Project description:In vitro fermentation characteristics of dietary fibers using fecal inocula from dogs treated with metronidazole

Project description:Aging alters gastrointestinal morphology, microbiota, and functionality, and is associated with increased incidence of intestinal disease. The mechanisms that contribute to these changes are poorly described. Gene expression in dogs has been evaluated for a few select genes under pathogenic or varying dietary conditions, but global gene expression profiles of aged versus young adult dogs have not been compared previously. Thus, we used canine microarrays to compare gene expression profiles of colonic epithelial tissue from geriatric and young adult dogs fed 2 different diets. Colon tissue samples were collected from 6 geriatric (12 yr-old) and 6 young adult (1 yr-old) female beagles after being fed one of two diets (animal protein-based versus plant-protein based) for 12 months. RNA samples were hybridized to Affymetrix GeneChip Canine Genome Arrays. Statistical analyses indicated that age had the greatest impact on gene expression, with 212 genes differentially expressed in geriatric dogs. Although not as robust as age, diet affected mRNA abundance of 66 genes. The effect of age was most notable, with increased expression in genes related to inflammation, stress response, cellular metabolism and cell proliferation and decreased expression in genes associated with apoptosis and defense mechanism in senior dogs. The effect of diet on gene expression was not consistent, but appeared to have a greater response in senior dogs. Six geriatric (11.1 yr old) and 6 weanling (8 wk old) female beagles were used. Three dogs of each age were assigned to one of two dietary treatments and fed for 12 months. Diets tested in this experiment were previously shown to manipulate energy metabolism. One diet was an animal-protein based diet (APB) and was composed primarily of highly digestible ingredients and animal-derived protein and fat sources (brewer’s rice, poultry by-product meal, poultry fat) and was formulated to contain 28% protein, 23% fat, and 5% dietary fiber. The other diet was a plant-protein based diet (PPB) and was composed primarily of moderately digestible plant-derived ingredients (corn, soybean meal, wheat middlings, and meat and bone meal) and was formulated to contain 26% protein, 11% fat, and 15% dietary fiber. Although the two diets were very different in terms of ingredient and chemical composition, both were formulated to meet or exceed all nutrient requirements for canine growth according to the Association of American Feed Control Officials. Young dogs were fed ad libitum to allow for adequate growth, while geriatric dogs were fed to maintain baseline BW throughout the experiment. To produce the desired metabolic effects, the PPB diet was formulated to contain a lower caloric density (APB = 5.38 kcal/g; PPB = 4.75 kcal/g) and have a lower nutrient digestibility than the APB diet. Thus, dogs fed the PPB diet needed to consume a greater (P<0.05) quantity of food (237 g/d; 1123 kcal/d) than dogs fed the APB diet (166 g/d; 893 kcal/d) to grow (young) or maintain BW (geriatrics). Even though metabolic indices were altered, mean BW among dietary treatments was not different at any time over the course of the study for young or geriatric dogs. After 12 months on experiment, animals were fasted for 12 hr and then given a lethal dose (130 mg/kg BW) of sodium pentobarbital (Euthasol, Virbac Corp., Fort Worth, TX) intravenously into the left forearm. Death was confirmed by lack of respiration and a corneal reflex, and absence of a heartbeat detected with a stethoscope placed under the left elbow. Colon samples were collected immediately after death was confirmed, flash frozen using liquid nitrogen, and stored at -80oC. Frozen samples were placed in RNAlater-ICE until epithelial layer could be scraped off and used for microarray analysis.

