Abnormal cardiovascular responses to exercise during the development of obesity in dogs

Obese dogs exhibit different fecal microbiome and specific microbial networks compared with normal weight dogs

Canine obesity is a major health concern that predisposes dogs to various disorders. The fecal microbiome has been attracting attention because of their impact on energy efficiency and metabolic disorders of host. However, little is known about specific microbial interactions, and how these may be affected by obesity in dogs. The objective of this study was to investigate the differences in fecal microbiome and specific microbial networks between obese and normal dogs. A total of 20 beagle dogs (males = 12, body weight [BW]: 10.5 ± 1.08 kg; females = 8, BW: 11.3 ± 1.71 kg; all 2-year-old) were fed to meet the maintenance energy requirements for 18 weeks. Then, 12 beagle dogs were selected based on body condition score (BCS) and divided into two groups: high BCS group (HBCS; BCS range: 7-9, males = 4, females = 2) and normal BCS group (NBCS; BCS range: 4-6, males = 4, females = 2). In the final week of the experiment, fecal samples were collected directly from the rectum, before breakfast, for analyzing the fecal microbiome using 16S rRNA gene amplicon sequencing. The HBCS group had a significantly higher final BW than the NBCS group (P < 0.01). The relative abundances of Faecalibacterium, Phascolarctobacterium, Megamonas, Bacteroides, Mucispirillum, and an unclassified genus within Ruminococcaceae were significantly higher in the HBCS group than those in the NBCS group (P < 0.05). Furthermore, some Kyoto Encyclopedia of Genes and Genomes (KEGG) modules related to amino acid biosynthesis and B vitamins biosynthesis were enriched in the HBCS group (P < 0.10), whereas those related to carbohydrate metabolism were enriched in the NBCS group (P < 0.10). Microbial network analysis revealed distinct co-occurrence and mutually exclusive interactions between the HBCS and NBCS groups. In conclusion, several genera related to short-chain fatty acid production were enriched in the HBCS group. The enriched KEGG modules in the HBCS group enhanced energy efficiency through cross-feeding between auxotrophs and prototrophs. However, further studies are needed to investigate how specific networks can be interpreted in the context of fermentation characteristics in the lower gut and obesity in dogs.

Guidelines for animal exercise and training protocols for cardiovascular studies

Whole body exercise tolerance is the consummate example of integrative physiological function among the metabolic, neuromuscular, cardiovascular, and respiratory systems. Depending on the animal selected, the energetic demands and flux through the oxygen transport system can increase two orders of magnitude from rest to maximal exercise. Thus, animal models in health and disease present the scientist with flexible, powerful, and, in some instances, purpose-built tools to explore the mechanistic bases for physiological function and help unveil the causes for pathological or age-related exercise intolerance. Elegant experimental designs and analyses of kinetic parameters and steady-state responses permit acute and chronic exercise paradigms to identify therapeutic targets for drug development in disease and also present the opportunity to test the efficacy of pharmacological and behavioral countermeasures during aging, for example. However, for this promise to be fully realized, the correct or optimal animal model must be selected in conjunction with reproducible tests of physiological function (e.g., exercise capacity and maximal oxygen uptake) that can be compared equitably across laboratories, clinics, and other proving grounds. Rigorously controlled animal exercise and training studies constitute the foundation of translational research. This review presents the most commonly selected animal models with guidelines for their use and obtaining reproducible results and, crucially, translates state-of-the-art techniques and procedures developed on humans to those animal models.

CD1d-associated expression of NF-kB and cardiac dysfunction in diabetic and obese mice

In patients with obesity and diabetes mellitus, abnormal production of inflammatory factors may result in cardiovascular dysfunction. In the current study, we tested the impact of CD1d-mediated innate immune responses on the expression and activation of NFkB in the hearts of adipose diabetic (db/db) mice. Splenocytes from adult db/db and CD1d-knockout mice of both genders and their wild-type, C57BL/6 and Balb/C counterparts were examined for tumor necrosis factor (TNF)-alpha and TNF-alpha receptor type 1. The percentage of natural killer T (NKT) cells in CD3+ T cells was compared with that in nondiabetic control mice. Despite the absence of inflammatory infiltrates, the hearts of db/db mice showed alterations in TNF-alpha receptor-1 and NFkB activity, including increased expression of both the NFkB p52 and p65 subunits. In the hearts of CD1d-knockout mice, p52 expression was reduced, while p65 expression remained largely unchanged. On echocardiography, the ratio of E to A transmitral flow velocities (an indicator of diastolic function) was significantly decreased in db/db mice after they swam for 30 minutes. These results provide evidence for CD1d-mediated NFkB activation and diastolic dysfunction in the hearts of db/db mice. Therefore, CD1d-associated abnormalities of innate immune responses and TNF-alpha production in splenic tissue may contribute to NFkB activation and cardiac dysfunction in type 2 diabetes.

