Ontogeny of the ryanodine receptor in rabbit urinary bladder smooth muscle

Bladder smooth muscle contraction is mediated by both direct calcium entry through the cell membrane, and by calcium induced calcium release (CICR) from the sarcoplasmic reticulum (SR) storage sites. Ryanodine is a neutral plant alkaloid which binds to an ion channel located on the SR membrane. Its effects in cardiac skeletal muscle are well characterized where it inibits the efflux of intracellular calcium stores, and thus it serves as a negative inotrope. It has also been shown that in the develpping rabbit myocardium, there is a gradual increase in the expression of this ion channel. Little has been written about the expression and function of the ryanodine sensitive ion channel in smooth muscle. Recently we have shown that neonatal rabbit bladder smooth muscle is not very sensitive to ryanodine, while that from mature rabbits is extremely sensitive. This leads us to quantify the expression of the ryanodine sensitive ion channel. In this paper we demonstrate that the Kd values do not change to any significant degree with normal rabbit bladder development. However the Bmax values for 3 day, 2, 4, 6, and 8 week rabbit bladder smooth muscle are 7, 10, 15, 29, and 44 fmol specifically bound ryanodine/mg protein. The differences between the neonatal groups and the mature groups are significant (P<0.5). This increase in ryanodine sensitive ion channel expression with normal growth would suggest that with normal maturation, the bladder smooth muscle cell acquires an increased pool of sequestrered intracellular calcium. This would follow a similar pattern of development that has already been described in rabbit myocardium.     

Creatine kinase activity in normal and hypertrophied rabbit urinary bladder tissue (following partial outlet obstruction)

The urinary bladder depends on intracellular ATP to support a number of essential intracellular processes including contraction. The concentration of ATP is maintained by mitochondrial oxidative phosphorylation, cytosolic glycolysis and the cytosolic activity of creatine kinase, the enzyme that catalysis the rapid transfer of a phosphate from creatine phosphate (CP) to ADP resulting in the formation of ATP.Prior studies in this lab and others have demonstrated that mitochondrial respiration is significantly lower in hypertrophied bladder tissue (induced by partial outlet obstruction of the white New Zealand Rabbit). In addition to decreased mitochondrial respiration, there are significant increases in glycolysis and lactic acid formation in the hypertrophied tissue.In view of the increased glycolysis and decreased mitochondrial function in the hypertrophied tissue, and the importance in creatine kinase in maintaining cytosolic levels of ATP, the current study was designed to determine if outlet obstruction induces any changes in the activity of creatine kinase.The following is a summary of the results: 1) The bladder mass increased from 2.2 ± 0.2 gm to 11.5 ±1.6 gm at 7 days following outlet obstruction. 2) The intracellular concentrations of both ATP and CP were significantly reduced in the bladder tissue following 7 days of obstruction. 3) The percent of protein (per tissue mass) was significantly lower in the obstructed bladders, although the percent of soluble protein was similar. 4) Creatine kinase activity of control bladders showed linear kinetics with a V_max = 1120 nmoles/mg protein/4 min and K_m = 147 µM CP. 2) The creatine kinase activity of obstructed bladders also displayed linear kinetics with a V_max = 1125 nmoles/mg protein/4 min tissue, and K_m = 276 µM CP.These studies demonstrate that whereas both control and obstructed bladders have virtually identical maximum creatine kinase activities, the K_m for the obstructed tissue is significantly higher than the K_m for the control tissue. This may indicate that under cellular conditions (at sub-maximum substrate concentrations), the creatine kinase activity of the obstructed bladders may be significantly lower than the activity of the control bladders. In addition, the reduced tissue concentrations of ATP and CP would certainly be consistent with the reduced functional response to bethanechol and field stimulation.     

