Ethanol exhibits specificity in its effects on differentiation of hematopoietic progenitors

Reduction of Cell Proliferation by Acute C2H6O Exposure

Endogenous acetaldehyde production from the metabolism of ingested alcohol exposes hematopoietic progenitor cells to increased genotoxic risk. To develop possible therapeutic strategies to prevent or reverse alcohol abuse effects, it would be critical to determine the temporal progression of acute ethanol toxicity on progenitor cell numbers and proliferative status. We followed the variation of the cell proliferation rate in bone marrow and spleen in response to acute ethanol intoxication in the MITO-Luc mouse, in which NF-Y-dependent cell proliferation can be assessed in vivo by non-invasive bioluminescent imaging. One week after ethanol administration, bioluminescent signals in bone marrow and spleen decreased below the level corresponding to physiological proliferation, and they progressively resumed to pre-treatment values in approximately 4 weeks. Boosting acetaldehyde catabolism by administration of an aldehyde dehydrogenase activity activator or administration of polyphenols with antioxidant activity partially restored bone marrow cells' physiological proliferation. These results indicate that in this mouse model, bioluminescent alteration reflects the reduction of the physiological proliferation rate of bone marrow progenitor cells due to the toxic effect of aldehydes generated by alcohol oxidation. In summary, this study presents a novel view of the impact of acute alcohol intake on bone marrow cell proliferation in vivo.

Oxidative stress mediates ethanol-induced skeletal muscle mitochondrial dysfunction and dysregulated protein synthesis and autophagy

Protein synthesis and autophagy are regulated by cellular ATP content. We tested the hypothesis that mitochondrial dysfunction, including generation of reactive oxygen species (ROS), contributes to impaired protein synthesis and increased proteolysis resulting in tissue atrophy in a comprehensive array of models. In myotubes treated with ethanol, using unbiased approaches, we identified defects in mitochondrial electron transport chain components, endogenous antioxidants, and enzymes regulating the tricarboxylic acid (TCA) cycle. Using high sensitivity respirometry, we observed impaired cellular respiration, decreased function of complexes I, II, and IV, and a reduction in oxidative phosphorylation in ethanol-treated myotubes and muscle from ethanol-fed mice. These perturbations resulted in lower skeletal muscle ATP content and redox ratio (NAD+/NADH). Ethanol also caused a leak of electrons, primarily from complex III, with generation of mitochondrial ROS and reverse electron transport. Oxidant stress with lipid peroxidation (thiobarbituric acid reactive substances) and protein oxidation (carbonylated proteins) were increased in myotubes and skeletal muscle from mice and humans with alcoholic liver disease. Ethanol also impaired succinate oxidation in the TCA cycle with decreased metabolic intermediates. MitoTEMPO, a mitochondrial specific antioxidant, reversed ethanol-induced mitochondrial perturbations (including reduced oxygen consumption, generation of ROS and oxidative stress), increased TCA cycle intermediates, and reversed impaired protein synthesis and the sarcopenic phenotype. We show that ethanol causes skeletal muscle mitochondrial dysfunction, decreased protein synthesis, and increased autophagy, and that these perturbations are reversed by targeting mitochondrial ROS.

Impact of Alcohol Abuse on the Adaptive Immune System

Alcohol exposure, and particularly chronic heavy drinking, affects all components of the adaptive immune system. Studies both in humans and in animal models determined that chronic alcohol abuse reduces the number of peripheral T cells, disrupts the balance between different T-cell types, influences T-cell activation, impairs T-cell functioning, and promotes T-cell apoptosis. Chronic alcohol exposure also seems to cause loss of peripheral B cells, while simultaneously inducing increased production of immunoglobulins. In particular, the levels of antibodies against liver-specific autoantigens are increased in patients with alcoholic liver disease and may promote alcohol-related liver damage. Finally, chronic alcohol exposure in utero interferes with normal T-cell and B-cell development, which may increase the risk of infections during both childhood and adulthood. Alcohol's impact on T cells and B cells increases the risk of infections (e.g., pneumonia, HIV infection, hepatitis C virus infection, and tuberculosis), impairs responses to vaccinations against such infections, exacerbates cancer risk, and interferes with delayed-type hypersensitivity. In contrast to these deleterious effects of heavy alcohol exposure, moderate alcohol consumption may have beneficial effects on the adaptive immune system, including improved responses to vaccination and infection. The molecular mechanisms underlying ethanol's impact on the adaptive immune system remain poorly understood.

Dysregulation of myelopoiesis by chronic alcohol administration during early SIV infection of rhesus macaques

BACKGROUND

Chronic alcohol intoxication suppresses immune function and increases osteoporosis risk suggesting bone-tissue cytotoxicity. Human immunodeficiency virus infection leads to similar impairments. This study investigated the effects of chronic alcohol administration during the early stage of simian immunodeficiency virus (SIV) infection on hematopoietic stem and progenitor cells (HSPCs) and their differentiated progeny in the bone marrow and peripheral blood of rhesus macaques.

METHODS

Rhesus macaques were administered alcohol or sucrose daily for a period of 3 months prior to intrarectal inoculation with 250 TCID50 of SIVmac251 . Bone marrow aspirates and blood samples were taken prior to and 2 weeks after SIV infection. Bone marrow cells (BMCs) were assessed using flow cytometric phenotyping for upstream HSPCs and for differentiated cells of the monocyte-granulocyte lineages. Likewise, cells were quantitated in peripheral blood.

