We previously demonstrated that alcohol-fed adolescent rats exhibit reductions in lumbar spine bone mineral density and vertebral body height, suggesting that chronic alcohol consumption has negative consequences for skeletal development during adolescence. Binge alcohol consumption is common in adolescents and young adults, yet little is known about its consequences on skeletal integrity or the attainment of peak bone mass. We used a previously validated binge alcohol exposure model to test the hypothesis that binge alcohol treatment of adolescent rats would be associated with distinct temporal and site-specific bone loss profiles, with incomplete recovery from bone loss following a period of alcohol abstinence. Seventy-two male adolescent Sprague-Dawley rats were assigned to one of 6 treatment groups (n = 12/group) receiving binge alcohol (3g/kg) or saline ip, 3 consecutive days (acute binge), 4 consecutive weekly (3-day) binge cycles (chronic binge), or 4 weekly binge cycles followed by a 30-day abstinence period without alcohol or saline injections (chronic binge with abstinence). Cancellous BMD was determined by pQCT and compressive strength determined by biomechanical testing. Serum testosterone and osteocalcin levels were measured by ELISA. Tibial cancellous BMD was significantly reduced by 25% (p < 0.05) after both acute and chronic binge alcohol treatment and vertebral cancellous BMD was significantly reduced by 15% (p<0.05) after chronic binge exposure. Vertebral compressive strength was also significantly decreased by 31% (p<0.05) after chronic binge alcohol treatment. Tibial cancellous BMD returned to control levels after the 30-day alcohol abstinence period, but vertebral cancellous BMD remained 15% below control values (p <0.05) 30 days after termination of binge alcohol exposures. Serum osteocalcin levels were significantly decreased following acute binge alcohol exposure (p<0.05). These results show that binge alcohol exposure can produce both short and long-term skeletal damage in the adolescent rat. This data may have relevance to peak bone mass attainment and future risk of skeletal disease in adolescents and young adults who engage in repeated binge drinking episodes.
Binge alcohol-related bone damage is prevented by concurrent administration of bisphosphonates, suggesting an activation of bone resorption with patterned alcohol exposure. Although chronic alcohol abuse is known to cause osteopenia, little is known about the effects of binge drinking on bone metabolism. We examined the effects of binge alcohol exposure on the relationship between bone damage and modulation of bone remodeling-specific gene expression profiles. Our hypothesis was that bone damage observed in young adult rats after binge alcohol exposure is associated with differential expression of bone remodeling-related gene expression. We further hypothesized that this differential gene expression specific to bone remodeling (bone resorption or formation related) would be influenced by the duration of binge alcohol exposure. Binge alcohol (3 g/kg, i.p.) was administered on 3 consecutive days each week, for 1 or 4 weeks, to adult male rats. Matched control animals were injected with an equal volume of isotonic saline. Lumbar vertebrae, L4-5, were analyzed for the presence of bone damage by quantitative computed tomography and compressive strength analysis. Total RNA was isolated from an adjacent vertebrae (L3), and whole transcriptome gene expression data were obtained for each sample. The expression levels of a subset of bone formation and resorption-associated differentially expressed genes were validated by quantitative reverse transcriptase-polymerase chain reaction. Bone loss was not observed after 1 week of treatment but was observed after four binge alcohol cycles with a 23% decrease in cancellous bone mineral density and 17% decrease in vertebral compressive strength compared with control values (P < 0.05). We observed that the duration of binge alcohol treatment influenced the modulation of expression profiles for genes that regulate the bone formation process. The expression of key bone formation-related marker genes such as osteocalcin and alkaline phosphatase were significantly reduced (P < 0.05) after acute binge alcohol exposure, and expression of regulators of osteoblast activity such as bone morphogenetic proteins and parathyroid hormone receptor displayed significantly (P < 0.05) decreased differential expression. The expression of sclerostin, a key canonical Wnt inhibitory protein, was significantly increased after acute binge alcohol treatment. The expression of important regulators of osteoclast maturation and activity such as NF-κβ (nuclear factor κβ) ligand (RANKL) and interleukin-6 were significantly increased (P < 0.05) by binge alcohol, and osteoprotegerin levels were significantly decreased (P < 0.05) in vertebral bone. These results show that expression patterns of several key bone remodeling genes are significantly perturbed by binge alcohol treatment, suggesting that perturbation of gene expression associated with bone remodeling may be one mechanism contributing to the disruption of bone mass homeostasis and subsequent bone loss observed after binge alcohol exposure in rode...