Project description:Mechanisms contributing to age-related cognitive decline are poorly defined. Thus, we used canine microarrays to compare gene expression profiles of brain tissue from geriatric and young adult dogs. Cerebral cortex samples were collected from 6 geriatric (12 yr-old) and 6 young adult (1 yr-old) female beagles after being fed one of two diets (animal protein-based versus plant-protein based) for 12 months. RNA samples were hybridized to Affymetrix GeneChip Canine Genome Arrays. Statistical analyses indicated that the age had the greatest impact on gene expression, with 963 transcripts differentially expressed in geriatric dogs. Although not as robust as age, diet affected mRNA abundance of 140 transcripts. As demonstrated in aged rodents and humans, geriatric dogs had increased expression of genes associated with inflammation, stress response, and calcium homeostasis and decreased expression of genes associated with neuropeptide signaling and synaptic transmission. In addition to its existing strengths, availability of gene sequence information and commercial microarrays make the canine a powerful model for studying the effects of aging on cognitive function. Keywords: age; diet Six geriatric (11.1 yr old) and 6 weanling (8 wk old) female beagles were used. Three dogs of each age were assigned to one of two dietary treatments and fed for 12 months. Diets tested in this experiment were previously shown to manipulate energy metabolism. One diet was an animal-protein based diet (APB) and was composed primarily of highly digestible ingredients and animal-derived protein and fat sources (brewer’s rice, poultry by-product meal, poultry fat) and was formulated to contain 28% protein, 23% fat, and 5% dietary fiber. The other diet was a plant-protein based diet (PPB) and was composed primarily of moderately digestible plant-derived ingredients (corn, soybean meal, wheat middlings, and meat and bone meal) and was formulated to contain 26% protein, 11% fat, and 15% dietary fiber. Although the two diets were very different in terms of ingredient and chemical composition, both were formulated to meet or exceed all nutrient requirements for canine growth according to the Association of American Feed Control Officials. Young dogs were fed ad libitum to allow for adequate growth, while geriatric dogs were fed to maintain baseline BW throughout the experiment. To produce the desired metabolic effects, the PPB diet was formulated to contain a lower caloric density (APB = 5.38 kcal/g; PPB = 4.75 kcal/g) and have a lower nutrient digestibility than the APB diet. Thus, dogs fed the PPB diet needed to consume a greater (P<0.05) quantity of food (237 g/d; 1123 kcal/d) than dogs fed the APB diet (166 g/d; 893 kcal/d) to grow (young) or maintain BW (geriatrics). Even though metabolic indices were altered, mean BW among dietary treatments was not different at any time over the course of the study for young or geriatric dogs. After 12 months on experiment, animals were fasted for 12 hr and then given a lethal dose (130 mg/kg BW) of sodium pentobarbital (Euthasol, Virbac Corp., Fort Worth, TX) intravenously into the left forearm. Death was confirmed by lack of respiration and a corneal reflex, and absence of a heartbeat detected with a stethoscope placed under the left elbow. Cerebral cortex samples were collected immediately after death was confirmed, flash frozen using liquid nitrogen, and stored at -80oC until further analysis.

Project description:Aging animals display a decline in a multitude of physical and physiological functions, including muscle function and strength. Muscle gene expression in dogs has been evaluated for a few select genes under pathogenic or varying dietary conditions, but global gene expression profiles of aged animals has not been performed. Because the mechanisms contributing to age-related decline in muscle function are poorly defined, we used canine microarrays to compare gene expression profiles of muscle tissue from geriatric and young adult dogs. Skeletal muscle (biceps femoris) samples were collected from 6 geriatric (12 yr-old) and 6 young adult (1 yr-old) female beagles after being fed one of two diets (animal protein-based versus plant-protein based) for 12 months. RNA samples were hybridized to Affymetrix GeneChip Canine Genome Arrays. Statistical analyses indicated that age had the greatest impact on gene expression, with 262 genes differentially expressed in geriatric dogs. Although not as robust as age, diet affected mRNA abundance of 22 genes. The effect of age was most notable in genes related to metabolism, cell cycle and cell development, and transcription function, with all of these functional groups being predominantly down-regulated in older animals. The effect of diet on gene expression was mostly limited to the geriatric animals, but interactions between age and diet do not allow for a clear-cut pattern of gene expression to be observed. Keywords: age; diet Six geriatric (11.1 yr old) and 6 weanling (8 wk old) female beagles were used. Three dogs of each age were assigned to one of two dietary treatments and fed for 12 months. Diets tested in this experiment were previously shown to manipulate energy metabolism. One diet was an animal-protein based diet (APB) and was composed primarily of highly digestible ingredients and animal-derived protein and fat sources (brewer’s rice, poultry by-product meal, poultry fat) and was formulated to contain 28% protein, 23% fat, and 5% dietary fiber. The other diet was a plant-protein based diet (PPB) and was composed primarily of moderately digestible plant-derived ingredients (corn, soybean meal, wheat middlings, and meat and bone meal) and was formulated to contain 26% protein, 11% fat, and 15% dietary fiber. Although the two diets were very different in terms of ingredient and chemical composition, both were formulated to meet or exceed all nutrient requirements for canine growth according to the Association of American Feed Control Officials. Young dogs were fed ad libitum to allow for adequate growth, while geriatric dogs were fed to maintain baseline BW throughout the experiment. To produce the desired metabolic effects, the PPB diet was formulated to contain a lower caloric density (APB = 5.38 kcal/g; PPB = 4.75 kcal/g) and have a lower nutrient digestibility than the APB diet. Thus, dogs fed the PPB diet needed to consume a greater (P<0.05) quantity of food (237 g/d; 1123 kcal/d) than dogs fed the APB diet (166 g/d; 893 kcal/d) to grow (young) or maintain BW (geriatrics). Even though metabolic indices were altered, mean BW among dietary treatments was not different at any time over the course of the study for young or geriatric dogs. After 12 months on experiment, animals were fasted for 12 hr and then given a lethal dose (130 mg/kg BW) of sodium pentobarbital (Euthasol, Virbac Corp., Fort Worth, TX) intravenously into the left forearm. Death was confirmed by lack of respiration and a corneal reflex, and absence of a heartbeat detected with a stethoscope placed under the left elbow. Skeletal muscle samples were collected immediately after death was confirmed, flash frozen using liquid nitrogen, and stored at -80oC until further analysis.