Faecal microbiota in lean and obese dogs

Previous work has shown obesity to be associated with changes in intestinal microbiota. While obesity is common in dogs, limited information is available about the role of the intestinal microbiota. The aim of this study was to investigate whether alterations in the intestinal microbiota may be associated with canine obesity. Using 16S rRNA gene pyrosequencing and quantitative real-time PCR, we evaluated the composition of the faecal microbiota in 22 lean and 21 obese pet dogs, as well as in five research dogs fed ad libitum and four research dogs serving as lean controls. Firmicutes, Fusobacteria and Actinobacteria were the predominant bacterial phyla. The phylum Actinobacteria and the genus Roseburia were significantly more abundant in the obese pet dogs. The order Clostridiales significantly increased under ad libitum feeding in the research dogs. Canine intestinal microbiota is highly diverse and shows considerable interindividual variation. In the pet dogs, influence on the intestinal microbiota besides body condition, like age, breed, diet or lifestyle, might have masked the effect of obesity. The study population of research dogs was small, and further work is required before the role of the intestinal microbiota in canine obesity is clarified.

Weight cycling during growth and beyond as a risk factor for later cardiovascular diseases: the 'repeated overshoot' theory

In people trying to lose weight, there are often repeated cycles of weight loss and regain. Weight cycling is, however, not limited to obese adults but affects people of normal weight, particularly young women, who are unhappy with their appearance. Furthermore, the onset of a pattern of weight cycling is shifting towards younger ages, owing to the increasing prevalence of overweight and obesity in children and adolescents, and the pressure from the media and society for a slim image even for normal weight children. Although there is still controversy whether weight cycling promotes body fat accumulation and obesity, there is mounting evidence from large population studies for increased cardiovascular risks in response to a behavior of weight cycling. Potential mechanisms by which weight cycling contributes to cardiovascular morbidity include hypertension, visceral fat accumulation, changes in adipose tissue fatty acid composition, insulin resistance and dyslipidemia. Moreover, fluctuations in blood pressure, heart rate, sympathetic activity, glomerular filtration rate, blood glucose and lipids that may occur during weight cycling--with overshoots above normal values during weight regain periods--put an additional load on the cardiovascular system, and may be easily overlooked if humans or animals are studied during a state of relatively stable weight. Overshoot of those risks factors, when repeated over time, will stress the cardiovascular system and probably contribute to the overall cardiovascular morbidity of weight cycling.

Multiple mechanisms involved in obesity-induced hypertension

Obesity and hypertension are two major cardiovascular risk factors gaining epidemic proportions in our modern world. The interplay between hypertension, obesity and their major detrimental outcome, cardiovascular disease, is multifaceted and can be represented as the three corners of a triangle. Obesity and hypertension both lead to cardiovascular complications. In addition, obesity per se can promote hypertension. In turn, cardiovascular diseases can also predispose to obesity and hypertension. Low levels of physical activity due to a weakened heart promote weight gain. Endothelial, vascular and renal dysfunctions, all consequences of high blood pressure, further worsen hypertension. The loop of mutually amplifying detrimental effects is thus closed: a 'vicious triangle' is established. The association between obesity and hypertension was recognised and described almost a century ago, but the mechanisms that underlie this connection are still not fully understood. Vasoconstriction and sodium retention seem to be the cornerstones of the obesity-hypertension puzzle. However, pathways possibly leading to vasoconstriction and sodium retention are numerous. Evidence has been gathered that hyperleptinaemia, hyperinsulinaemia and elevated free fatty acids may induce sympathetic activation and vasoconstriction. The latter is further potentiated by insulin resistance and endothelial dysfunction. Positive sodium balance and ensuing volume expansion may be due to increased renal tubular sodium reabsorption induced by sympathetic stimulation, insulin or by a hyperactive renin-angiotensin system. All enumerated factors act together toward a state of permanently elevated blood pressure.

Adolescent Obesity Adversely Affects Blood Pressure and Resting Heart Rate

BACKGROUND

Obesity is associated with hypertension (HT) and high resting heart rate (HR), as well as metabolic disturbances. However, little is known about how strongly these hemodynamic abnormalities are associated with the degree of obesity in adolescents.

METHODS AND RESULTS

Height, body weight, resting HR, and systolic and diastolic blood pressures were measured in 20,165 male and 19,683 female high-school students. Adiposity levels were classified into 6 groups by body mass index: group 1 (<20th percentile), group 2 (20th-39.9th percentile), group 3 (40th-59.9th percentile), group 4 (60th-79.9th percentile), group 5 (80th-98.9th percentile), and group 6 (> or =99th percentile). Systolic and diastolic hypertensions were defined as > or =140 mmHg and > or =85 mmHg, respectively. Resting tachycardia was defined as the corresponding 95th percentile or greater. Resting HR and systolic and diastolic blood pressures increased with adiposity level in both sexes (p<0.0001). Both systolic HT and diastolic HT were associated with high resting HR, and the clustering of these unfavorable conditions increased with the degree of obesity.