RESULTS

Of the bone marrow HSPCs, only the common lymphoid progenitor (CLP) was altered by alcohol administration pre-SIV (38 ± 9.4/10(6) BMCs vs. 226 ± 64.1/10(6) BMCs, sucrose vs. alcohol). Post-SIV, the frequency of CLPs in the bone marrow of alcohol-administered macaques decreased compared with the sucrose-administered macaques (107 ± 47.6/10(6) BMCs vs. 43 ± 16.3/10(6) BMCs). However, marrow mature cells of the monocyte lineage, specifically macrophages and osteoclast progenitors, were increased by both chronic alcohol administration and SIV infection (287% and 662%, respectively). As expected, mature cells such as granulocytes (polymorphonuclear cells), B cells, and CD4+ T cells in the peripheral blood were decreased by SIV infection (37 to 62% decline from preinfection), but not affected after 3 months of chronic alcohol administration.

CONCLUSIONS

Chronic alcohol administration disrupts myelomonocytic development in the bone marrow during the early period of SIV infection promoting macrophage and osteoclast lineages. We predict this shift in CLP:macrophage/osteoclast balance creates an environment that favors bone resorption and immunosuppression.

Determination of genotype combinations that can predict the outcome of the treatment of alcohol dependence using the 5-HT(3) antagonist ondansetron

OBJECTIVE

The authors previously reported that the 5'-HTTLPR-LL and rs1042173-TT (SLC6A4-LL/TT) genotypes in the serotonin transporter gene predicted a significant reduction in the severity of alcohol consumption among alcoholics receiving the 5-HT3 antagonist ondansetron. In this study, they explored additional markers of ondansetron treatment response in alcoholics by examining polymorphisms in the HTR3A and HTR3B genes, which regulate directly the function and binding of 5-HT3 receptors to ondansetron.

METHOD

The authors genotyped one rare and 18 common single-nucleotide polymorphisms in HTR3A and HTR3B in the same sample that they genotyped for SLC6A4-LL/TT in the previous randomized, double-blind, 11-week clinical trial. Participants were 283 European Americans who received oral ondansetron (4 mg/kg of body weight twice daily) or placebo along with weekly cognitive-behavioral therapy. Associations of individual and combined genotypes with treatment response on drinking outcomes were analyzed.

RESULTS

Individuals carrying one or more of genotypes rs1150226-AG and rs1176713-GG in HTR3A and rs17614942-AC in HTR3B showed a significant overall mean difference between ondansetron and placebo in drinks per drinking day (22.50; effect size=0.867), percentage of heavy drinking days (220.58%; effect size=0.780), and percentage of days abstinent (18.18%; effect size=0.683). Combining these HTR3A/HTR3B and SLC6A4-LL/TT genotypes increased the target cohort from approaching 20% (identified in the previous study) to 34%.

CONCLUSIONS

The authors present initial evidence suggesting that a combined fivemarker genotype panel can be used to predict the outcome of treatment of alcohol dependence with ondansetron. Additional, larger pharmacogenetic studies would help to validate these results.

Alcohol affects the late differentiation of progenitor B cells

AIMS

Previous studies show that alcohol exposure can affect the differentiation of progenitor B cells. Before final commitment to a B lineage, progenitor B cells usually undergo several important stages. However, it is still unclear whether alcohol alters B cell differentiation at which stages. The aim of this study was to determine which stage(s) of progenitor cell differentiation are affected by alcohol and to elucidate the mechanism(s) responsible for the effect of alcohol on B cell differentiation.

METHODS

Oligoclonal-neonatal-progenitor (ONP) cells from bone marrow cells of 2-week-old mice were cultured under different conditions in vitro with or without the exposure of 100 mM alcohol. Phenotype analysis was performed at different time points and expression levels of transcription factors (TFs) and cytokine receptors were measured quantitatively and kinetically.

RESULTS

After 3 days in vitro culture, ONP cells differentiated into two populations: B220(-)CD11b(-) and B220(-)CD11b(+) cells. B220(-)CD11b(-) cells can further differentiate into B lineage cells only with the support of B220(-)CD11b(+) cells. Cells exposed to 100 mM of alcohol during the first 3 days of culture showed no statistically significant difference in B cell formation after 12 days compared with the control group. However, cells exposed to alcohol from Day 4 till the end of culture yield very few B cells. Expression levels of TFs and cytokine receptors were down-regulated kinetically among ONP cells co-cultured with the addition of 100 mM alcohol.

CONCLUSIONS

Alcohol affects the ONP cell differentiation into B lineage at a late stage. Alcohol also down-regulates the expression level of TFs and cytokine receptors resulting in the impairment of B cell differentiation.

Heparin binding epidermal growth factor-like growth factor reduces ethanol-induced apoptosis and differentiation in human embryonic stem cells

Alcohol affects approximately 1% (40,000) of new born infants each year and is the main preventable cause of mental retardation in the US. Ethanol alters cell signaling and promotes apoptosis and differentiation. Heparin-binding epidermal growth factor-like growth factor (HB-EGF), a member of the EGF family of growth factors, has been reported to prevent apoptosis and differentiation. We treated human embryonic stem cells (hESCs) with ethanol (20 mM) to reflect casual drinking, with and without HB-EGF to measure its ability to prevent ethanol-induced apoptosis and differentiation. Apoptosis was measured by DNA fragmentation (terminal dUTP nick-end labeling assays) and activated caspase-3, while differentiation was accessed by SSEA-1 and OCT-3/4; western blotting assessed MAPK signaling. HB-EGF reduced SSEA-1 and elevated OCT-3/4, while reducing the amount of activated caspase-3 and DNA fragmentation. Western blot analysis showed HB-EGF prevents ethanol from altering MAPK phosphorylation. This data suggests that ethanol-induced apoptosis was reduced by HB-EGF, while hESC pluripotency was maintained.