Sucrose-drinking Rats Research Articles

Hexosamine biosynthetic pathway activity in leptin resistant sucrose-drinking rats

Rats offered 30% sucrose solution in addition to chow and water become leptin resistant therefore we investigated the effect of sucrose solution consumption on leptin signaling. In Experiment 1 rats were resistant to 3rd ventricle injections of1.5μg leptin after 36days of sucrose and western blot indicated that resistance was associated with increased basal levels of signal transducer and activator of transcription 3 phosphorylation (pSTAT3). In Experiment 2 rats were resistant to a peripheral injection of 2mg leptin/kg after 26days of sucrose. Immunohistochemistry indicated that increased basal pSTAT3 was limited to the medial and lateral arcuate nucleus of the hypothalamus. Increased availability of glucose and fructose can stimulate the hexosamine biosynthetic pathway (HBP) which O-GlcNAc-modifies proteins. This has the potential to change protein bioactivity. We tested whether this pathway could account for the leptin resistance. There was no increase in the expression of HBP enzymes in tissues from sucrose rats in Experiment 1, however, direct activation of the HBP with a 3h intravenous infusion of 30μmol/kg/min glucosamine significantly increased hypothalamic pSTAT3. Although sucrose consumption and activation of the HBP both increase hypothalamic pSTAT3 experiments described here did not provide evidence of a direct link between sucrose consumption, HBP activity and leptin resistance. Unexpectedly, we found that the HBP enzyme glutamine fructose-6-phosphate amidotransferase (GFAT) in liver and O-GlcNAcase in hypothalamus were increased 30min after leptin injection in leptin responsive animals, implying a complex interaction between activity of the HBP and leptin responsiveness.

The Kv7 potassium channel activator retigabine decreases alcohol consumption in rats

Background: Activation of Kv7 potassium channels may decrease the reactivity of mesolimbic dopaminergic neurons that are implicated in mediating the reinforcing effects of ethanol. Objectives: The objective of this study was to determine whether the administration of the Kv7 potassium channel opener retigabine would decrease ethanol intake in Long Evans rats. Methods: A limited access two-bottle choice model of alcohol (10% solution) consumption was used in this study. A separate group of animals was tested to evaluate the actions of retigabine on sucrose (5% solution) consumption to determine whether this drug might produce non-selective impairment of the ability of rats to drink liquids. Animals were treated with either vehicle or increasing doses (2.5–7.5 mg/kg SC) of retigabine administered over a 3-day period. Results: Compared to vehicle, retigabine at a dose of 7.5 mg/kg produced a reduction in the amount of ethanol consumed. These effects did not occur in association with significant changes in water consumption. A significant time effect was found for the actions of retigabine in sucrose-drinking rats with a trend for an increase in sucrose intake with the highest dose of retigabine administered. Conclusions: These results indicate that the administration of retigabine may produce a decrease in ethanol consumption by rats at doses that do not significantly reduce the drinking of either water or a sucrose solution. These findings are consistent with the hypothesis that activation of Kv7 channels facilitates the reduction of alcohol consumption in the rat.

Functional Response of Bladder Strips From Streplozotocon Diabetic Rats Depends on Bladder Mass

We investigated the relationship of bladder mass to responses to electrical field stimulation and adrenergic agonists in diabetic rat bladders. Longitudinal strips were removed from the ventral and dorsal detrusor of age matched control, 2-month diabetic and sucrose drinking rats. Contractile responses to electrical field stimulation, KCl and phenylephrine, and relaxation in response to norepinephrine and isoproterenol were measured. Bladders from sucrose drinking and diabetic rats weighed significantly more than those of controls. Diabetic rats were divided into 2 groups with the bladder weighing less than or greater than 265 mg. Strips from small diabetic bladders were generally more responsive to field stimulation and norepinephrine than those from control or sucrose drinking rats. Conversely decreased function was especially apparent in dorsal strips from large diabetic bladders. Ventral strips were significantly more sensitive to the relaxant actions of norepinephrine and isoproterenol than dorsal strips. Our results suggest that the responsiveness of diabetic rat bladder to electrical field stimulation and adrenergic agonists is related to bladder mass, analogous to observations after partial outlet obstruction. Decreased function was particularly apparent in dorsal strips from diabetic rats with a large bladder.

