Protein, carbohydrate, and ethanol consumption: interactions in AA and ANA rats

Patterned Feeding of a Hyper-Palatable Food (Oreo Cookies) Reduces Alcohol Drinking in Rats

While a bidirectional positive link between palatable food intake and alcohol drinking has been suggested, several rodents studies report reduced alcohol drinking following palatable diets exposure. These studies utilized purified rodents’ diets high in sugar/fat; however, the effects of hyper-palatable food (HPF) rich in fat and sugar on alcohol drinking remain unclear. Furthermore, neural substrates involved in HPF-mediated changes in alcohol consumption are poorly understood. Therefore, the present study evaluated the effects of patterned feeding of a hyper-palatable food (Oreo cookies) on alcohol drinking as well as dopamine (DA) and serotonin (5-HT) content in rat’s mesocorticolimbic (medial-prefrontal cortex, orbitofrontal cortex, amygdala, and nucleus accumbens) circuitry. Male Long Evans rats received 8-weeks of intermittent (Mon, Tue, Wed) Oreo cookies access, which induced a patterned feeding, in which rats in the Oreo group overconsumed calories on HPF days whereas underconsumption was observed on chow only (Thu, Fri) days. Following HPF exposure, alcohol consumption was evaluated while patterned feeding continued. Alcohol intake in the Oreo group was significantly lower as compared to the chow controls. However, alcohol intake in the Oreo group increased to the levels seen in the group receiving chow following the suspension of patterned HPF feeding. Finally, DA levels in the nucleus accumbens were significantly greater, whereas its metabolite (DOPAC) levels were lower in the Oreo group compared to the chow controls. Surprisingly, 5-HT levels remained unaltered in all tested brain areas. Together, these data suggest that HPF-associated increased DA availability and reduced DA turnover within mesocorticolimbic circuitry may regulate alcohol drinking following patterned HPF feeding.

Effect of different standard rodent diets on ethanol intake and associated allodynia in male mice

Alcohol is the most ubiquitously consumed and misused mind-altering substance in the world. Various animal models exist to aid in our neurobiological understanding of alcohol addiction. One variable too often taken for granted and not consistently controlled is the "standard" chow diet rodents are maintained on. In this set of experiments, we sought to determine the effect of different commonly used diets on ethanol intake, ethanol preference, and mechanical pain sensitivity in a widely used mouse model of heavy alcohol drinking, the intermittent access to 20% alcohol model. We found that male mice kept on LabDiet 5001 (Diet 2 [LD5001]) and on Teklad Diet 7012 (Diet 3 [H7012]) consistently drank more ethanol than mice kept on Teklad Diet 2918 (Diet 1 [H2918]) as well as compared to mice on LabDiet 5V75 (Diet 4 [LD5V75]). In addition, water intake was consistently lower in mice kept on LabDiet 5001 (Diet 2 [LD5001]), and occasionally in mice kept on Teklad Diet 7012 (Diet 3 [H7012]), compared to the Teklad Diet 2918 (Diet 1 [H2918]) group. We found that male mice showed a strong mechanical allodynia following 8 weeks of intermittent ethanol drinking at 72 h of withdrawal, compared to water Control mice, regardless of the diet and hence of the different amount of ethanol consumed. Our data provide evidence that the type of rodent diet subjects are exposed to is an important variable to report and control, in all ethanol drinking studies.

Reduced alcohol drinking following patterned feeding: Role of palatability and acute contingent availability

Recent studies from our lab have demonstrated that intermittent high-fat diet access reduces alcohol drinking in rats. However, it was unclear if caloric overload, palatability, or diet itself triggered reduced alcohol drinking. It is also unknown if a similar paradigm could reduce relapse-like alcohol drinking. The presented study tested the hypothesis that acute intermittent palatable diet (PD) access would rescue relapse-like drinking and palatability, but not diet itself contributes to reduced drinking. Male Long Evans rats received six-weeks intermittent or chronic chow (controls) or PDs (high-fat diet, high-sugar diet) exposure, and alcohol testing occurred following PDs suspension. Alcohol intake was not significantly different among groups in either condition, suggesting that diet itself did not impact alcohol drinking. A subset of these rats received two-weeks intermittent PDs (Int-PDs) exposure and alcohol testing reinitiated while Int-PDs access continued. Alcohol intake significantly escalated (~137% compared to baseline; alcohol deprivation effect) in the chow controls, whereas it remained unchanged in PD groups. These data demonstrate the critical importance of acute intermittent PDs availability and its protective effect in relapse-like drinking. To assess the contribution of palatability in reduced alcohol drinking, a separate group of rats received two-weeks intermittent high-sugar diet (Int-HSD) or saccharin (Int-SAC) access and tested for alcohol drinking while Int-HSD/SAC continued. Alcohol drinking significantly decreased (~30%) in both HSD and SAC groups compared to the controls. These data identify the critical parameters by which acute intermittent PD access reduces alcohol drinking and could have important therapeutic implications in the management of alcoholism.