Project description:The liver is the central organ in the regulation of nutrient metabolism, xenobiotic metabolism, and detoxification. Aging leads to a marked change in liver structure and function, characterized by a decline in weight, blood flow, regeneration rate, and detoxification. However, the mechanisms that contribute to these changes are poorly described. Global gene expression profiles of aged versus young adult dogs have not been compared previously. Thus, we used canine microarrays to compare gene expression profiles of liver tissue from geriatric and young adult dogs fed 2 different diets. Liver tissue samples were collected from 6 geriatric (12 yr-old) and 6 young adult (1 yr-old) female beagles after being fed one of two diets (animal protein-based versus plant-protein based) for 12 months. RNA samples were hybridized to Affymetrix GeneChip Canine Genome Arrays. Statistical analyses indicated that age had the greatest impact on gene expression, with 234 gene transcripts differentially expressed in geriatric dogs. Although not as robust as age, diet affected mRNA abundance of 137 gene transcripts. The effect of age was most notable, with increased expression in genes related to inflammation, oxidative stress, and glycolysis and decreased expression in genes associated with regeneration, xenobiotic metabolism, and cholesterol trafficking in senior dogs. The effect of diet on gene expression was not consistent, but led to more changes in young adult dogs. Six geriatric (11.1 yr old) and 6 weanling (8 wk old) female beagles were used. Three dogs of each age were assigned to one of two dietary treatments and fed for 12 months. Diets tested in this experiment were previously shown to manipulate energy metabolism. One diet was an animal-protein based diet (APB) and was composed primarily of highly digestible ingredients and animal-derived protein and fat sources (brewer’s rice, poultry by-product meal, poultry fat) and was formulated to contain 28% protein, 23% fat, and 5% dietary fiber. The other diet was a plant-protein based diet (PPB) and was composed primarily of moderately digestible plant-derived ingredients (corn, soybean meal, wheat middlings, and meat and bone meal) and was formulated to contain 26% protein, 11% fat, and 15% dietary fiber. Although the two diets were very different in terms of ingredient and chemical composition, both were formulated to meet or exceed all nutrient requirements for canine growth according to the Association of American Feed Control Officials. Young dogs were fed ad libitum to allow for adequate growth, while geriatric dogs were fed to maintain baseline BW throughout the experiment. To produce the desired metabolic effects, the PPB diet was formulated to contain a lower caloric density (APB = 5.38 kcal/g; PPB = 4.75 kcal/g) and have a lower nutrient digestibility than the APB diet. Thus, dogs fed the PPB diet needed to consume a greater (P<0.05) quantity of food (237 g/d; 1123 kcal/d) than dogs fed the APB diet (166 g/d; 893 kcal/d) to grow (young) or maintain BW (geriatrics). Even though metabolic indices were altered, mean BW among dietary treatments was not different at any time over the course of the study for young or geriatric dogs. After 12 months on experiment, animals were fasted for 12 hr and then given a lethal dose (130 mg/kg BW) of sodium pentobarbital (Euthasol, Virbac Corp., Fort Worth, TX) intravenously into the left forearm. Death was confirmed by lack of respiration and a corneal reflex, and absence of a heartbeat detected with a stethoscope placed under the left elbow. Liver samples were collected immediately after death was confirmed, flash frozen using liquid nitrogen, and stored at -80oC until further analysis.

