Temperature preference of genetically obese (ob/ob) mice

Genetically obese (ob/ob) and lean mice selected their preferred ambient temperature in a thermal gradient. Preferred ambient temperature was defined as that ambient temperature which the mice selected for sleep during daylight hours. Lean mice selected a temperature of 31.2 degrees C which resulted in a body temperature (36.7 degrees C) not greatly different from the pretest body temperature of 36.4 degrees C. Obese mice selected 29.4 degrees C which resulted in a body temperature of 36.8 degrees C, 1.8 degrees C above the pretest body temperature of 35.0 degrees C. These data indicate that obese mice select an ambient temperature that results in a body temperature no different from that of lean mice. The selection by obese animals of an ambient temperature significantly lower than that of lean mice but which results in the same body temperature may reflect an effect of adiposity on heat loss. There is no evidence of a diminished thermoregulatory set-point in obese mice.     

Thermal preference behavior of genetically obese (ob/ob) and genetically lean (+/?) mice

Chronically lower colonic temperatures (T_cs) of genetically-obese (ob/ob) mice at ambient temperatures below thermoneutrality have led to speculation that these mutants regulate a lowered thermal setpoint relative to lean mice. Previous experiments, however, have not provided an opportunity for obese mice to exhibit compensatory thermoregulatory behaviors which might reinstate normal body temperature. In the present experiment, adult obese and lean (+/?) mice were tested at room temperature (25°C) on a copper bar, thermal gradient to determine what temperatures they would select and what effect their selection would have on their T_cs. The data revealed that ob/obs were more frequently observed within 25–35°C locales than were lean controls, which spent more time in the below-25°C zone (p<0.005). Ob/obs also raised their T_cs to pretest values of leans' T_cs, although ob/obs' T_cs remained significantly lower than those of leans at the conclusion of testing. These data suggest that the hypothermia exhibited by the ob/ob may reflect both the absence of the opportunity to behaviorally thermoregulate and a genetic defect in thermogenesis.     

Behavioural energy regulation in lean and genetically obese (ob/ob) mice

The role of behaviour in the control of energy regulation has been investigated in relation to environmental temperature, nutrition and genetics. Techniques of operant conditioning were used, with lean and genetically obese (ob/ob) mice being tested at three environmental temperatures (10, 20 and 30 degrees C) and on two feeding regimes (after a 24 hr fast and after feeding ad lib). They were allowed access to heat and food, although the design of the apparatus ensured that both were not available simultaneously. Both the lean and ob/ob showed an initial preference for heat when tested in a cold environment. At a low ambient temperature the ob/ob were dependent on the heater rather than food to increase rectal temperature, both when fasted and when fed. By contrast, the lean had a lower demand for heat than the obese and used the time to explore the environment and to feed. Food intake increased with an increase in ambient temperature in both genotypes. Possible reasons for this are discussed.     

Thermal preference behavior in preweaning genetically obese (ob/ob) and lean (+/?, +/+) mice

Impaired nonshivering thermogenesis and lowered rectal temperatures (Tre) are hallmarks that appear early in the postnatal ontogeny of the genetically obese (ob/ob) mouse. Adult obese mice compensate behaviorally for these impairments and do not defend their low Tres. We predicted that, because young mice primarily rely on behavior to ensure thermal homeostasis during preweaning development, the appearance of the obese mouse's thermoregulatory impairment should promote their continued reliance on behavioral thermoregulation compared to lean pups. Accordingly, intact litters of pups from heterozygous lean (C57BL/6J, ob/+) and from homozygous lean (+/+) matings were tested at 6, 12, and 18 days postpartum on a thermal gradient (14-44 degrees C). Obese pups had lower pretest Tres than lean (+/?) littermates at 6 days and lower pretest Tres than both lean littermates and homozygous (+/+) lean control pups at 12 and 18 days. Exposure to the gradient ameliorated these differences (i.e., no posttest Tre differences among phenotypes). Correspondingly, obese pups preferred warmer gradient locations than +/+ pups but similar locations to their phenotypically lean (+/?) littermates until 18 days, when both lean groups preferred similar thermal locations compared to warmer-seeking obese pups. These data support our hypothesis and emphasize the age-dependent impact of the ob gene on altering mouse pups' thermal preferences.     

