Warren W. Nichols

Potential DNA Vaccine Integration into Host Cell Genome

Studies have been designed to examine the potential integration of DNA vaccines into the host cell genome. This is of concern because of the possibility of insertional mutagenesis resulting in the inactivation of tumor suppressor genes or the activation of oncogenes. The requirements for adequate testing were determined to be (1) a method to purify host cell genomic DNA from nonintegrated free plasmid, (2) a sensitive method to detect integrated plasmid in the purified genomic DNA, and (3) stringent methods to avoid contamination. These requirements were fulfilled by agarose-gel electrophoresis, the polymerase chain reaction, and separation of each activity with stringent handling procedures, respectively. An exploratory experiment was carried out in which mice were injected with 100 micrograms of vaccine plasmid DNA in each quadriceps. Examination of quadriceps and 12 other tissues at several time points failed to reveal any evidence of integration at a sensitivity level that could detect 1 to 7.5 integrations in 150,000 nuclei. A worst-case scenario determined that this would be at least 3 orders of magnitude below the spontaneous mutation frequency.

Plasmid DNA Vaccines: Tissue Distribution and Effects of DNA Sequence, Adjuvants and Delivery Method on Integration into Host DNA

A variety of factors could affect the frequency of integration of plasmid DNA vaccines into host cellular DNA, including DNA sequences within the plasmid, the expressed gene product (antigen), the formulation, delivery method, route of administration, and the type of cells exposed to the plasmid. In this report, we examined the tissue distribution and potential integration of plasmid DNA vaccines following intramuscular administration in mice and guinea pigs. We compared needle versus Biojector (needleless jet) delivery, examined the effect of aluminum phosphate adjuvants, compared the results of different plasmid DNA vaccines, and tested a gene (the human papilloma virus E7 gene) whose protein product is known to increase integration frequency in vitro. Six weeks following intramuscular injection, the vast majority of the plasmid was detected in the muscle and skin near the injection site; lower levels of plasmid were also detected in the draining lymph nodes. At early time points (1–7 days) after injection, a low level of systemic exposure could be detected. Occasionally, plasmid was detected in gonads, but it dissipated rapidly and was extrachromosomal – indicating a low risk of germline transmission. Aluminum phosphate adjuvant had no effect on the tissue distribution and did not result in a detectable increase in integration frequency. Biojector delivery, compared with needle injection, greatly increased the uptake of plasmid (particularly in skin at the injection site), but did not result in a detectable increase in integration frequency. Finally, injection of a plasmid DNA vaccine containing the human papilloma virus type 16 E7 gene, known to increase integration in vitro, did not result in detectable integration in mice. These results suggest that the risk of integration following intramuscular injection of plasmid DNA is low under a variety of experimental conditions.

Plasmid DNA vaccines: investigation of integration into host cellular DNA following intramuscular injection in mice.

The primary safety concern for DNA vaccines is their potential to integrate into the host cell genome. We describe an integration assay based on purification of high-molecular-weight genomic DNA away from free plasmid using gel electrophoresis, such that the genomic DNA can then be assayed for integrated plasmid using a sensitive PCR method. The assay sensitivity was approximately 1 plasmid copy/µg DNA (representing ∼150,000 diploid cells). Using this assay, we carried out integration studies of three different plasmid DNA vaccines, containing either the influenza hemagglutinin, influenza matrix or HIV gag gene. Six weeks after intramuscular injection, free plasmid was detected in treated muscle at levels ranging from approximately 1,000 to 4,000 copies/µg DNA. At 6 months, the plasmid levels ranged between 200 and 800 copies/µg DNA. Gel purification of genomic DNA revealed that essentially all of the detectable plasmid in treated quadriceps was extrachromosomal. If integration had occurred, the frequency was ≤1–8 integrations per 150,000 diploid cells, which would be at least three orders of magnitude below the spontaneous mutation rate. Our results suggest that the risk of mutation due to integration of plasmid DNA vaccines following intramuscular injection is negligible.