Background Our laboratory established that binge alcohol-related bone damage is prevented by aminobisphosphonates, suggesting bone resorption increases following binge exposure. We examined the effects of binge alcohol and antiresorptive therapy on the relationship between bone damage and modulation of the vertebral transcriptome, in an attempt to determine how alcohol-induced bone damage and its prevention modulate bone-related biological pathways. Methods Male Sprague–Dawley rats were assigned to 1 of 6 treatment groups (n = 12/group). (C1) saline ip 3 d/wk for 1 week, (A1) binge alcohol, 3 g/kg, ip 3 d/wk for 1 week, (C4) saline ip, 3 d/wk for 4 weeks, (A4) binge alcohol, ip, 3 g/kg 3 d/wk for 4 weeks, (I4) ibandronate, saline ip 3 d/wk for 4 weeks, plus a single ip injection of ibandronate at 120 μg/animal, and (AI4) binge alcohol plus ibandronate as above. After 1 or 4 weeks, adjacent lumbar vertebrae were assayed for bone damage or transcriptional changes. Results Bone loss was not observed after 1 week of binge alcohol treatment. After 4 weeks, binge alcohol decreased vertebral BMD by 23% (p < 0.05) and compressive strength by 18% compared to saline controls (p < 0.05). Concurrent ibandronate prevented bone loss, increasing these parameters by 145 and 134% respectively compared to binge alcohol. (p < 0.05). Analysis of the vertebral transcriptome identified gene clusters specific for acute and chronic binge alcohol-related bone damage. Acute binge alcohol modulated the expression of integrin signaling-specific genes, while chronic binge alcohol modulated canonical Wnt signaling gene expression. Ibandronate normalized the expression of approximately 20% of the genes affected by chronic binge alcohol, allowing the identification of a unique subset of alcohol-sensitive, ibandronateresponsive genes. Conclusions Identification of bone-specific gene expression clusters associated with acute and chronic binge alcohol treatment allowed for the identification of cellular pathways affected by binge treatment with known involvement in bone remodeling (Integrin, Canonical Wnt signaling) not previously identified as alcohol-sensitive. This data provides a basis for a plausible mechanistic explanation for the known detrimental effects of alcohol on bone formation and resorption.
Decreased bone mass and bone strength can result from excess alcohol consumption in humans and alcohol treatment in the rat. Although the specific mechanism is unknown, the damaging effects of alcohol abuse modulate the bone remodeling cycle and increase bone turnover. Chronic alcohol consumption models have shown an inhibition of bone formation. We previously reported that binge alcohol treatment increases bone resorption and that alcohol-induced damage can be prevented by treatments with intermittent parathyroid hormone and bisphosphonates. In this study we hypothesized that an effective dose of vitamin D (cholecalciferol) or a single dose of ibandronate would prevent bone loss caused by binge alcohol treatment in male rats. Forty-eight adult (450 gram) male Sprague-Dawley rats were randomly assigned to 6 treatment groups (n=8): a) saline, i.p.3 days/ week (C); b) binge alcohol, 3g/kg i.p., 3 days/week (A); c) vitamin D, 5,000 IU/kg daily s.c., (D); d) binge alcohol and vitamin D (AD); e) e) ibandronate, (120 ug, given as a single i.p. injection (I); f) alcohol and ibandronate (AI). After 4 weeks of treatment proximal tibia and L3 and L4 vertebrae were analyzed for bone mineral density (BMD) by quantitative computerized tomography and compressive strength-to-failure using an Instron materials testing machine. Type-I collagen crosslinked c-telopeptide, calcium, and 25-OH vitamin D levels were measured in serum collected at the time of sacrifice. Binge alcohol significantly decreased cancellous BMD by 58% in tibia and 23% in lumbar spine (p < 0.05). Binge alcohol treatment decreased L3 and L4 compressive strength-tofailure by 21% (p <.05). Treatment with vitamin D at 5,000 IU/kg/day prevented alcohol-induced bone loss, significantly increasing both tibial and vertebral cancellous BMD values (161% increase in tibia and 40% increase in vertebra, respectively, p < 0.05) compared to alcohol alone groups. Pretreatment with the single dose of 120 ug ibandronate prevented alcohol-induced bone loss, increasing cancellous BMD by 186% in tibiae and by 46% in vertebrae compared to the alcohol alone group (p < 0.05). In summary, binge alcohol-induced tibial and vertebral bone loss can be prevented using an effective dose of vitamin D or a single dose of ibandronate even during high blood alcohol concentrations that have been shown to impair osteoblast functions and increase bone resorption.
These results demonstrate that binge alcohol exposure can produce disruptions of normal bone gene expression patterns in the adolescent rat that persist well beyond the period of active intoxication. This data may have relevance to peak bone mass attainment and future risk of skeletal disease in adolescents engaging in repeated binge-drinking episodes.
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