On the activity and fidelity of chromatin-associated hepatic DNA polymerase-beta in aging murine species of different life spans

Replicative enzymes, DNA polymerase alpha (pol alpha), and in vitro ageing

Normal cells in culture are used to investigate the underlying mechanisms of DNA synthesis because they retain regulatory characteristics of the in vivo replication machinery. During the last few years new studies have identified a number of genetic changes that occur during in vitro ageing, providing insight into the progressive decline in biological function that occurs during ageing. Maintaining genomic integrity in eukaryotic organisms requires precisely coordinated replication of the genome during mitosis, which is the most fundamental aspect of living cells. To achieve this coordinated replication, eukaryotic cells employ an ordered series of steps to form several key protein assemblies at origins of replication. Major progress has recently been made in identifying the enzymes, and other proteins, of DNA replication that are recruited to origin sites and the order in which they are recruited during the process of replication. More than 20 proteins, including DNA polymerases, have been identified as essential components that must be preassembled at replication origins for the initiation of DNA synthesis. Of the polymerases, DNA polymerase alpha-primase (pol alpha) is of particular importance since its function is fundamental to understanding the initiation mechanism of eukaryotic DNA replication. DNA must be replicated with high fidelity to ensure the accurate transfer of genetic information to progeny cells, and decreases in DNA pol alpha activity and fidelity, which are coordinated with cell cycle progression, have been shown to be important facets of a probable intrinsic cause of genetic alterations during in vitro ageing. This has led to the proposal that pol alpha activity and function is one of the crucial determinants in ageing. In this review we summarize the current state of knowledge of DNA pol alpha function in the regulation of DNA replication and focus in particular on its interactive tasks with other proteins during in vitro ageing.

Age-associated changes in the template-reading fidelity of DNA polymerase alpha from regenerating rat liver

DNA polymerases (deoxynucleosidetriphosphate: DNA deoxynucleotidyltransferase EC 2.7.7.7.) were extracted from regenerating livers from young and aged rats. DNA polymerase alpha was separated and partially purified by DEAE-cellulose column chromatography, polyethyleneglycol precipitation, and phosphocellulose column chromatography, and fidelity levels were then monitored with the synthetic template-primer poly (dG-dC). The fidelity level of the DNA polymerase from regenerating liver a 4-month-old rat was very high, while that of the DNA polymerase from a 24-month-old rat was significantly decreased. To confirm this result, DNA was synthesized on poly (dG-dC) in a reaction mixture containing [32P]dTTP, and the synthetic polynucleotide was purified and digested with HhaI restriction endonuclease. After hydrolysis, the oligonucleotides were developed by two dimensional thin layer chromatography on PEI cellulose plates. Spots containing [32P]dTMP were observed when DNA polymerase from a 24 month-old rat was used, but none was found in polynucleotides synthesized using DNA polymerase from a 4 month-old rat. Nearest neighbor analysis suggested that dG-dT and dC-dT pairs were constructed by mis-incorporation due to DNA polymerase alpha.

The role of DNA damage in cellular aging: is it time for a reassessment?

There is now evidence that the immediate cause of the loss of proliferative capacity in senescent cells is mediated by a specific inhibitor. If this tentative interpretation is correct, the next hurdle will be to determine mechanism(s) that regulate this putative senescence cell inhibitor that would, in effect, be the determinant of proliferative life span. One previously proposed hypothesis predicts that the decline of replicative activity is analogous to a checkpoint response to accumulated chromosomal damage (Rosenberger et al., 1991). Advances in our basic understanding of the nature of DNA damage, DNA repair mechanisms, and the response of eukaryotic cells to accumulated DNA damage provide a solid rationale for a reassessment of the causal role of the accumulation of chromosomal damage in cell senescence in vitro.

Age-related changes in expression and activity of DNA polymerase alpha: some effects of dietary restriction

DNA polymerase alpha (pol alpha) purified from human diploid fibroblasts (HDF) and from livers of C57BL/6N mice showed age-related decreases in: (1) mRNA levels; (2) the amount of enzyme isolated per cell; and (3) enzyme activity (HDF); as well as: a) the amount of enzyme isolated; b) the specific activity; and c) the enzyme fidelity (liver). Hepatic pol alpha from dietary restricted (DR) mice exhibited less of a decline in specific activity and copied synthetic DNA templates with relatively higher fidelity than did enzymes from animals fed ad libitum (AL). Pol alpha from fetal-derived HDF exhibited increased expression compared with aged donor-derived HDF, with both fetal and old cell pol alpha in normal cells being expressed at lower levels than in their transformed cell corollaries. Treatment of human pol alpha from aged donor-derived HDF with a pol alpha accessory protein isolated from log phase murine cells resulted in increased pol alpha binding of DNA and increased pol alpha activity. However, highly active pol alpha isolated from fetal-derived or transformed HDF, or from transformed murine cells, showed little or no activity enhancement in the presence of accessory protein. These data indicate that, as a function of increased age, there is a decrease in pol alpha expression and specific activity in HDF, as well as decreases in specific activity and fidelity of pol alpha in essentially amitotic murine hepatic tissues. Dietary restriction impedes the age-related declines in both activity and fidelity of hepatic pol alpha in mice. The data further indicate that transformation of slowly dividing HDF is associated with increased expression of pol alpha, but suggest that increased expression alone is not sufficient to explain the difference in polymerase activity levels between parental and transformed HDF. Lastly, the data suggest that interaction of pol alpha with an essential accessory protein may be altered as a function of age, an alteration that appears to be correlated with the decline in pol alpha DNA binding and specific activity.