CONCLUSION

Hemodynamic abnormalities, such as HT and a high resting HR, are closely associated with adolescent obesity and are probably explained by impaired autonomic nerve function.

Ectopic fat storage in heart, blood vessels and kidneys in the pathogenesis of cardiovascular diseases

In humans and most animal models, the development of obesity leads not only to increased fat depots in classical adipose tissue locations but also to significant lipid deposits within and around other tissues and organs, a phenomenon known as ectopic fat storage. The purpose of this review is to explore the possible locations of ectopic fat in key target-organs of cardiovascular control (heart, blood vessels and kidneys) and to propose how ectopic fat storage can play a role in the pathogenesis of cardiovascular diseases associated with obesity. In animals fed a high-fat diet, cardiac fat depots within and around the heart impair both systolic and diastolic functions, and may in the long-term promote heart failure. Accumulation of fat around blood vessels (perivascular fat) may affect vascular function in a paracrine manner, as perivascular fat cells secrete vascular relaxing factors, proatherogenic cytokines and smooth muscle cell growth factors. Furthermore, high amounts of perivascular fat could mechanically contribute to the increased vascular stiffness seen in obesity. Finally, accumulation of fat in the renal sinus may limit the outflow of blood and lymph from the kidney, which would alter intrarenal physical forces and promote sodium reabsorption and arterial hypertension. Taken together, ectopic fat storage in key target-organs of cardiovascular control may impair their functions, contributing to the increased prevalence of cardiovascular diseases in obese subjects.

Cardiovascular vagosympathetic activity in rats with ventromedial hypothalamic obesity

OBJECTIVE

Rats with ventromedial hypothalamic lesion (VMH) are massively obese with endogenous hyperinsulinemia, insulin resistance, low sympathetic activity, and high parasympathetic activity, which are likely to induce hypertension. The goal was to follow in this model the long-term hemodynamic changes and to investigate the role of autonomic nervous system and insulin resistance in these changes.

RESEARCH METHODS AND PROCEDURES

Heart rate and blood pressure were monitored for 12 weeks after operation using a telemetric system in VMH and sham rats. Plasma catecholamines and heart beta-adrenoceptors were measured. Glucose tolerance was studied after an intravenous glucose injection and insulin sensitivity during a euglycemic hyperinsulinemic clamp test.

RESULTS

A marked bradycardia and only a mild increase in blood pressure occurred in VMH rats compared with sham animals. Response to autonomic-acting drugs showed an increase in heart vagal tone and responsiveness to a beta-agonist drug. Plasma catecholamine levels were markedly increased, and the density and affinity of heart beta-adrenoceptors were similar in VMH, sham, and control rats. Muscle glucose use was reduced by 1 week after operation in VMH animals.

DISCUSSION

These results show the following in this model of massively obese rats with sympathetic impairment: 1). adrenal medulla secretion is increased, probably as a result of hyperinsulinemia and increased vagal activity; 2). cardiac responsiveness to beta-agonist stimulation is increased; and 3). despite these changes and suspected resistance to the vasodilative effect of insulin, blood pressure does not increase. We conclude that high vagal activity may be protective against hypertension associated with obesity.

Mechanisms of hypertension and kidney disease in obesity

Abnormal kidney function is an important cause as well as a consequence of obesity. Excess renal sodium reabsorption, probably in the loop of Henle, and a hypertensive shift of pressure natriuresis play a major role in initiating increased blood pressure associated with weight gain. The mechanisms responsible for increased sodium reabsorption and altered pressure natriuresis in obesity include activation of the renin-angiotension and sympathetic nervous systems, and physical compression of the kidneys due to accumulation of intrarenal fat and extracellular matrix. Sympathetic activation may be mediated, in part, by elevated circulating leptin and interactions with neuropeptides in the hypothalamus. Renal remodeling and extracellular matrix proliferation likely involve complex interactions between intrarenal physical forces, neurohumoral factors, and local growth factors and cytokines. Although glomerular hyperfiltration and increased arterial pressure help to compensate for increased renal tubular reabsorption in the early phases of obesity, these changes also increase glomerular capillary wall stress which, along with activation of neurohumoral systems and increased lipids and glucose intolerance, cause glomerular cell proliferation, matrix accumulation, and eventually glomerulosclerosis and loss of nephron function in the early phases of obesity. This creates a slowly developing vicious cycle that requires additional increases in arterial pressure to maintain sodium balance and therefore makes effective antihypertensive therapy more difficult. Because obesity is the main cause of Type 2 diabetes and an important cause of human essential hypertension, it seems likely that obesity is also one of the most important risk factors for end-stage renal disease.