Experimental and observational studies on alcohol use and dietary intake: a systematic review

The scientific literature on links among alcohol use, total energy intake, cardiometabolic disease and obesity is conflicting. To clarify the link between alcohol use and cardiometabolic health, this systematic review (PROSPERO CRD42016039308A) uses PRISMA (Preferred Reporting Items for Systematic Reviews and Meta-Analyses) guidelines to synthesize how alcohol use affects dietary intake (carbohydrate, fat and protein intake) in humans. A search of Google Scholar, PsycINFO and PubMed from June 2016-March 2019 yielded 30 qualified studies. Experimental and observational studies allowed for inferences about effects of a single drinking occasion and of frequent drinking, respectively. Alcohol quantities were standardized according to the 2015-2020 Dietary Guidelines for Americans. On average, methodological quality of the studies was medium strength. Results indicated that a single occasion of light and moderate drinking as well as frequent light and moderate drinking were linked to greater fat and protein intake, albeit the majority of studies did not detect differences in dietary intake due to these drinking behaviours. Frequent heavy drinking, on the other hand, was linked to less carbohydrate intake in the majority of studies. Overall, alcohol use does not appear to uniformly affect diet but instead appears to affect intake of specific macronutrients in a dose-dependent manner, most consistently decreasing carbohydrate intake with heavier use.

Behavioral and Neurobiological Consequences of Hedonic Feeding on Alcohol Drinking

A complex interplay of peripheral and central signaling mechanisms within the body of an organism maintains energy homeostasis. In addition, energy/food intake is modified by various external factors (e.g., palatability, food availability, social and environmental triggers). Highly palatable foods can provoke maladaptive feeding behavior, which in turn disrupts normal homeostatic regulation resulting in numerous health consequences. Furthermore, neuroendocrine peptides, traditionally considered to regulate appetite and energy homeostasis, also control the intake and reinforcing properties of alcohol and drugs of abuse. Therefore, dysregulated eating as a result of a hedonic/binge-like intake of hyper-palatable food may impact alcohol drinking behavior. Relevant in this case is the fact that eating disorders are highly comorbid with several neuropsychiatric conditions, including alcohol use disorder. The present review is intended to summarize the neurobiological and functional consequences of hedonic feeding on alcohol intake.

A high-fat meal or injection of lipids stimulates ethanol intake

Findings of earlier studies support the idea of a possible relation between dietary fat and ethanol intake, but it is unclear whether acute exposure to fat can increase ethanol consumption directly. In the current series of experiments, we examined whether daily overeating of fat, a single high-fat meal, or the injection of fat can increase ethanol intake. In Experiment 1, adult Sprague-Dawley rats were maintained on a high-fat diet (50% fat) for 7 days and switched subsequently to a laboratory chow diet while being trained to drink 9% ethanol. Rats that had eaten the greatest amount of the high-fat diet subsequently drank the most ethanol. In Experiment 2, a 1-h meal of the high-fat diet (50% fat) produced a significant increase in 7% ethanol consumption in comparison with what occurred after consumption of an equicaloric, low-fat (10% fat) meal. In Experiment 3, the orosensory effect of fat was eliminated with an intraperitoneal injection of a fat emulsion, Intralipid (20% fat, 5.0 ml). The injection of Intralipid, in comparison with saline, increased the ingestion of 9% ethanol. This finding is in contrast to what occurred with injection of an equicaloric, 50% glucose solution, which suppressed ethanol intake. These findings provide new evidence to support a positive relation between dietary fat and the consumption of ethanol.