Thermoregulation and non-shivering thermogenesis in the genetically obese (ob/ob) mouse

1. The capacity ofr thermoregulation and thermogenesis in lean and genetically obese (ob/ob) mice has been investigated. 2. At 4 degrees C ob/ob mice rapidly die of hypothermia, because of a reduced capacity for cold-induced thermogenesis, but the animals are able to survive if previously adapted to 12 degrees C. 3. At all environmental temperatures between 30 degrees C and 10 degrees C the body temperature of ob/ob mice is 2.0-2.5 degrees C below that of lean animals. This may be due to a lower "setting" for body temperature. 4. At 34 degrees C the oxygen consumption of obese mice is greater than that of the lean animals while at 30 degrees C it is similar. When the environmental temperature is below 30 degrees C the oxygen consumption of the lean mice is greater. The obese animals therefore expend less energy on thermoregulatory thermogenesis. 5. The capacity for non-shivering thermogenesis was measured in lean and obese mice by investigating the effect of an injection of L-nor-adrenaline (1000 microgram/kg body weight) on the metabolic rate at 31 degrees C. Non-shivering thermogenesis was reduced by one-half in the obese animals. 6. One cause of the obesity of the ob/ob mouse is its high metabolic efficiency. We suggest that this high metabolic efficiency is due, at least in part, to less energy being expended on thermoregulatory thermogenesis.     

Decrease in particle-induced osteolysis in obese (ob/ob) mice

There may be variability in the susceptibility of different individuals to osteolysis from wear debris, and it is not clear whether some individuals may have a genetic predisposition for a more marked osteolytic response. The purpose of this study in mice was to determine whether genetically determined obesity can alter the response to particulate debris. Polyethylene particles were implanted onto the calvaria of seven wild-type mice and seven obese mice (ob/ob). Calvaria from unimplanted wild-type and obese mice served as controls. Calvaria were harvested after 7 days, stained with toluidine blue and for tartrate-specific alkaline phosphatase, and analyzed by histomorphometry. The osteoclast number per mm total bone perimeter was 8.000+/-3.464 in wild-type animals with particles and 2.857+/-1.676 in ob/ob animals with particles (p=0.002; Fisher's PLSD). Bone resorption was 1.895+/-0.713 mm/mm(2) in wild-type animals with particles and 1.265+/-0.494 mm/mm(2) in ob/ob animals with particles (p=0.0438; Fisher's PLSD). Particles induced a diminished osteolytic response in genetically determined obese mice, suggesting that obesity may have a protective role against particle-induced bone resorption-similar to obesity and osteoporosis. These important new findings may help to stimulate clinical studies which may define criteria to better identify patients at risk to develop particle-induced osteolysis.     

Hunger and satiety in genetically obese mice (C57BL/6J-ob/ob)

To determine the mechanism for hyperphagia in genetically obese mice (C57BL/6J-ob/ob), several experiments were conducted on the ability of these mice to respond to caloric deficits and surpluses. Presentation of food or sugar reduces subsequent operant licking in both obese and lean mice. When given sugar solutions, evaporated milk, or sweetened non-fat milk, both obese and lean mice reduce food intake to compensate for the calories obtained from the solutions. These findings indicate that genetically obese mice respond normally to caloric surpluses. Obese mice respond to food deprivation (caloric deficit) by increasing subsequent food intake but they do so more slowly than controls.     

Food intake during tumor growth: anorexia in genetically obese ob/ob mice and hyperphagia in lean mice

Recent findings indicate that obese (ob/ob) mice suffer a low incidence of lung metastasis and survive longer than lean (+/?) littermates following injection with B16 melanoma cells [34]. The present study examined the food intake of obese and lean mice during the growth of this tumor. Mice from both groups increased their food intake by small and approximately equal amounts during the first three quarters of the survival period following injection with 10⁶ cells, and body weights remained fairly stable. During the final quarter, however, obese mice became anorexic whereas lean mice became intensely hyperphagic; body weights changed accordingly. Thus, food intake is differentially affected by tumor growth in this form of genetic obesity.     

Regulation of myoplasmic Ca(2+) in genetically obese (ob/ob) mouse single skeletal muscle fibres

The present study examined whether calcium handling in skeletal muscle fibres from ob/ob mice was abnormal compared to normal mice. Simultaneous measurements of free myoplasmic calcium and force were made in mouse single intact muscle fibres at rest, during repetitive stimulation and for 30 min afterwards. Fibres were subjected to two bouts of intermittent tetanic contractions 1 h apart. The first bout consisted of 50 tetani only, while during the second bout stimulation was continued until force fell to 40% of control. During a bout of 50 repeated contractions, muscle fibres from ob/ob mice were unable to maintain basal calcium and tetanic calcium transients. During a second series of contractions, muscle fibres from ob/ob mice showed a marked improvement in calcium handling compared to the first series but still fatigued more rapidly than control fibres. It is concluded that calcium handling in skeletal muscle fibres from ob/ob mice is abnormal compared to fibres from normal mice and this contributes to premature fatigue.     