Project description:Consumption of diets rich in fibers has been associated with several beneficial effects on gastrointestinal health. However, detailed studies on the molecular effects of fibers in colon are limited. In this study we investigated and compared the influence of five different fibers on the mucosal transcriptome, and luminal microbiota and SCFA concentrations in murine colon. Mice were fed diets enriched with fibers that differed in carbohydrate composition, namely inulin (IN), oligofructose (FOS), arabinoxylan (AX), guar gum (GG), resistant starch (RS) or a control diet (corn starch) for 10 days. Gene expression profiling revealed the regulation of specific, but also overlapping sets of epithelial genes by each fiber, which on a functional level were mainly linked to cell cycle and various metabolic pathways including fatty acid oxidation, tricarboxylic acid cycle, and electron transport chain. In addition, the transcription factor PPAR was predicted to be a prominent upstream regulator of these processes. Microbiota profiles were distinct per dietary fiber, but the fibers IN, FOS, AX and GG induced a common change in microbial groups. All dietary fibers, except resistant starch, increased SCFA concentrations but to a different extent. Multivariate data integration revealed strong correlations between the expression of genes involved in energy metabolism and the relative abundance of bacteria belonging to the group of Clostridium cluster XIVa, that are known butyrate producers. These findings illustrate the potential of multivariate data analysis to unravel simple relationships in complex systems. Keywords: Expression profiling by array Mice received a control diet, or a diet supplemented with 10% dietary fibers for 10 days. After an overnight fast colon was removed, epithelial cells were scraped off, and subjected to gene expression profiling.

Project description:Aging alters gastrointestinal morphology, microbiota, and functionality, and is associated with increased incidence of intestinal disease. The mechanisms that contribute to these changes are poorly described. Gene expression in dogs has been evaluated for a few select genes under pathogenic or varying dietary conditions, but global gene expression profiles of aged versus young adult dogs have not been compared previously. Thus, we used canine microarrays to compare gene expression profiles of colonic epithelial tissue from geriatric and young adult dogs fed 2 different diets. Colon tissue samples were collected from 6 geriatric (12 yr-old) and 6 young adult (1 yr-old) female beagles after being fed one of two diets (animal protein-based versus plant-protein based) for 12 months. RNA samples were hybridized to Affymetrix GeneChip Canine Genome Arrays. Statistical analyses indicated that age had the greatest impact on gene expression, with 212 genes differentially expressed in geriatric dogs. Although not as robust as age, diet affected mRNA abundance of 66 genes. The effect of age was most notable, with increased expression in genes related to inflammation, stress response, cellular metabolism and cell proliferation and decreased expression in genes associated with apoptosis and defense mechanism in senior dogs. The effect of diet on gene expression was not consistent, but appeared to have a greater response in senior dogs.

Project description:Peripheral blood mononuclear cell (PBMC) gene expression profiling is a low-invasive tool used in human diet intervention studies. In dogs this technique has been used to investigate disease states but not to examine the effect of diet. We tested the hypothesis that diet alters dog systemic immune cell gene expression profiles by comparing PBMC gene expression in dogs fed either a premium kibbled diet or a raw red meat diet for 9 weeks. Our results showed that diet shifted the dogs’ PBMC gene expression profile and these alterations corresponded with changes in plasma IgA levels. This illustrates that PBMC microarrays are a useful tool that may be applied to study the long-term effects of diet on health outcomes for the dog.

Project description:With increasing age microglia shift toward a pro-inflammatory phenotype and become hyperresponsive to inflammatory stimuli, disrupting brain homeostasis. Soluble fibers have been suggested as a dietary strategy to prevent or reverse microglia dysregulation, due to the bioactive nature of the short chain fatty acids (SCFA; e.g., butyrate) produced during its fermentation in the colon.

Project description:In contrast to the well-established role of oxidative muscle fibers in regulating fatty acid oxidation and whole body metabolism, little is known that about the function of fast/glycolytic muscle fibers in these processes. Here, we generated a skeletal muscle-specific, conditional transgenic mouse expressing a constitutively-active form of Akt1. Transgene activation led to muscle hypertrophy due to the growth of type IIb muscle fibers, which was accompanied by an increase in strength. These mice were then used to assess the consequence of building fast/glycolytic muscle fibers on adiposity and metabolism. Akt1 transgene induction in obese mice resulted in reductions in body weight and fat mass, a resolution of hepatic steatosis and improved metabolic parameters. These effects were achieved independent of changes in physical activity and levels of food consumption. Akt1-mediated skeletal muscle growth opposed the effects of high fat/sucrose diet on transcript expression patterns in the liver, and increased hepatic fatty acid oxidation and ketone body production. Our findings indicate that an increase in fast/glycolytic muscle mass can result in the regression of obesity and obesity-related metabolic disorders in part through its ability to alter fatty acid metabolism in remote tissues. Experiment Overall Design: 11 samples are included in this series. 3 wild-type mice fed on a normal diet, 4 wild-type mice fed on a HF diet, and 4 Akt1 double transgenic mice fed on a HF diet. All samples are on the mixed background.