Different diets and amino acid supplementation do not affect the voluntary consumption of ethanol by rats

The effects of four different diets (control diet: 19.5% protein, 60.5% carbohydrate, 10% fat; diet I: 65% protein, 10% carbohydrate, 10% fat; diet II: 5% protein, 76% carbohydrate, 10% fat; diet III: 20% protein, 69% carbohydrate, 1% fat; diet IV: 69% protein, 15% carbohydrate, 1% fat) and supplementation with 3 amino acids (tryptophan: 150 mg/kg/d; arginine: 400 mg/kg/d; taurine: 380 mg/kg/d) on the voluntary consumption of ethanol were investigated in rats using the 2 bottle method. First, rats received the control diet and diets I, II, III and IV for 20 days with a choice of ethanol for the last 6 days only. Ethanol consumption was similar in all dietary groups. Second, rats received the control diet for 8 days followed by diets I, II and IV for another 8 days. Ethanol was offered throughout both periods. The switch to the special diets did not affect ethanol consumption. Third, rats received a control diet with arginine, tryptophan or taurine added to the drinking fluids for 16 days with a choice of ethanol for the last 5 days; thereafter supplementation stopped but the ethanol choice remained. No difference in the voluntary intake of ethanol was noted but ethanol consumption fell after cessation of arginine supplementation. In conclusion, diets differing greatly in their composition or supplementation with these 3 amino acids did not affect the voluntary choice of ethanol by rats in a significant manner.

Effects of lifelong ethanol consumption on drinking behavior and motor impairment of alcohol-preferring AA and alcohol-avoiding ANA rats

The effects of drinking ethanol throughout a lifetime on voluntary drinking behavior and ethanol-induced motor impairment were studied in alcohol-preferring AA (Alko, Alcohol) and alcohol-avoiding ANA (Alko, Non-Alcohol) rats of both sexes. At the age 3 months, the rats were tested for individual voluntary ethanol (10% vol./vol.) intake and ethanol-induced motor impairment (2 g/kg, i.p.). The rats were housed in group cages, half of them having 12% (vol./vol.) ethanol as the only source of fluid and the other half having free access to water. Food was always available for all animals. At the age of 23 months, their individual voluntary ethanol intake and ethanol-induced motor impairment were tested again. During forced drinking, the females of both strains consumed more ethanol than did the males. The ethanol consumption of the AA and ANA females and the ANA males increased significantly (P < .001) with age, but a slight decrease was seen in the ethanol consumption of the AA males. Time x strain interaction showed a significant (P < .05) difference in the ethanol consumption of male rats, with the AA males having a slight decrease in ethanol consumption with age, whereas the ANA males increased their ethanol consumption. After 19 months of forced ethanol exposure, AA males significantly decreased their individual voluntary ethanol consumption, and individual voluntary ethanol consumption by ethanol-exposed AA males was more pronounced (P < .001) than that of the AA rats that had free access to water (P < .05). For the female AA rats, those having free access to water significantly decreased their voluntary ethanol consumption (P < .05), but those having ethanol only did not. No significant changes in voluntary ethanol consumption with age or with different exposures were seen in the ANA rats. Body weights were higher in the groups having access to water than in the ethanol-only groups, but the differences were not significant within the AA and ANA strains. The ANA rats were significantly heavier in all groups. These results indicate that the voluntarily nondrinking ANA rats can drink almost as much ethanol as the voluntarily drinking AA rats when they are forced to drink ethanol and that lifelong forced ethanol drinking does not change their inherent drinking habits. When sensitivity to ethanol was measured with the tilting-plane test, the old AA female rats were more sensitive to ethanol than were the young ones. The young ANA females were more sensitive than the AA females when tested at 4 months. In males, aging did not produce any differences in ethanol sensitivity.

Neuropeptide-Y in the paraventricular nucleus increases ethanol self-administration

The paraventricular nucleus (PVN) of the hypothalamus is known to modulate feeding, obesity, and ethanol intake. Neuropeptide-Y (NPY), which is released endogenously by neurons projecting from the arcuate nucleus to the PVN, is one of the most potent stimulants of feeding behavior known. The role of NPY in the PVN on ethanol self-administration is unknown. To address this issue, rats were trained to self-administer ethanol via a sucrose fading procedure and injector guide cannulae aimed at the PVN were surgically implanted. Microinjections of NPY and NPY antagonists in the PVN were conducted prior to ethanol self-administration sessions. All doses of NPY significantly increased ethanol self-administration and preference, and decreased water intake. The NPY antagonist D-NPY partially reduced ethanol self-administration and completely blocked the effects of an intermediate dose of NPY (10 fmol) on ethanol intake, preference, and water intake. The competitive non-peptide Y1 receptor antagonist BIBP 3226 did not significantly alter ethanol self-administration or water intake when administered alone in the PVN but it completely blocked the effect of NPY (10 fmol) on ethanol intake. NPY infused in the PVN had no effect on ethanol self-administration when tested in rats that did not have a long history of ethanol self-administration. The doses of NPY tested produced no effect on food intake or body weight measured during the 24-h period after infusion in either ethanol-experienced or ethanol-inexperienced rats. These results indicate that elevation of NPY levels in the PVN potently increases ethanol self-administration and that this effect is mediated through NPY Y1 receptors.

