Niacin Deficiency Decreases Bone Marrow Poly(ADP-Ribose) and the Latency of Ethylnitrosourea-Induced Carcinogenesis in Rats

Cancer chemotherapy agents cause damage in the bone marrow, resulting in leukopenia during treatment and secondary cancers after recovery from the original disease. We created an experimental model of alkylation-based chemotherapy using ethylnitrosourea (ENU) to investigate the effect of niacin stat...

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Bibliographic Details
Published inThe Journal of nutrition Vol. 132; no. 1; pp. 108 - 114
Main Authors Boyonoski, Ann C., Spronck, Jennifer C., Gallacher, Lisa M., Kirkland, James B., Jacobs, Robert M., Shah, Girish M., Poirier, Guy G.
Format Journal Article
LanguageEnglish
Published Bethesda, MD Elsevier Inc 01.01.2002
American Society for Nutritional Sciences
American Institute of Nutrition
Subjects
Alkylating Agents - toxicity
Animals
Biological and medical sciences
bone marrow
Bone Marrow - metabolism
bone metabolism
carcinogenesis
Chemotherapy
diet
Disease Models, Animal
DNA damage
Ethylnitrosourea - toxicity
Leukemia
leukopenia
Male
Morbidity
neoplasms
Neoplasms, Experimental - chemically induced
Neoplasms, Experimental - metabolism
niacin
Niacin - administration & dosage
Niacin - deficiency
Niacin - metabolism
nitrosourea
Nutritional Status
pharmacokinetics
Poly Adenosine Diphosphate Ribose - metabolism
poly(ADP-ribose)
Rats
Rats, Long-Evans
risk
Rodents
Time Factors
Vitamin B
weanlings
weight loss
LT50
leukemia
CON
LT20
PARP
DEN
chemotherapy
ENU
BSA
ND
PF
niacin deficiency
nitrosourea
poly(ADP-ribose)
rats
ssDNA
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Summary:Cancer chemotherapy agents cause damage in the bone marrow, resulting in leukopenia during treatment and secondary cancers after recovery from the original disease. We created an experimental model of alkylation-based chemotherapy using ethylnitrosourea (ENU) to investigate the effect of niacin status on cancer induction. For 4 wk, nontumor-bearing weanling Long-Evans rats were fed niacin-deficient (ND) diets or were pair-fed (PF) identical quantities of a niacin-adequate diet. One week after the initiation of niacin feeding protocols, ENU treatment began (12 doses, 30 mg/kg by gavage, every other day). At the end of dietary modulation and ENU treatment, all rats were fed a high quality control diet and monitored for weight loss (>5%) and palpable tumors (>1cm), at which point they were necropsied for the presence of disease. The morbidity curves were significantly different; ND rats reached 20% morbidity 10 wk earlier than PF rats. In the first 20 wk after ENU treatment, ND rats developed 17 malignancies, including 11 leukemias, whereas PF rats developed 3 malignancies with 2 leukemias. In the end, there was a 47% greater average number of malignancies in ND vs. PF rats, despite a more rapid onset of morbidity. In short-term studies, niacin deficiency caused an 80% decrease in bone marrow NAD+. Basal poly(ADP-ribose) levels were dramatically reduced by niacin deficiency. A single dose of ENU increased poly(ADP-ribose) levels fivefold in PF rats, whereas levels in ND rats remained 90% lower. Niacin deficiency did not alter the initial accumulation of DNA damage, indicating that drug metabolism is not an underlying factor in the diet-induced changes. These data show that niacin deficiency alters poly(ADP-ribose) metabolism in the bone marrow and increases the risk of nitrosourea-induced leukemias.
ISSN:0022-3166
1541-6100
DOI:10.1093/jn/132.1.108