Sucrose diuresis protects rat bladder from outlet partial obstruction-induced contractile dysfunction

Objectives. Evidence is accumulating that bladder dysfunction caused by experimental partial obstruction of the bladder outlet can be reduced or reversed by treatment that results in upregulation of bladder function, even in the presence of obstruction. Inducing diuresis in rats or rabbits results in a significant increase in bladder mass and increased contractility in response to stimulation. The objective of the present study was to determine whether diuresis-induced amplification of bladder function in the rat could protect the bladder from contractile dysfunctions caused by partial outlet obstruction. Methods. Thirty-two rats were separated into four groups of 8 rats each. Groups 2 and 4 were fed 5% sucrose instead of water; groups 1 and 3 were fed only water. Three weeks later, partial outlet obstructions were created in groups 3 and 4. After 4 weeks of obstruction, all bladders were rapidly excised and cut into longitudinal strips; each strip was mounted in an isolated muscle bath for contractile studies. Results. Sucrose-induced diuresis caused a moderate but significant increase in bladder mass. Partial outlet obstruction stimulated significant increases in bladder mass in both water-drinking and sucrose-drinking groups; the bladder mass of sucrose-drinking rats, however, increased less than that of water-drinking rats. In water-drinking rats, partial outlet obstruction resulted in significantly decreased bladder strip contractility in vitro in response to field stimulation (1 to 32 Hz), carbachol (0.1 to 22 μM), and KCl (120 mM). After 3 weeks of sucrose-induced diuresis, partial obstruction of the rat bladder outlet did not result in decreased in vitro contractile responses to any form of stimulation applied. Conclusions. Sucrose-induced diuresis caused an increase in bladder mass and an increase in contractile strength, consequently protecting the rat bladder from the contractile dysfunctions that usually follow partial outlet obstruction.

Temporal Changes in Micturition and Bladder Contractility after Sucrose Diuresis and Streptozotocin-induced Diabetes Mellitus in Rats

Studies were done to compare the acute effects of streptozotocin-induced diabetes and sucrose consumption on micturition, bladder mass and contractile responses of bladder strips to field stimulation and contractile agonists. Micturition changes occurred gradually in diabetic rats, reached maximal values within 7 to 14 days, and were accompanied by significant increases in bladder mass after 7 days. Bladder strips from diabetics responded to field stimulation, carbachol and KCl with significantly greater contractions than did those from controls within 7 days. Sucrose-drinking rats had maximal increases in fluid consumption and micturition frequency on the first night after starting treatment. Increases in micturition volumes were slower to develop than in diabetics. Bladder mass was significantly increased 30 and 60 days after starting sucrose treatment. Bladder strips from sucrose-drinking rats responded to field stimulation and carbachol with significantly greater contractions than did those from controls only after 60 days. Monitoring of drinking and micturition patterns established that diabetic rats drink and urinate during both the dark and light cycles. In contrast, control and sucrose-drinking rats drink and urinate principally at night. The results demonstrate that differences in bladder function between diabetic and sucrose drinking rats are apparent during the first month after treatment begins. The data suggest that the effects of diabetes and sucrose consumption on contractile bladder function are related to the diuresis-induced increases in bladder mass.

Factors underlying the increased sensitivity to field stimulation of urinary bladder strips from streptozotocin-induced diabetic rats.

1. The responses of bladder strips from control, streptozotocin-diabetic, and sucrose-drinking rats to electrical field stimulation were investigated. Sucrose-drinking rats were included as additional controls because they have enlarged bladders as a result of non-diabetic diuresis. 2. Bladder strips from diabetic rats developed more spontaneous activity than those from the two control groups. Indomethacin reduced the amplitude and frequency of spontaneous contractions suggesting that they resulted from endogenous prostaglandin formation. Tetrodotoxin (TTX) had little effect, while alpha, beta-methylene ATP caused increases in spontaneous activity. 3. Bladder strips from diabetic rats responded to field stimulation with greater contractions than controls in the absence of antagonists as well as in the presence of atropine and alpha, beta-methylene ATP. Increasing TTX concentrations caused a step-wise depression of the contractile response to electrical stimulation which was not affected by preincubation with either atropine or alpha, beta-methylene ATP. 4. Atropine and indomethacin had no effect on strength-duration curves constructed to measure threshold contractile responses to five pulses stimulation. The curves were shifted to the right by both TTX and alpha, beta-methylene ATP, indicating that the responses were neurogenic in nature and at least partially, the result of stimulation of P2-purinoceptors. In the absence of drugs, bladder strips from diabetics responded at lower voltages and pulse widths than those of control and sucrose-drinking rats, suggesting that they were more excitable. 5. The response curve of bladder strips from diabetics to field stimulation at increasing voltage was shifted upwards and to the left compared to strips from control or sucrose-drinking rats. 6. Bladder strips from diabetics responded to stimulation at increasing pulse width with greater responses than those from control or sucrose-drinking rats. At 1.0 ms pulse width, the TTX-resistant response of strips from diabetic rats was still greater than that of the other groups, indicating that a myogenic component was also involved.7. The data suggest that bladder strips from diabetic rats are more excitable than those of control or sucrose-drinking rats. This may result from diabetes-induced decreases in bladder lipid or other membrane changes, and/or be a result of partial depolarization, perhaps related to diabetic neuropathy.