The biochemistry of mammalian senescence

Senescence is a process which, until quite recently, has been the subject of little scientific investigation. Even the word "senescence" is difficult to define, and complex methodological pitfalls have impeded progress. In the past few years, there have been exciting advances in understanding the physiological, cell biological, biochemical, and molecular biological nature of senescence. Changes in membrane function, protein synthesis, DNA structure (including glycosylation, altered tertiary structure, free-radical effects, and loss of telomeric DNA), and changes in gene regulation with age are reviewed. Recent work on changes in responses to transcriptional regulatory proteins and cellular senescence factors, some of which have been identified, is particularly promising and leads to the conclusion that senescence, at least in part, is a programmed process. Despite these advances, the fundamental cause of senescence remains elusive but might, as in the case of other biological processes which are phylogenetically widespread, turn out to be quite simple, and perhaps, even modifiable.

Effect of dietary restriction on the fidelity of DNA polymerases in aging mice

DNA polymerases purified from hepatic tissues of C57BL/6 mice showed an age-related decrease in both specific activity and fidelity of the various enzyme forms. Polymerases from dietary restricted mice exhibited less of a decline in specific activity and copied synthetic DNA templates with relatively higher fidelity than did enzymes from animals fed ad libitum. Polymerases treated with inositol-1,4-bisphosphate [I(1,4)P2] showed varying levels of increased activity, with fidelity increases up to 3-fold. These data indicate that aging is associated with decreases in both specific activity and fidelity of DNA polymerases isolated from a nondividing tissue, and that dietary restriction impedes the age-related decline in both specific activity and fidelity of these polymerases. The data further indicate that DNA polymerases may interact with phosphoinositide hydrolysis products resulting in increased specific activity and fidelity of the enzymes. Phosphoinositide interactions with polymerases could constitute an important mechanism moderating the age-related decrease in function and accuracy of DNA polymerases.

Mouse DNA polymerase beta gene promoter: fine mapping and involvement of Sp1-like mouse transcription factor in its function

The promoter of mouse DNA polymerase beta gene was analyzed by combining 5'-upstream region of this gene with chloramphenicol acetyltransferase (CAT) gene and by introduction of the recombinant plasmid DNA into mouse NIH/3T3 cells. Serial deletion of the mouse DNA sequence revealed that the promoter function resides within a 33 base pair region from the nucleotide position -48 to -15 with respect to the transcription initiation site, and is highly active without enhancer sequence. The promoter region was separated into two subregions: one (-48 to -35) contains a GC-box and the other contains a 10 base pair palindrome, whose sequence is similar to one of promoter consensus sequences found in a number of promoters including adenovirus promoters. The DNA polymerase beta promoter-directed CAT expression was competitively inhibited by the simultaneous transfection of plasmid DNA containing SV40 early promoter sequence. The viral sequences which are competitive to the GC-box of DNA polymerase beta gene promoter were the GC-boxes of SV40 promoter. Therefore, it is concluded that transcription of mouse DNA polymerase beta gene is regulated by mouse trans-acting factors equivalent to human Sp1 which is known to be trans-acting protein factor acting on SV40 GC-box sequences.

Strategies and criteria for the development of molecular biomarkers of senescence

While it may be possible to employ panels of molecular parameters which correlate with senescence in vivo or in vitro, in a manner analogous to the use of mutagenesis assays for economic carcinogen screening, such an endeavor would at present be impeded by the absence of a clear mechanistic rationale for focusing on particular biomarkers, and by the complexity of the senescent phenotype and its multilevel interactions. Nevertheless, insight into the mechanism(s) of senescence may derive indirectly from correlative studies, or directly from strategies of molecular intervention, provided that such studies meet reasonable criteria for relevance and functionality. Even the control of expression of a single gene may be quite complex, with multigenic interactions and the potential to produce a cascade affecting many downstream genes. In order to understand such processes, functional assays and selective systems will need to be developed.

