Alcoholism causes increased susceptibility to lung infections and pulmonary disease (Krumpe et al., 1984; Moss and Burnham, 2003). Studies have suggested that an increased risk of pneumonia is associated with high alcohol consumption (Nelson et al., 1991; Reynolds, 1995). However, the role that cigarette smoking plays in alcohol-related lung disease remains understudied. Current population studies report that 23.3% of adults in the United States smoke cigarettes (Cigarette Smoking Among Adults, 2002). Approximately 30% of these smokers are alcoholics (Miller and Gold, 1998). Indeed, reports linking cigarette smoking and alcohol abuse have suggested that as many as 95% of alcoholics are smokers (Patten et al., 1996). Therefore, research into the effects of alcohol on lung function must include a consideration of cigarette smoke as a confounding factor. Normal lung defense against bacterial inhalation is based on the maintenance of the mucociliary apparatus to provide a first-line barrier of protection. This mucociliary apparatus consists of mucus production and secretion, in concert with orchestrated cilia beating, resulting in lung clearance of aspirated microorganisms and inhaled particles. Mucociliary clearance is highly regulated by pH, temperature, mucus content, viscosity, particle stimulation, and chemical modulators such as β-agonists (Foster et al., 1976). This dynamic organelle regulation results in slow ciliary beating during a resting state and increased ciliary beating to enhance airway clearance at times of stimulation or stress. The increased burden of mucociliary defense during lung infections such as bacterial bronchitis and aspiration pneumonia is a common complication of heavy alcohol ingestion. We have previously reported the in vitro effects of ethanol on airway ciliary motility (Sisson, 1995). We observed that ethanol acutely elevates ciliary motility in an in vitro cell culture model. In this model, ethanol requires an adenosine 3’:5’-cyclic monophosphate (cAMP) and nitric oxide-dependent signaling pathway (Sisson et al., 1999; Wyatt et al., 2003). This follows the observation that either cAMP or cyclic guanosine monophosphate (cGMP) elevations result in increased cilia beating (Wyatt et al., 1998). However, continued exposure to ethanol eventually results in a return to baseline, unstimulated levels of cilia beating as potentially mediated via the action of a cAMP-phosphodiesterase (Forget et al., 2003). Once ciliated cells have been chronically exposed to ethanol in this manner, repeat challenges with ethanol fail to stimulate ciliary motility increase. Furthermore, such chronic ethanol exposure desensitizes the cells even to β-agonist stimulated increases in cilia motility (Wyatt and Sisson, 2001). Although well characterized in an in vitro tissue culture cell line, the desensitization of ciliary beating in response to chronic ethanol has not yet been demonstrated in vivo. We hypothesized that animals fed a diet containing a significant amount of ethanol would no longer respond to β-agonist challenge with increased ciliary beating compared with the same animals fed a control diet. Furthermore, we hypothesized that cigarette smoke exposure in the same alcohol-fed animals would augment this ethanol-dependent desensitization of ciliary beat. Such findings would suggest that the increased presence of bacterial colonization in the lungs of alcoholics could be in part related to the mechanism of chronic ethanol-induced ciliary desensitization.