescine content during aging of IMR-90 human diploid fibroblasts

The roles of ornithine decarboxylase (ODC, EC 4.1.1.17) and polyamines in cellular aging were investigated by examining serum-induced changes of these parameters in quiescent IMR-90 human diploid fibroblasts as a function of their population doubling level (PDL) and in human progeria fibroblasts. Serum stimulation caused increases of ODC and DNA synthesis in IMR-90 human diploid fibroblasts, with maximal values occurring, respectively, 10 hr and 22 hr after serum stimulation. Both serum-induced ODC activity and DNA synthesis in IMR-90 cells were found to be inversely related to their PDL. Maximal ODC activity and DNA synthesis in young cells (PDL = approximately 18-22) were, respectively, five-fold and six-fold greater than that in old cells (PDL = approximately 50-55), which in turn were comparable or slightly higher than that in progeria fibroblasts. Polyamine contents (putrescine, spermidine, and spermine) in quiescent IMR-90 cells did not show significant PDL-dependency. The putrescine and spermine contents in quiescent progeria cells were comparable to those in quiescent IMR-90 cells. The spermidine content in quiescent progeria cells, however, was extremely low, less than half of that in quiescent IMR-90 cells. Serum stimulation caused a marked increase in putrescine content in young cells but not in old cells or in progeria cells. The spermidine and the spermine content in IMR-90 cells, either young or old, and in progeria cells did not change significantly after serum stimulation. Our study indicated that aging of IMR-90 human diploid fibroblasts was accompanied by specific changes of polyamine metabolism, namely, the serum-induced ODC activity and putrescine accumulation. These changes were also observed in progeria fibroblasts derived from patients with Hutchinson-Gilford syndrome.