Murine DNA polymerase beta gene: mapping of transcription initiation sites and the nucleotide sequence of the putative promoter region

The nucleotide sequence of the region (total, 2,512 base pairs [bp]) from intron 2 to the 5'-flanking region was determined for the mouse DNA polymerase beta genomic clone, and the 300-bp region from intron 1 to the 5'-flanking region was also sequenced for the rat clone. At 51 bp upstream from the ATG codon which was previously suggested to be the translation initiation codon for the rat cDNA sequence, we found another ATG in the same reading frame in both mouse and rat genes. Three major transcription initiation sites (cap sites) each for rat and mouse DNA polymerase beta mRNAs were localized precisely by primer extension analysis at 51, 41, and 0 bp upstream from the first ATG codon, suggesting that this codon is used for translation initiation. The 400-bp region around exon 1 was extremely G + C rich (about 70%). Although neither a TATA box nor a CAAT box was found within the 500-bp region upstream of the 5'-most cap site, triple repeats of 5'-CCGCCC were found within the 100-bp region flanking the cap site.

Murine DNA polymerase beta gene: mapping of transcription initiation sites and the nucleotide sequence of the putative promoter region

The nucleotide sequence of the region (total, 2,512 base pairs [bp]) from intron 2 to the 5'-flanking region was determined for the mouse DNA polymerase beta genomic clone, and the 300-bp region from intron 1 to the 5'-flanking region was also sequenced for the rat clone. At 51 bp upstream from the ATG codon which was previously suggested to be the translation initiation codon for the rat cDNA sequence, we found another ATG in the same reading frame in both mouse and rat genes. Three major transcription initiation sites (cap sites) each for rat and mouse DNA polymerase beta mRNAs were localized precisely by primer extension analysis at 51, 41, and 0 bp upstream from the first ATG codon, suggesting that this codon is used for translation initiation. The 400-bp region around exon 1 was extremely G + C rich (about 70%). Although neither a TATA box nor a CAAT box was found within the 500-bp region upstream of the 5'-most cap site, triple repeats of 5'-CCGCCC were found within the 100-bp region flanking the cap site.

Cellular senescence revisited: a review

The field of cellular senescence (cytogerontology) is reviewed. The historical precedence for investigation in this field is summarized, and placed in the context of more recent studies of the regulation of cellular proliferation and differentiation. The now-classical embryonic lung fibroblast model is compared to models utilizing other cell types as well as cells from donors of different ages and phenotypes. Modulation of cellular senescence by growth factors, hormones, and genetic manipulation is contrasted, but newer studies in oncogene involvement are omitted. A current consensus would include the view that the life span of normal diploid cells in culture is limited, is under genetic control, and is capable of being modified. Finally, embryonic cells aging in vitro share certain characteristics with early passage cells derived from donors of increasing age.

Fidelity of DNA polymerase-beta in neurons from young and very aged mice

Neurons do not divide during adult life and thus they provide a unique system to study the effects of age-accumulated damage to DNA in the absence of DNA replication. We have analyzed DNA polymerase activity in neurons isolated from young adult and very aged mice. The predominant catalytic activity is DNA polymerase-beta and it is present in similar amounts in neurons from young and old mice. This polymerase is highly error-prone in copying phi X174 DNA, the error frequency being about 1/7,000 and not significantly different when obtained from young and old animals. This high infidelity is considered with respect to DNA repair and the protein synthesis error catastrophe theory of aging.

Age changes of chromatin. A review

The age-related studies of chromatin and DNA has attracted significant interest in recent years. However, individual works describe only some and a few of the many changes of chromatin. It is often difficult to decide whether these changes have secondary or primary nature. The overview of these studies makes it possible to realize how many very complex and interdependent changes occur in chromatin during ageing. Chromatin is the most complex among self-reproducible parts of the cell. A very sophisticated structure of chromatin makes possible the differential transcription of a genetic programme which supports the accurate specialized functions of each cell in interphase and also provides a mechanism for perfect reproduction of this complex machinery of genetic information during cell division. It is known that chromatin proteins, more than chromatin DNA show tissue specificity and developmental changes. There are many theories of cellular ageing which select some special types of DNA, RNA or protein changes and to promote them as the main or primary causes of cellular senescence. However, if these changes are considered within the more comprehensive picture of functional structure of chromatin the results show the interdependence of individual alterations and their proper place in the complex, multichannel, species and tissue-specific character of actual ageing. An attempt to summarize the basic facts and theories about age changes of the two main parts of chromatin structure, proteins and DNA is being made in this review. At the same time the author tried to develop a concept of non-random distribution of the age changes in chromatin and a possible higher rate of accumulation of different alteration and lesions in the transcribed and functionally active parts of chromatin.