Comparison of Urinary Bladder Function in Rats with Hereditary Diabetes Insipidus, Streptozotocin-Induced Diabetes Mellitus, and Nondiabetic Osmotic Diuresis

In vivo and in vitro bladder function were studied in three different models of increased diuresis: 1) Brattleboro rats with hereditary diabetes insipidus (di/di), 2) Sprague-Dawley rats with streptozotocin-induced diabetes mellitus (STZ), and 3) Sprague-Dawley rats with increased diuresis due to 5% sucrose added to the drinking water. When compared with controls, all three models showed bladder mass, increased water consumption and urine output, higher mean and maximal increased micturition volumes, and greater bladder capacity and compliance by in vitro cystometry. The changes were more extensive in di/di rats than in STZ and sucrose-drinking rats. The concentration of bladder collagen decreased in all three rat models when compared with controls. However, the collagen concentration of STZ bladders was significantly lower than the collagen concentration of di/di and sucrose bladders, suggesting that the decrease in bladder collagen concentration associated with experimental diabetes mellitus is only partly related to the increased diuresis. Contractile function was studied using a whole bladder model. Responses of whole bladders from control and diabetic rats to electrical field stimulation, carbachol and KCl were identical. Volume-pressure relations of the isolated whole bladder showed that the magnitude of the contractile response to KCl is constant at intravesical volumes ranging from about 10 to 95% of cystometrical bladder capacity. Bladders from Brattleboro di/di rats and STZ rats showed a rightward shift of volume-passive pressure curves when compared with appropriate controls. Bladders from sucrose-drinking rats had volume-passive pressure curves similar to the bladders from controls. This study suggests that while contractile function remains intact with increased diuresis, the passive function changes, with the bladder becoming more distensible.

The influence of diabetes mellitus on glucose utilization by the rat urinary bladder

Streptozocin-induced diabetes in rats causes changes in urinary bladder function and increases the responsiveness of isolated bladder strip preparations to contractile agents and field stimulation. We monitored the role of extracellular glucose in the contractile responsiveness of bladder body strips from control, 2-month diabetic, and sucrose-drinking rats to the muscarinic agonist bethanechol. Consumption of sucrose and induction of diabetes caused increases in bladder mass compared with that of controls. In the presence of normal glucose levels (5.6 mmol/L), bladder strips from diabetic rats responded to bethanechol with significantly larger responses than those from control or sucrose-drinking rats. Removal of glucose from the bathing medium caused time-dependent decreases in contractile response of bladder strips from all groups; there were no differences in the percent decrease in response between the three groups. The presence of insulin (100 mU/mL) had no effects on contractile responsiveness or the rate of decline of response. Following return of glucose to the medium, there were progressive increases in contractile responsiveness in all groups, which returned to original contractile values within 60 minutes and were unaffected by insulin. Pyruvate (9.1 mmol/L) was able to substitute for glucose in maintaining the contractile responses. Increasing the glucose concentration of the medium to 30 mmol/L had no effects on contractile responses. Unstimulated bladder adenosine triphosphate (ATP) and creatine phosphate concentrations were similar in control, diabetic, and sucrose-drinking rats. In conclusion, changes in glucose utilization and high-energy phosphate levels cannot explain the increased contractile responsiveness of bladder body strips from diabetic rats to contractile agents.