Revalidation of the in vitro alkaline elution/rat hepatocyte assay for DNA damage : improved criteria for assessment of cytotoxicity and genotoxicity and results for 81 compounds

The in vitro alkaline elution/rat hepatocyte assay is a sensitive assay for genotoxicity, measured as DNA strand breaks induced in primary cultures of rat hepatocytes after 3-h treatments with test compounds. Since DNA degradation can be rapid and extensive in dead and/or dying cells, the original criteria for a positive result in the assay were that a compound induce a 3.0-fold or greater increase in the elution slope (for the terminal phase of alkaline elution from 3 to 9 h) in the absence of significant cytotoxicity (defined as relative cell viability of less than 70% by trypan blue dye exclusion; TBDE). Recently we have shown that false-positive results can still be obtained due to cytotoxicity when loss of membrane integrity is a late event in toxic cell death relative to the induction of endonucleolytic DNA degradation. To improve the ability of the assay to discriminate between genotoxic vs. cytotoxic effects of chemicals, we have evaluated additional assays of cytotoxicity including cell adenosine triphosphate (ATP) and potassium (K+) content, tetrazolium dye reduction (MTT), TBDE after a further 3-h recovery incubation without test chemicals (delayed toxicity), cell blebbing and endonucleolytic DNA degradation (double-strand breaks; DSBs) assessed by pulsed-field gel electrophoresis (PFGE). We have also evaluated 2 parameters derived from the elution data which can indicate extensive, cytotoxicity-induced DNA degradation: the fraction of the DNA recovered in the neutral lysis/rinse fraction and the gamma-intercept of the extrapolation of the 3-9-h segment of the elution curve. Twenty-eight rodent non-carcinogens that are negative (or inconclusive) in the Ames assay with no, or limited, other evidence of genotoxicity, and 33 genotoxins, most of which are also carcinogens, were evaluated. The results showed that DNA degradation as measured by a 1-h PACE (Programmed Autonomously Controlled Electrodes)/PFGE assay was a sensitive indicator of cytotoxicity which correlated well with results of the other cytotoxicity indicators. The delayed TBDE (after a 3-h recovery), intracellular potassium and ATP assays as well as the gamma-intercept parameter were also shown to be sensitive and in some cases complementary measures of cytotoxicity. Using new criteria based on these data of an induced slope (treatment slope-negative control slope) of 0.020 for the 3- to 9-h elution period and cytotoxicity limits of 70% relative viability for the delayed TBDE assay and 50% for intracellular ATP content, the assay scores the genotoxicity of these 61 reference compounds with an overall accuracy of 92%. Test results using these new criteria are provided for an additional 20 compounds (5 non-genotoxic carcinogens and 15 compounds whose genotoxic and carcinogenic potential are unknown or equivocal).

DNA synthesis inhibition as an indirect mechanism of chromosome aberrations: comparison of DNA-reactive and non-DNA-reactive clastogens

Positive results in the in vitro assay for chromosome aberrations sometimes occur with test chemicals that apparently do not react with DNA, being negative in tests for mutation in bacteria, for DNA strand breaks, and for covalent binding to DNA. These chromosome aberrations typically occur over a narrow concentration range at toxic doses, and with mitotic inhibition. Indirect mechanisms, including oxidative damage, cytotoxicity and inhibition of DNA synthesis induced by chemical exposure, may be involved. Understanding when such mechanisms are operating is important in evaluating potential mutagenic hazards, since the effects may occur only above a certain threshold dose. Here, we used two-parameter flow cytometry to assess DNA synthesis inhibition (uptake of bromodeoxyuridine [BrdUrd]) associated with the induction of aberrations in CHO cells by DNA-reactive and non-reactive chemicals, and to follow cell cycle progression. Aphidicolin (APC), a DNA polymerase inhibitor, induces aberrations without reacting with DNA; 50 microM APC suppressed BrdUrd uptake during a 3-h treatment to <10% of control levels. Several new drug candidates induced aberrations concomitant with marked reductions in cell counts at 20 h (to 50-60% of controls) and suppression of BrdUrd uptake (<15% of control). Several non-mutagenic chemicals and a metabolic poison, which induce DNA double strand breaks and chromosome aberrations at toxic dose levels, also suppressed DNA synthesis. In contrast, the alkylating agents 4-nitroquinoline-1-oxide, mitomycin C, methylnitrosourea, ethylnitrosourea, methylmethane sulfonate and ethylmethane sulfonate, and a topoisomerase II inhibitor, etoposide, produced many aberrations at concentrations that were less toxic (cell counts >/=73% of controls) and gave little inhibition of DNA synthesis during treatment (BrdUrd uptake >/=85% of controls), although cell cycle delay was seen following the 3-h treatment. Thus, inhibition of DNA synthesis at the time of treatment is supporting evidence for an indirect mechanism of aberrations, when there is no direct DNA reactivity.