Longevity-dependent organ-specific accumulation of DNA damage in two closely related murine species

To measure directly the accumulation of DNA damage with age, and to understand better the effect of modulators of DNA damage in vivo, the DNA of brain, liver, and kidney of two mice from different families, Mus musculus and Peromyscus leucopus, have been examined for age-dependent accumulation of single-strand breaks plus alkali-labile bonds, by the alkaline sucrose sedimentation method. These two species of small rodents are closely related taxonomically, yet differ significantly in maximum achievable lifespan. Using the reciprocal of the number average molecular weight for estimation of DNA size, these analyses indicate that: (a) DNA damage does not measurably accumulate in brain tissue; (b) the accumulation of DNA damage was more pronounced in hepatic DNA than other tissue DNA; and (c) the rate of accumulation of DNA damage in liver and kidney cells with age was greater in the shorter-lived species (M. musculus) and was inversely proportional to maximum achievable lifespan. There are suggestions that a similar threshold might exist for tolerance of DNA damage in the two species in specific organs, and that these species differ in the rate at which this threshold is reached as a function of maximum achievable lifespan.

S-phase transit times as a function of age in human diploid fibroblasts

The minimum time it takes a cell to pass completely through the S phase (MIN S) was examined in human diploid fibroblasts using a sequential [14C]thymidine, [3H]thymidine, [14C]thymidine labeling protocol. MIN S appeared to be around 6-8 h for both WI-38 and MRC-5 cells. In addition, MIN S did not increase in senescent cultures. Since damage to either DNA, its polymerases, or both would result in a reduction in the rate of DNA synthesis and a corresponding increase in MIN S, this suggests that in senescent cultures at least a portion of the cells contain DNA that is relatively undamaged and DNA polymerases that exhibit normal replicative kinetics.

Delayed and reduced cell replication and diminishing levels of DNA polymerase-alpha in regenerating liver of aging mice

Kinetics of cell replication was compared in regenerating livers of Mus musculus at ages ranging between 6 and 32 months. Incorporation of [3H]-thymidine into DNA and autoradiographic analysis showed that the maximal extent of DNA replication following partial hepatectomy became delayed with age. Furthermore, the total fraction of parenchymal and nonparenchymal cells in S phase at different intervals during regeneration diminished as mice aged. The specific activity of DNA polymerase-alpha, the putative replicative enzyme, declined progressively during aging. The specific activity of DNA polymerase-beta, the purported repair enzyme, declined to an appreciably lesser extent during the lifespan of the mouse. No evidence was found for the appearance of a specific inhibitor of polymerase-alpha in senescent mouse liver. Also, the bulk of the activities of both hepatic DNA polymerase-alpha and -beta remained localized in the cell nucleus throughout the lifetime of the animal and were mainly associated with chromatin.

Changes in DNA polymerases alpha, beta and gamma in mouse liver as a function of age

The activities of DNA polymerases alpha, beta and gamma were determined in mouse liver as a function of age by a combination of glycerol density gradient centrifugation with polymerase specific assays. Although alpha polymerase was preserved throughout the life span, the activity dropped sharply from a high level at the fetal and neonatal stages to a level one order lower after maturation through adjustment of the amount of protein administered. beta polymerase showed similar but less drastic changes than alpha. DNA polymerase gamma activity increased about two-fold in going from newborn to adult stages and remained constant after maturation. According to the amount of DNA, DNA polymerase alpha decreased after birth, but the change was less drastic compared to that through adjustment of the amount of protein. DNA polymerase beta increased the activity 2-3-fold within a period of 3 months following birth. gamma polymerase underwent more than a 10-fold increase in activity through adjustment of the amount of DNA within the same period.

Unscheduled DNA synthesis and elimination of DNA damage in liver cells of gamma-irradiated senescent mice

The level of 'spontaneous' and gamma-radiation-induced DNA synthesis which is not inhibited with hydroxyurea (unscheduled synthesis) is considerably lower in hepatocytes of 18-22-month-old mice than that of 1.5-2-month-old mice. The dose-dependent increase (10-300 Gy) of unscheduled DNA synthesis (UDS) in hepatocytes of senescent mice is higher than in young animals. The elimination of damage in DNA of gamma-irradiated hepatocytes (100 Gy) was examined by using an enzyme system (M. luteus extract and DNA-polymerase I of E. coli). It was found that the rate of elimination of the DNA damage in hepatocytes of 20-month-old mice is lower than that of 2-month-old mice although the activities of DNA-polymerase beta and apurinic endonuclease remain equal in the liver of both senescent and young mice. However, the nucleoids from gamma-irradiated liver nuclei of 2-month-old mice are relaxed to a greater extent (as judged by the criterion of ethidium-binding capacity) than those of 20-month-old mice. The results suggest that there are limitations in the functioning of repair enzymes and in their access to damaged DNA sites in the chromatin of senescent mouse liver cells.