Flow-cytometric assessment of cellular poly(ADP-ribosyl)ation capacity in peripheral blood lymphocytes.

BACKGROUND: Poly(ADP-ribosyl)ation is a posttranslational modification of nuclear proteins catalysed by poly(ADP-ribose) polymerases (PARPs), using NAD+ as a substrate. Activation of PARP-1 is in immediate response to DNA damage generated by endogenous and exogenous damaging agents. It has been implicated in several crucial cellular processes including DNA repair and maintenance of genomic stability, which are both intimately linked with the ageing process. The measurement of cellular poly(ADP-ribosyl)ation capacity, defined as the amount of poly(ADP-ribose) produced under maximal stimulation, is therefore relevant for research on ageing, as well as for a variety of other scientific questions. RESULTS: This paper reports a new, robust protocol for the measurement of cellular poly(ADP-ribosyl)ation capacity in PBMC or Jurkat T-cells using flow cytometry, based on a previously established immuno-dot-blot assay. In order to validate the new assay, we determined the dose-response curve of 3-aminobenzamide, a well-known competitive PARP inhibitor, and we derived an IC50 that is very close to the published value. When testing a set of PBMC samples taken from fifteen healthy young human donors, we could confirm the presence of a substantial interindividual variation, as previously observed using a radiometric assay. CONCLUSION: The methodology described in this paper should be generally useful for the determination of cellular poly(ADP-ribosyl)ation capacity in a wide variety of settings, especially for the comparison of large sets of samples, such as population studies. In contrast to previously published radiometric or immuno-dot-blot assays, the new FACS-based method allows (i) selective analysis of mononuclear cells by gating and (ii) detection of a possible heterogeneity in poly(ADP-ribosyl)ation capacity between cells of the same type.

An investigation of DNA mismatch repair capacity under normal culture conditions and under conditions of supra-physiological challenge in human CD4+T cell clones from donors of different ages.

T cells undergo rapid clonal expansion upon antigenic stimulation to produce an effective immune response. Any defect in the DNA mismatch repair (MMR) system may have a detrimental effect on T cell proliferation. This study employed an in vitro model of human CD4+T cell ageing to investigate MMR capacity at various stages of T cell lifespan. A novel modification of the alkaline comet assay, which utilised T4 endonuclease VII to detect single base DNA mismatches, was used to assess DNA mismatch frequency. No clear pattern in DNA mismatch frequency with increasing culture age was observed. However, the ability to repair induced DNA mismatches (following treatment with acridine mutagen ICR-191) revealed an age-related decline in the efficiency of the MMR system in clones derived from a 26 and a 45-year-old donor, but not from an 80-year-old very healthy SENIEUR donor. This study suggests that unchallenged, dividing human T cell clones have variable levels of DNA mismatches throughout their lifespan, not affecting proliferation. However, when challenged with supra-physiological levels of DNA mismatches, deficiencies were found in ageing T cell clones in MMR capacity, with the exception of T cell clones from a SENIEUR donor previously shown to maintain effective DNA excision repair.

HLA haplotypes and TNF polymorphism do not associate with longevity in the Irish.

Polymorphism of the human leukocyte antigen has been implicated in a number of autoimmune disorders including ageing. In the course of the present study, no association of the human leukocyte antigen (HLA)-A1, B8, DR3 haplotype with a male Irish aged population, as previously reported, was observed. Two polymorphic nucleotides in the TNF cluster (G-308A TNF-alpha and G+252A TNF-beta), associated with increased TNF-alpha production, were shown to be in tight linkage disequilibrium with the class I and II HLA loci, generating HLA haplotypes with extended linkage disequilibrium. However, no age-related allele or genotype frequencies were observed for either polymorphic nucleotide.

An investigation of DNA excision repair capacity in human CD4+ T cell clones as a function of age in vitro.

DNA damage has been shown to increase with age in lymphocytes of healthy humans and in human CD4+ T cell clones. Such genetic damage, if unrepaired, may have a detrimental effect on lymphocyte-mediated immune responses. This study investigated DNA excision repair capacity of human CD4+ T cell clones as a function of age in vitro. Cultures of T cell clones were treated with a range of DNA damaging agents; hydrogen peroxide, N-methyl-N'-nitro-N-nitrosoguanidine or 254 nm ultraviolet irradiation. Following treatment, the amount of DNA damage in the clones was determined over a time course using modified comet assays. The results obtained revealed a decline related to in vitro age in the DNA repair capacity of clones derived from a 26 and a 45 year old donor. This decline may represent at least a partial explanation for the age related increase in DNA damage in these clones when cultured in vitro. In contrast, there was no evidence for a decline related to in vitro age in repair capacity in the clones derived from an 80 year old SENIEUR donor. An alternative mechanism must underlie the age related increased in DNA damage in these clones when cultured in vitro.

Effects of a reduced oxygen tension culture system on human T cell clones as a function of in vitro age.

Oxidative DNA damage has been suggested to contribute to the decline in T cell clone (TCC) function with increased age in vitro. To test this hypothesis the effect of a reduced oxygen tension culture system (6% O(2)) on TCCs was examined. Specifically, the effects of the altered culture conditions on DNA damage levels, in vitro lifespan and proliferative capacity were assessed in five independently derived human CD4+ TCCs. DNA damage levels over the entire lifespan were significantly lowered by reducing oxygen tension. Lifespan (total population doublings (PDs) achieved) and proliferative capacity (PDs/week) were reduced for all clones under reduced oxygen tension when compared to standard culture conditions. This observed tendency warrants further investigation using a greater number of clones from donors of all age groups before definitive conclusions regarding the effect of low oxygen tension on the lifespan and proliferative capacity of TCC can be made. However, these results may suggest that the reduced oxygen tension culture system has interfered with some aspect of T cell biology not yet examined within the remit of this study.