No Requirement for V(D)J Recombination in p53-Deficient Thymic Lymphoma

ABSTRACT The p53 tumor suppressor is activated in response to a variety of cellular stress signals, although specific in vivo signals that trigger tumor suppression are unknown. In mouse thymocytes, where p53 inactivation leads to tumorigenesis, several observations suggest that V(D)J recombination of T-cell receptor (TCR) loci could provide a DNA damage signal triggering p53-dependent apoptosis and tumor suppression. Inactivation of p53 would allow V(D)J driven mutation of additional cancer genes, facilitating tumorigenesis. Here, we show that mice with a p53 deficiency in thymocytes and unable to carry out V(D)J recombination are not impaired in the development of thymoma. Recombination-activating gene (RAG) deficiencies were introduced into both p53−/− mice and TgTΔN transgenic mice, a strain in which 100% of the mice develop thymoma due to thymocyte-specific inactivation of p53 by a simian virus 40 T-antigen variant. V(D)J recombination was dispensable for tumorigenesis since thymomas developed with or without the RAG-1 or RAG-2gene, although some delay was observed. When V(D)J recombination was suppressed by expression of rearranged TCR transgenes, 100% of the TgTΔN mice developed thymoma, surprisingly with reduced latency. Further introduction of a RAG deficiency into these mice had no impact on the timing or frequency of tumorigenesis. Finally, karyotype and chromosome painting analyses showed no evidence for TCR gene translocations in p53-deficient thymomas, although abundant aneuploidy involving frequent duplication of certain chromosomes was present. Thus, contrary to the current hypothesis, these studies indicate that signals other than V(D)J recombination promote p53 tumor suppression in thymocytes and that the mechanism of tumorigenesis is distinct from TCR translocation oncogene activation.

Age-dependent decline in rejoining of X-ray-induced DNA double-strand breaks in normal human lymphocytes

Unstimulated human peripheral blood lymphocytes (HPBL), separated by density centrifugation from anticoagulated whole blood, were X-irradiated (30 Gy) on ice and incubated in medium at 37 degrees C for repair times of 15, 30, and 120 min. Blood donors were 18 normotensive, non-smoking Caucasians aged 23-78, free from overt pathology and not taking any medications. Neutral filter elution was used to assay DNA double-strand break (DSB) induction and completeness of DSB rejoining (plus rejoining of any X-ray-induced alkali-labile sites converted to DSBs in vitro at pH 9.6). After 30 or 120 min repair incubation, the percentage of DSBs rejoined by cells from older donors (aged 66-78 years) was less than half the percentage of DSBs rejoined by cells from younger donors (aged 23-39 and 42-57). When data from the 3 age groups were pooled, the age-related decline in percent DSBs rejoined was significant for repair times 30 min (r = -0.63, p less than 0.005) and 120 min (r = -0.64, p less than 0.005) but not for 15 min (r = -0.04). These age-related declines were observed even though DNA from older donors sustained fewer strand breaks as demonstrated by the negative correlation between donor age and DSB induction (r = -0.65, p less than 0.005). These results suggest that the efficacy of X-ray-induced DSB repair diminishes with in vivo age in unstimulated HPBL.

Cytotoxicity as measured by trypan blue as a potentially confounding variable in the in vitro alkaline elution/rat hepatocyte assay.