Milk intakes of genetically obese (ob/ob) and lean mouse pups differ with enhanced milk supply

Although obese (C57Bl/6J, ob/ob) pups have greater avidity for nonnutritive suckling than leans as early as 15 days postpartum, previous research has not found differences in milk intake between ob/ob and lean mice during the preweaning period. Because ob/ob pups suckle longer than leans, their perseveration should enhance their opportunity to ingest milk if (a) maternal milk supply is not limited and (b) longer sucking durations reflect increased pup willingness to ingest milk. Accordingly, the present study was designed to evaluate the milk intake of ob/ob and lean pups when they had access to an enhanced supply of maternal milk. Intact litters of pups, from heterozygous lean (ob/+) parents, were randomly assigned to be tested at either 6, 12, or 18 days. Pups were neither dam- nor milk-deprived before being cross-fostered successively to milk-replete surrogate dams for 60 min each. Obese pups showed a greater percentage body weight gain (the index of milk intake) than leans did, with younger pups showing larger increments than 18-day-olds. Although early adiposity in ob/ob pups may not rely on increased intake in the single-dam, nest situation, these data emphasize an early predisposition to overeating in this mutant.     

Na+,K+-ATPase enzyme units in lean and obese (ob/ob) thyroxine-injected mice.

The possible involvement of Na+,K+-ATPase in the etiology of obesity in the obese (ob/ob) mouse was explored. The number of Na+,K+-ATPase enzyme units in skeletal muscle, liver, and kidneys from 4- and 8-wk-old obese and lean mice was estimated from saturable [3H]ouabain binding to particulate fractions. Neither phenotype nor age altered the Kd value for ouabain binding in these three tissue preparations. The total number of [3H]ouabain binding sites in hindlimb muscles was 35--55% lower in 4- and 8-wk-old obese mice than in their lean counterparts. However, the total number of [3H]ouabain binding sites in liver and kidneys of obese mice was similar to values observed in their lean counterparts. Because it has been suggested that ob/ob mice are hypothyroid, we investigated the response of Na+,K+-ATPase in these mice to thyroid hormone treatment (approximately 5 microgram thyroxine/day for 2 wk). The number of [3H]ouabain binding sites in the three tissues increased in both obese and lean mice injected with this relatively large dose of thyroxine, but the obese mice were 2--3 times more responsive than lean mice.     

Norepinephrine turnover in obese (ob/ob) mice: effects of age, fasting, and acute cold

The possibility that low sympathetic nervous system (SNS) activity in brown adipose tissue (BAT) of 8-wk-old obese (ob/ob) mice results from their gross obesity at that age was investigated. Norepinephrine (NE) turnover, an estimator of SNS activity, was measured in BAT and other organs of 2-wk-old preobese ob/ob mice, and at 4 and 8 wk of age. Rates of NE turnover were 36% slower in BAT of preobese ob/ob mice than in lean littermates and remained slow in their BAT at 4 (-66%) and 8 (-56%) wk of age. In heart, rates of NE turnover were 48% slower in preobese ob/ob mice than in lean littermates, but the difference diminished at 4 (-21%) and 8 (-16%) wk of age. Rates of NE turnover in white adipose tissue, liver, and pancreas of obese mice were generally comparable with rates in these organs of lean mice. Effects of fasting (24 h) and acute cold exposure (14 degrees C for 8 h) were also examined. In general, fasting lowered and cold exposure elevated NE turnover equally in obese and lean mice. Ob/ob mice housed at 23-25 degrees C exhibit low SNS activity in their BAT prior to the onset of gross obesity, even though SNS activity in their BAT responds normally to an acute cold stress. This low SNS activity probably contributes to their subsequent high efficiency of energy retention.     

Abnormal feeding and postprandial behavioral responses to food deprivation in genetically obese mice (C57B1/6J-ob/ob).

Meal size, intermeal interval (IMI), statiety ratio and postprandial behaviors of obese and lean male mice were measured after 1.5 to 6.0 hr of food deprivation in the dynamic and static phases of weight gain. Obese mice ate the same sized meal as lean mice after food deprivation except after 1.5 hr deprivation in the dynamic phase when obese mice ate more. Obese mice had significantly different satiety ratios than lean mice, but the nature of the difference depended on the phase of weight gain. In the dynamic phase obese mice had a significantly smaller satiety ratio after 1.5 hr deprivation, but in the static phase obese mice had a significantly larger satiety ratio after 1.5 and 3.0 hr deprivation. Thus the differences in meal taking did not persist from the dynamic to the static phase. Differences in postprandial behaviors did. Obese mice groomed less, explored less and rested more than lean mice in the dynamic and static phases of weight gain. This demonstrates that these differences in postprandial behaviors are dissociated from body weight and meal taking responses to deprivation.     