Dietary energy shortage and ethanol intake in golden hamsters

Adult male golden hamsters, which are avid consumers of ethanol solutions, were maintained on powdered Purina chow and tap water, and they were permitted continuous access to either a 15% or a 30% ethanol solution (v/v). In two experiments, the effect of chronic dietary energy shortage on ethanol consumption was examined. Energy shortage was produced either by food restriction (Experiment 1) or by dilution of the diet with nonnutritive cellulose (Experiment 2). Dietary energy shortage caused increases of up to 50% in ethanol consumption, and the energy derived from ethanol offset the short-fall in food-derived energy by up to 50%. When normal feeding conditions were reinstated, hamsters maintained their enhanced intake of ethanol solutions, consuming up to 15.4 g/kg/day of ethanol. Possible factors underlying the enhanced intake of ethanol solution both during and after dietary energy shortage are discussed.

Ethanol reinforcement and its relationship to saccharin preference in Wistar rats

Forty rats were given a choice between 0.1% sodium saccharin and water. Based on their intakes, three groups of six rats representing high, intermediate, and low saccharin preferences were selected. These rats were reduced to 80% of their free-feeding weights. Ethanol was established as a reinforcer by use of a food-induced drinking procedure. Between-group differences were assessed based on response rates across acquisition sessions (0, 1, 2, 4, 5.7, 8%, w/v), a fixed-ratio series (1, 2, 4, 8, 1), and a concentration series (8, 5.7, 4, 2, 2, 4, 5.7, 8, 11.3, 16, 22.6, 32, 8%, w/v). In 29 of 32 conditions which were analyzed, the mean number of responses for ethanol was higher for the high saccharin preference group than for the low, and in 25 of 32 conditions, the intermediate group fell between the high and the low. However, there was considerable variability within groups across all conditions, such that mean between-group differences were not significant. This variability may be reduced by considering diet preferences in addition to saccharin preference. Nonetheless, these results offer limited support for the increasing body of evidence indicating a relationship between the factors mediating ethanol self-administration and those involving ingestion of palatable foods and fluids.

Can dietary macronutrient preference profile serve as a predictor of voluntary alcohol consumption?

A diet rich in protein has been shown to increase voluntary alcohol consumption (VAC) in a variety of animal species. Macronutrient preference (MP) profile varies widely among different outbred rats of the same strain. Using outbred Sprague-Dawley rats and two inbred selected strains of rats (P and NP) that are known for large differences in alcohol preference, we have examined whether 1) there is a relationship between MP profile and VAC and 2) MP profile can be a predictor of VAC. Results of these studies show 1) wide animal-to-animal variations in both the MP and VC and 2) the presence of an association between MP profile and VAC in P and NP but not Sprague-Dawley rats. Therefore, we conclude that MP profile may not serve as a reliable predictor of VAC in a nonselected population.

Fat-preferring rats consume more alcohol than carbohydrate-preferring rats

Rats with a genetic preference for alcohol (ETOH) have been found to consume more dietary fat then ETOH nonpreferring rats. We therefore hypothesized that rats selected on the basis of fat and carbohydrate (CHO) preferences would differ in ETOH intake. Patterns of macronutrient self-selection were determined by allowing rats to select diets from separate sources of CHO, fat and protein. Subsequently, CHO- and fat-preferring groups were formed. All rats were then returned to a lab chow diet and trained to drink ETOH (4-12%) during one hour of access per day. Food restriction was used only in the first three weeks of the procedure. On the final drinking sessions, water and ETOH were alternated on a daily basis. Fat-preferring rats consumed significantly more ETOH than water; CHO-preferring rats consumed approximately equal amounts of ETOH and water. Furthermore, fat-preferring rats consumed more ETOH than CHO-preferring rats. This study suggests that there may be a common mechanism underlying diet preference and oral intake of ETOH.