Rat hepatocytes treated in vitro with A2RA, an angiotensin II receptor antagonist, displayed an increased level of DNA-strand breaks as determined by alkaline elution, without an appreciable increase in cytotoxicity as determined by a trypan blue dye exclusion assay at harvest. The alkaline elution profile appeared to have two components: a rapidly eluting component detected in the first fraction collected (often associated with DNA from dead or dying cells), followed by a more slowly eluting component detected in the subsequent fractions. Further analysis of hepatocytes treated with A2RA by pulsed-field gel electrophoresis and neutral elution revealed significant levels of DNA double-strand breaks. Electron microscopy (EM) showed pronounced damage to mitochondria; although cell blebbing was seen using both EM and light microscopy, the plasma and nuclear membranes appeared intact when examined by EM. Cellular ATP levels decreased precipitously with increasing doses of A2RA, falling to less than 10% of control values at a dose of 0.213 mM A2RA, a concentration showing 100% relative viability by trypan blue at harvest. Thus, whereas in our experience trypan blue dye exclusion accurately reflects cytotoxicity induced by the majority of test agents, in this rather unusual case, trypan blue did not accurately reflect compound-induced cytotoxicity at harvest since there was no concurrent loss of membrane integrity. However, when hepatocytes treated with A2RA were incubated for either 3 h or 20 h in the absence of compound, a sharp, dose-dependent decline in viability was observed using trypan blue dye exclusion. Together with the initial, dose-dependent drop in the alkaline elution curve, these data suggest that the observed DNA double-strand breaks arose as a consequence of endonucleolytic DNA degradation associated with cytotoxicity, rather than by a direct compound-DNA interaction. Since DNA double-strand breaks behave under alkaline denaturing conditions as two single-strand breaks and can therefore produce increases in the alkaline-elution slope values, a necessary criteria for a valid positive result in this assay is that cytotoxicity by trypan blue dye exclusion will not be greater than 30%. Our data, however, indicate that interpretation of the elution assay as a test for genotoxicity can still be confounded by the failure of the trypan blue dye exclusion assay to reflect cytotoxicity in the unusual instance when there is no concurrent, immediate loss of membrane integrity.

Skin fibroblasts from aged fischer 344 rats undergo similar changes in replicative life span but not immortalization with caloric restriction of donors

We have compared the in vitro replicative life span and characteristics of immortalization of skin fibroblast cultures derived from ad libitum-fed and caloric-restricted Fischer 344 rats of 6, 24, and 29 months of age. Cells from all 6-, 24-, and 29-month-old animals showed a gradual decline in proliferative potential as evidenced by decreases in harvest density, in the fraction of cells initiating DNA synthesis, and in the number of population doublings per passage. These declines were accompanied by morphological changes including cell enlargement. The replicative life span prior to immortalization decreased significantly with donor age (P less than 0.0001), while caloric restriction had no effect on the cumulative population doubling level. Prior to immortalization mitotic cells from all cultures showed a normal rat karyotype. Postcrisis cultures tended to have more polyploid cells but there were no characteristic or specific chromosomal changes found in the cells with an immortalized phenotype. Interestingly, fibroblasts derived from caloric-restricted animals had a significantly slower growth rate through the tenth week after immortalization (P less than 0.005). When these cultures were seeded at one-quarter the normal seeding density, to favor the outgrowth of the fastest growing cells, a population with a more transformed phenotype emerged.

No change in DNA damage or repair of single- and double-strand breaks as human diploid fibroblasts age in vitro

Using the in vitro human diploid fibroblast model, we tested theories of aging which hypothesize that either accumulation of DNA damage or decreased DNA repair capacity is causally related to cellular senescence. Between population doubling level (PDL) 32 and 71, fetal lung-derived normal diploid human fibroblasts (IMR 90) were assayed for both DNA single-strand breaks (SSBs, spontaneous and induced by 6 Gy) and DNA double-strand breaks (DSBs, spontaneous and induced by 100 Gy). After gamma-irradiation cells were kept on ice unless undergoing repair incubation at 37 degrees C for 7.5-120 min or 18-24 h. To assay DNA strand breaks we used the filter elution technique in conjunction with a fluorometric determination of DNA which is not biased in favor of proliferating aging cells as are radioactive labelling methods. We found no change with in vitro age in the accumulation of spontaneous SSBs or DSBs, nor in the kinetics or completeness of DNA strand rejoining after gamma-irradiation. Cells at varying PDLs rejoined approx. 90% of SSBs and DSBs after 60 min repair incubation and 100% after 18-24 h repair incubation. We conclude that aging and senescence as measured by proliferative lifespan in IMR 90 cells are neither accompanied nor caused by accumulation of DNA strand breaks or by diminished capacity to rejoin gamma-radiation-induced SSBs or DSBs in DNA.