Diastolic compliance is reduced in obese rabbits

Obesity often leads to symptoms of cardiopulmonary congestion associated with normal systolic but abnormal diastolic function. This study analyzed alterations in passive diastolic compliance in obesity using the rabbit model. New Zealand White rabbits were fed a normal (n=8) or 10% added fat diet (n=8). After 12 weeks, rabbits fed the high fat diet developed obesity (5.34+/-0.11 versus 3.68+/-0. 04 kg, P</=0.05) and left ventricular hypertrophy (1.37+/-0.07 versus 0.98+/-0.03 g dry weight, P</=0.05). Compliance was assessed with the isolated heart preparation by analyzing the passive end-diastolic left ventricular pressure-volume relationship. The pressure-volume relation was fit to an exponential function by regression analysis; results showed that the modulus of stiffness was greater in obese than in lean rabbits (1.21+/-0.16 versus 0. 83+/-0.05, P</=0.05), indicating that diastolic compliance was reduced. Computer simulation analyses suggested that an isolated reduction in diastolic compliance may contribute to elevated cardiac filling pressures and exercise intolerance. These data suggest that diastolic compliance is reduced early in the development of obesity and may be an important component in the reduction of cardiac reserve in obesity.

Changes in skeletal muscle vascular resistance with weight gain: associations with insulin and sympathetic activity

OBJECTIVE

This study was designed to characterize changes in peripheral vascular resistance with weight gain, and whether these changes are correlated with insulin and/or sympathetic activity.

RESEARCH METHODS AND PROCEDURES

Femoral vascular resistance (FVR), mean arterial pressure, heart rate, and plasma insulin were measured before and during overfeeding in seven dogs with unilateral lumbar ganglionectomy (L3 to L6). Measurements were taken standing and while walking on a treadmill.

RESULTS

There was a significant main effect of weight gain to increase mean arterial pressure (16.5+/-8.4 mmHg and 12.5+/-6.8 mmHg increase for standing and walking baseline, respectively) and heart rate (increase from week 1 of 31.6+/-10.6 beats/minute standing and 38.3+/-9.1 walking beat/minute). FVR increased immediately with overfeeding/ weight gain [standing: denervated (DNX):1.32+/-0.3 to 2.34+/-0.5; intact: 0.88+/-0.17 to 1.9+/-0.33 mmHg/mL.min(-1)], but returned to baseline with continued weight gain. Return of FVR to baseline occurred between weeks 2 and 3 of overfeeding in the DNX limb, but did not return to baseline until week 6 in the innervated limb. These changes were not correlated with plasma insulin levels.

DISCUSSION

These data suggest that vascular resistance may be normal in the obese, but increases in vascular resistance occur early with weight gain (before changes in arterial pressure). This initial increase in vascular resistance could initiate the series of events leading to obesity-associated hypertension. Additionally, changing vascular resistance during weight gain may be influenced by sympathetic activity, because DNX limb FVR returned to baseline approximately 3 weeks earlier than the innervated limb.

Hemodynamic alterations in hypertensive obese rabbits

There is little information on changes in overall and regional hemodynamics in obesity-associated hypertension. Therefore, the purpose of this study was to determine alterations in overall and regional blood flows and resistances in adipose and nonadipose tissues in a new model of obesity-associated hypertension in rabbits. Sixteen female New Zealand White rabbits were fed either a maintenance or high-fat diet; after 8 to 12 weeks cardiac output and regional blood flows were measured with the use of radioactive microspheres. Obese rabbits (5.22 +/- 0.14 versus 3.66 +/- 0.04 kg) had higher blood pressure (113 +/- 3 versus 95 +/- 1 mm Hg), cardiac output (812 +/- 59 versus 593 +/- 47 mL/min), and heart rate (269 +/- 12 versus 219 +/- 9 beats per minute) and lower overall peripheral resistance (0.14 +/- 0.01 versus 0.17 +/- 0.01 mm Hg/[mL/min]) than lean rabbits. Compared with lean controls, obese rabbits had higher weights of the ventricles, kidneys, liver, ovaries, adrenals, diaphragm, and spleen. Absolute blood flows were greater in the ventricles, kidneys, lungs, and ovaries, but differences were minimized when flows were normalized for organ weight. Adipose tissue flow per gram weight was significantly lower and resistance higher in obese rabbits. However, calculated total adipose tissue flow was higher in obese rabbits (86 versus 45 mL/min). Absolute resistances were lower in the left ventricle, kidneys, and large intestine, but when resistances were indexed for organ weight, kidney resistance tended to be higher in obese rabbits. These results indicate that even short periods of obesity-associated hypertension result in marked overall and regional hemodynamic changes.