Behavioral response of the genetically obese (ob/ob) mouse to heat stress: effects of naloxone and prior exposure to immobilization stress

Genetically obese (ob/ob) mice, which possess abnormally elevated levels of pituitary β-endorphin and adrenocorticotropin exhibited less grooming, rearing and jumping during a five min exposure to different levels of heat stress compared to their lean littermate controls (ob/?). Naloxone had a diametrically opposite effect on rearing in these animals, particularly when exposed to low heat stress; it enhanced rearing in ob/ob mice and suppressed the rearing response in ob/? mice. Naloxone enhanced jumping in both the ob/ob mice and the ob/? mice. This effect was slightly, although not significantly, stronger in the obese mice. Finally, exposure to 10 min of immobilization stress before testing at 46°C, enhanced grooming and suppressed jumping in ob/ob and ob/? mice. Naloxone pretreatment reversed the effect of immobilization stress in ob/ob mice but not in their lean littermate controls. The data is discussed in terms of the differential involvement of pituitary endorphins in the behavioral response of ob/ob and ob/? mice to stress.     

The feeding response of obese mice (genotype,ob ob) and their wild-type littermates to cholecystokinin (pancreozymin)

Genetically obese mice that had been reared on a restricted diet and their wild-type littermates were deprived of food for 23 hours. Then, 10 minutes after an IP injection of either 0, 15, 30, 60 or 120 units/kg Cholecystokinin in saline vehicle, they were given behavioural tests. Consummatory feeding, drinking and exploratory activity were recorded for a period of 20 min. 15 Units/kg had no effect; higher doses caused a greater reduction in the feeding rates of obese than in wild-type mice. Frequencies of drinking and exploration remained unchanged. The results suggest that the characteristic hyperphagia of obese mice may be due, in part, to low levels of endogenous satiety hormones.     

Effects of the obese (ob/ob) genotype on spleen cell immune function.

Spleen cells from mice homozygous for the obese (ob) mutation killed DBA/2 mastocytoma target cells less well than spleen cells from lean littermates or unrelated age-and sex-matched controls of the same strain. Killing was impaired only when the attacker cells were primed in vivo, not following in vitro priming. Hence the effect of the ob/ob genotype is not to produce an irreversible functional change in the lymphocyte, but rather to produce an environment in which lymphocytes are less able to react to priming antigen. Not only were the spleen cells of in vivo primed obese mice less active than those of lean controls, but also their number per spleen was significantly decreased. Such a quantitive difference was no longer found in adrenalectomised animals, but the qualitative difference in spleen cell cytotoxic activity still occurred. This suggests that adrenocortical hyperfunction may affect immune function in obese mice, without necessarily being the only factor in the in vivo environment of obese mouse spleen cells capable of depressing cellular immune reactivity.     

The kappa opioid receptor, ingestive behaviors and the obese mouse (ob/ob)

Recent studies have suggested a role for the kappa opiate receptor and its endogenous ligand, dynorphin, in the central regulation of appetite. In this study we found that the ob/ob mouse was mildly resistant to the ability of three kappa agonists, viz, butorphanol, tifluadom, and ketocyclazocine to induce food intake. In addition, we could find no change in ir-dynorphin levels in 7 areas for the central nervous system. These findings do not provide evidence for a role of kappa opioid feeding system in the pathogenesis of obesity in the ob/ob mouse.     

Additive effects of leptin and topiramate in reducing fat deposition in lean and obese ob/ob mice

The objective of the present study was to investigate the effects of the antiepileptic drug topiramate (TPM) on components of energy balance in lean and obese (ob/ob) mice in the presence or absence of leptin. Lean and ob/ob mice infused with either leptin or phosphate-buffered saline were treated with TPM for 7 days. TPM was mixed into the diet and administered at a dose of 60 mg/kg/day, whereas leptin was infused at the rate of 100 microg/kg/day using osmotic minipumps, which were subcutaneously implanted in the interscapular region. Food intake and body weight were monitored throughout the study. Body composition was measured prior to and following treatment with TPM and leptin, using dual-energy X-ray absorptiometry (DEXA). Glucose (glucose oxidase method) and insulin (radioimmunoassay) were also determined. TPM and leptin significantly reduced body weight gain, food intake and body fat gain in obese mice. The effects of TPM and leptin on fat gain were also statistically significant in lean animals. There was no interaction of TPM and leptin on the energy balance variables, the effects of the two substances being additive instead. Leptin abrogated hyperinsulinemia in obese mutants whereas TPM did not alter insulin levels in either lean or obese mice. The combination of leptin and TPM led to the normalization of glucose levels in obese mice. Our study demonstrates an effect of TPM in leptin-deficient animals, which suggests that TPM does not require the presence of leptin to exert its effect. They also show that the effects of leptin and TPM can be additive. The treatment with leptin in ob/ob mice neither accentuated nor blunted the effect of TPM on energy balance.