Drinking of high concentrations of ethanol versus palatable fluids in alcohol-preferring (P) rats: valid animal model of alcoholism

A genetically based animal model of alcoholism has been characterized in Wistar-derived rats in terms of their preference (P rats) or lack of preference (NP rats) for 10% ethanol over water. The present experiments were designed to determine: 1) whether a 10% solution of ethanol is the optimal concentration for differentiation of these lines; 2) what concentrations of ethanol are maximally preferred by P and NP rats; and 3) whether highly palatable fluids presented simultaneously with each rat's preferred solution of ethanol would alter the patterns of drinking by either the P or NP or both lines of rats. A three-bottle procedure was used to establish preference for ethanol in the presence of water as well as highly palatable solutions. The results showed that, when concentrations ranging from 3-30% were presented over a 12-day test interval, the mean absolute intake of ethanol of the P rats was 6.7 g/kg per day, with a maximum intake of 10.9 g/kg per day at the 25% concentration. These levels of intake were significantly higher than the 4.3 g/kg per day consumed during the presentation of the commonly used constant concentration of 10%. Similarly, the mean absolute intake of ethanol by the NP rats was also elevated significantly at concentrations of 15-30% (2.0 g/kg per day) above that consumed at the 10% concentration (0.4 g/kg).(ABSTRACT TRUNCATED AT 250 WORDS)

Dietary regulation of voluntary alcohol consumption in rats. Influence of a high protein diet and a methylene blue diet

The importance of glucose homeostasis for high voluntary alcohol consumption was studied in alcohol-preferring (AA) and alcohol-avoiding (ANA) rats fed either a control diet, a protein-rich diet or a control diet supplemented with methylene blue. AA rats on the control diet were found to receive 13.6% of their daily energy intake from alcohol. On the high-protein or methylene blue diet, the alcohol consumption of the AA rats was respectively 40% and 48% higher than on the control diet. The voluntary alcohol consumption of ANA rats corresponded to 0.8-2.3% of their daily energy intake irrespective of diet. The protein diet increased the blood glucose concentration of AA rats by 20% but no increase was observed after the methylene blue diet. The diets had no effect on the blood glucose levels of ANA rats. In AA rats, the protein diet reduced the hepatic concentration of the three major glucogenic amino acids (serine, glycine, alanine) on average by 24%, suggesting an increased utilization for gluconeogenesis. No such reduction was observed in AA rats on the methylene blue diet or in ANA rats on any diet. The utilization of amino acids for maintenance of glucose balance in AA rats is further supported by the observed negative correlation between plasma concentration of urea, the end product of amino acid catabolism, and the sum of the concentrations of the three glucogenic amino acids in the liver, and by the positive correlation between plasma urea and blood glucose concentration. Furthermore, in AA rats, but not in ANA rats, the concentration of alanine, the main amino acid used in gluconeogenesis, correlated negatively with the amount of alcohol consumed. These findings indicate that the maintenance of glucose homeostatis is important for high voluntary alcohol consumption.

The effect of clonidine and related substances on voluntary ethanol consumption in rats

Clonidine, guanfacine and tiamenidine, in equihypotensive doses, significantly reduced alcohol intake in ethanol-preferring rats having free choice between 10% ethanol and drinking water. Water intake was only slightly reduced, especially during the first hours following the administration of clonidine. Simultaneous treatment with yohimbine attenuated the clonidine-induced reduction in ethanol intake. Putative central mechanisms underlying the observed inhibitory actions of clonidine and other alpha-2 adrenoceptor agonists on oral self-administration of alcohol are discussed.

The AA and ANA rat lines, selected for differences in voluntary alcohol consumption

The offspring of rats that voluntarily select larger quantities of alcohol are heavier consumers of alcohol than the offspring of rats that tend to avoid it. Such selective breeding, repeated over many generations, was used to develop the AA (Alko, Alcohol) line of rats which prefer 10% alcohol to water, and the ANA (Alko, Non-Alcohol) line of rats which choose water to the virtual exclusion of alcohol. In addition to demonstrating the likely role of genetic factors in alcohol consumption, these lines have been used to find behavioral, metabolic, and neurochemical correlates of differential alcohol intake. Some of the line differences that have been found involve the reinforcing effects of ethanol, the changes in consumption produced by alcohol deprivation and nutritional factors, the behavioral and adrenal monoamine reactions to mild stress, the development of tolerance, the accumulation of acetaldehyde during ethanol metabolism, and the brain levels of serotonin. It is hoped that these studies will lead to a better understanding of the genetically-determined mechanisms that influence the selection of alcohol.