Niacin supplementation decreases the incidence of alkylation-induced nonlymphocytic leukemia in Long-Evans rats.

Niacin deficiency impairs poly(ADP-ribose) formation and enhances ethylnitrosourea (ENU)-induced carcinogenesis. Previous experiments were compromised by rapid progression of cancer, and the current study was designed with half the number of ENU doses. Weanling male Long-Evans rats were fed niacin deficient (ND), pair-fed (PF) control (30 mg nicotinic acid/kg), or pharmacological niacin (NA; 4 g nicotinic acid/kg) diets. After 2 wk, rats were gavaged every other day with ENU [30 mg/kg body weight (bw)] or vehicle (6 doses). Four days after the last dose of ENU, all rats were switched to AIN-93M diet and mildly feed restricted to maintain a constant food intake per bw. Rats were monitored for termination criteria and assessed for cancer development. Total cancers developed more rapidly in rats on the ND diet compared to those receiving high dose supplements of NA (P = 0.02; Gehan's generalized Wilcoxon test). Importantly, all of these differences occurred in the leukemias, especially the nonlymphocytic leukemia fraction (P = 0.008; Gehan's generalized Wilcoxon test), with incidences of 36%, 17%, and 11% in ND, PF, and NA rats, respectively. Because nonlymphocytic leukemias represent the majority of secondary cancers, these data support the concept that niacin supplementation may help protect cancer patients from the deleterious side effects of chemotherapy.

Niacin deficiency delays DNA excision repair and increases spontaneous and nitrosourea-induced chromosomal instability in rat bone marrow.

We have shown that niacin deficiency impairs poly(ADP-ribose) formation and enhances sister chromatid exchanges and micronuclei formation in rat bone marrow. We designed the current study to investigate the effects of niacin deficiency on the kinetics of DNA repair following ethylation, and the accumulation of double strand breaks, micronuclei (MN) and chromosomal aberrations (CA). Weanling male Long-Evans rats were fed niacin deficient (ND), or pair fed (PF) control diets for 3 weeks. We examined repair kinetics by comet assay in the 36h following a single dose of ethylnitrosourea (ENU) (30mg/kg bw). There was no effect of ND on mean tail moment (MTM) before ENU treatment, or on the development of strand breaks between 0 and 8h after ENU. Repair kinetics between 12 and 30h were significantly delayed by ND, with a doubling of area under the MTM curve during this period. O(6)-ethylation of guanine peaked by 1.5h, was largely repaired by 15h, and was also delayed in bone marrow cells from ND rats. ND significantly enhanced double strand break accumulation at 24h after ENU. ND alone increased chromosome and chromatid breaks (four- and two-fold). ND alone caused a large increase in MN, and this was amplified by ENU treatment. While repair kinetics suggest that ND may be acting by creating catalytically inactive PARP molecules with a dominant-negative effect on repair processes, the effect of ND alone on O(6)-ethylation, MN and CA, in the absence of altered comet results, suggests additional mechanisms are also leading to chromosomal instability. These data support the idea that the bone marrow cells of niacin deficient cancer patients may be more sensitive to the side effects of genotoxic chemotherapy, resulting in acute bone marrow suppression and chronic development of secondary leukemias.

Chronic DNA damage and niacin deficiency enhance cell injury and cause unusual interactions in NAD and poly(ADP-ribose) metabolism in rat bone marrow.

Previous work has shown that niacin deficiency in rats increases the severity of ethylnitrosourea (ENU)-induced anemia and leukopenia and the long-term development of cancer. The current study was initially designed to characterize changes in bone marrow cell populations during ENU treatment in this model. Weanling Long-Evans rats were fed diets containing 0 or 30 mg/kg of added niacin for a period of 2-3 wk. ENU treatment started after 1 wk of feeding and consisted of either 4 or 8 doses of ENU delivered by gavage, every other day. Niacin deficiency (ND) alone caused a significant depression in nucleated red blood cells (30%), and a sporadic effect on granulocytes (+23% after 4 doses of vehicle, -29% after 8 doses of vehicle). ENU treatment, after only 4 doses, caused a large decline in the numbers of bone marrow cells, and this effect was enhanced by ND (ENU decreased lymphocytes by 66% in pair-fed (PF) and 86% in ND, granulocytes by 41% in PF and 64% in ND, and nucleated red blood cells by 63% in PF and 71% in ND). Cell cycle distribution suggested that bone marrow cells in niacin-adequate rats, but not ND rats, mounted a compensatory proliferative response during chronic ENU exposure. ND alone caused an 80% decrease in bone marrow NAD+ levels at all time points. Surprisingly, chronic exposure to ENU (which should cause DNA damage and NAD+ utilization) led to a 2.8-fold increase in NAD+ content in ND marrow cells. This finding led to a second study in which ND and niacin-adequate PF control rats received 7 doses of ENU or vehicle (CON), after which all rats received 1 dose of ENU. In this study, modestly enhanced bone marrow NAD+ in chronically treated PF rats was used to synthesize 2-fold greater amounts of poly(ADP-ribose) than seen after one acute dose of ENU, while this did not occur in chronically treated ND rats, in spite of a 2.8-fold increase in bone marrow NAD+. This study has shown that bone marrow cell populations are sensitized to ENU treatment by ND, that NAD+ pools are regulated in response to DNA damage, and that NAD+ localization and/or utilization in the nucleus is altered during ND and chronic DNA damage.