Length-Tension Relationship of Urinary Bladder Strips from Streptozotocin-Diabetic Rats

Streptozotocin-induced diabetes mellitus or the consumption of 5% sucrose in place of drinking water cause an increase in rat urinary bladder capacity and mass. Length-tension curves were generated using bladder body strips isolated from control, diabetic, or sucrose-drinking rats to determine whether the length-tension relationship was altered by the bladder hypertrophy associated with diabetic and nondiabetic diuresis. In addition, we compared the data using three different methods of expression: (1) absolute grams tension developed; (2) grams tension/100 mg tissue, and (3) grams tension/mm2. The cross-sectional area of strips from diabetic rats was increased compared to the other two groups. The length-passive tension curves for all three groups increased with increasing tissue length to a plateau. No optimal resting length for generation of active tension was found. Strips from diabetic and sucrose-drinking rats reached the plateau at a slightly larger passive tension than did strips from control rats. In addition, strips from diabetic and sucrose-drinking rats generally developed a greater active tension than did strips from control rats depending on the method of data presentation used. The data suggest that the complex nonlinear arrangement of smooth muscle fibers in the bladder wall results in the unusual length-tension curves generated by urinary bladder strips (as compared to skeletal or vascular smooth muscle). This relationship would be of benefit in the urinary bladders of early-stage diabetic patients before neuropathy development, where the stretching of the bladder wall would allow accommodation without any compromise of bladder function. The data indicate that comparisons of bladder strip function from control and diabetic rats should be done at passive tensions of greater than or equal to 2 g to ensure that maximal active tension is generated.

In vivo urinary bladder function in rats following prolonged diabetic and non‐diabetic diuresis

AbstractChanges in urinary bladder function are present in animal models of diabetes mellitus. In vivo cystometry in diabetic rats shows a bladder with increased capacity and a raised threshold for initiation of the micturition reflex. At sacrifice, diabetic rats have bladder hypertrophy, resulting in approximately a doubling of the bladder weight.This study was designed to characterize the effects of diabetes on micturition in the streptozotocin‐diabetic rat. For comparative purposes, two different control groups were examined: 1) age‐matched control rats and 2) age‐matched rats which were given 5% sucrose to drink. Sucrose‐fed rats consumed large volumes of fluid resulting in diuresis and bladder hypertrophy.Fluid consumption and excretion were significantly increased in diabetic and sucrose‐drinking rats. In addition, the diabetic rats both drank and excreted more than the sucrose‐drinking rats. Control rats had twice as many micturitions during the dark cycle than during the light cycle, but the volume micturition during the dark cycle was less than one‐half the volume per micturition during the light cycle. Sucrose drinking rats had the same number of micturitions as control rats during the light cycle. but the volumes per micturition were significantly increased. During the dark cycle, the number of micturitions increased four‐fold and the volume per micturition was significantly increased compared to controls. The diabetic rats, in contrast to the two control groups, had a significant increase in the number of micturitions during the light and dark cycles. Similar to the sucrose drinking rats, the volumes excreted per micturition were significantly greater than the normal controls. The data are discussed with regard to the effects of prolonged diuresis on bladder function and hypertrophy.

The influence of intravesical volume upon contractile responses of the whole bladder preparation from streptozotocin-diabetic rats

1. The in vivo whole bladder preparation was used to correlate bladder volume with the ability of urinary bladders from control, sucrose-drinking, and diabetic rats to develop pressure in response to bethanechol or nerve stimulation. 2. Both streptozotocin-induced diabetes mellitus and sucrose-diuresis caused an increase in rat urinary bladder capacity and mass. 3. There were significant decreases in the ability of bladders from control rats to develop pressure in response to bethanechol at 1.0 ml intravesical volume, but no change in responsiveness of bladders from sucrose-drinking or diabetic rats at different intravesical volumes. Bladders from sucrose-drinking and diabetic rats developed significantly less pressure in response to bethanechol stimulation at low intravesical volumes than did bladders from control rats. 4. Bladders from diabetic rats developed significantly less pressure in response to 32 Hz stimulation at 0.2 ml intravesical volume compared to larger volumes, however, there were no differences in the responses of bladders from sucrose-drinking or control rats at any intravesical volume. 5. Bladders from control and sucrose-drinking rats had a reduced ability to empty in response to bethanechol and field stimulation at large intravesical volumes. 6. Bladders from 8-week streptozotocin-diabetic rats are able to contract and empty efficiently in response to nerve stimulation and bethanechol over a wide range of intravesical volumes.