Expression of stress proteins (HSP-70 and HSP-90) in the rabbit urinary bladder subjected to partial outlet obstruction

Partial obstruction of the rabbit bladder outlet induces a rapid hypertrophy characterized by increased bladder mass, increased smooth muscle content, and increased collagen deposition. In addition, partial outlet obstruction induces decreased contractile responses to both field stimulation and postsynaptic receptor stimulation. Although the morphological and contractile responses to partial outlet obstruction have been well characterized, there is little information on the cellular and molecular mechanisms of these changes. In a previous study, we demonstrated that one of the earliest genes to be expressed following partial outlet obstruction in rabbits was the gene expressing stress protein-70 (HSP-70). In order to further define the genetic and molecular basis of these responses, the expression of stress gene products HSP-70 and HSP-90 in rabbit urinary bladder subjected to partial outlet obstruction has been quantitatively evaluated by Western blot coupled with laser densitometry using anti-HSP-70 and-90 monoclonal antibodies. The data show that stress gene products HSP-70 and HSP-90 are constitutively expressed in control rabbit bladder tissue and transiently increased following partial outlet obstruction. Increased content of HSP-70 was detected at 6 hr after obstruction and reached a maximum (2.7-fold over the control level) at 24 hr. Increased HSP-90 was also detected at 6 hr but reached a maximum (4.5-fold over the control level) at 12 hr. By 7 day post-obstruction, the content of these two proteins returned to the control levels. This study suggests that alterations of stress gene expression resulting in increased HSP-70 and 90 may play an important role in the response of the bladder to partial outlet obstruction.     

Vascular response of the rabbit bladder to chronic partial outlet obstruction

Partial outlet obstruction of the rabbit urinary bladder results, initially, in a rapid increase in bladder mass and remodeling of the bladder wall. Previously, it was shown that this response was characterized by serosal growth (thickening) which was apparent after 1 day of obstruction, before any visible vascularization was observed. After 1 week of obstruction, significant microvessel formation was seen in the transition region between the detrusor smooth muscle and the thickening serosa; after 2 weeks the entire serosa was vascularized.In this study we investigated the effect of chronic (4 week) partial outlet obstruction on microvessel density and distribution in the bladder wall immunohistochemically using CD31 as a marker for vascular endothelium. Transverse sections of bladder wall were examined after 4 weeks of no surgery, sham surgery or partial obstruction.The microvessel density of the obstructed rabbit bladder mucosa and detrusor smooth muscle increased relative to augmentation of these compartments while new vessels appeared in the thickening serosa. Although vessel density did not change with obstruction a significant shift in mean vessel circumference to the left occurred indicating a significant increase in the number of microvessels and small vessels consistent with angiogenesis.     

Effect of partial outlet obstruction on nitrotyrosine content and distribution within the rabbit bladder

Purpose: Evidence indicates that free radicals are etiological factors in obstructive bladder disease. However, it is not clear which species of reactive oxygen or nitrogen species mediate the damage. The current studies were designed to determine if partial outlet obstruction in rabbits results in the generation of nitrotyrosine (NT). Materials and methods: Sixteen rabbits were separated into four groups of four. The rabbits in groups 1 and 2 underwent sham operation while rabbits in groups 3 and 4 underwent partial outlet obstruction. The rabbits in groups 1 and 3 were evaluated after 1 week of obstruction and the rabbits in groups 2 and 4 were evaluated after 2 weeks of obstruction. A separate group of four controls were evaluated simultaneously with the sham and obstructed rabbits. Four rabbits from each group were evaluated after 1 and 2 weeks of obstruction. Four control rabbits were also evaluated. Isolated strips were evaluated for contractile responses and NT content of the mucosa and muscle were quantitated by Western blot analysis. Results: (1) The mucosa contains both 42 and 62 kD proteins exhibiting a strong nitrotyrosine signal; the muscle presents a signal only at 62 kD. (2) The sham operations had no effect on nitrotyrosine distribution or content. (3) The nitrotyrosine of both mucosal proteins and the muscle protein are increased in the 1 week obstructed bladder; whereas, only the 62 kD signal is increased in the two week obstructed bladder mucosa. (4) The contractile response to FS are reduced to a significantly greater degree than the responses to carbachol, KCl, or ATP. Conclusions: These studies clearly demonstrated that partial outlet obstruction in rabbits results in significant increases in nitrotyrosine within the bladder and may contribute to the contractile dysfunctions mediated by partial outlet obstruction. (Mol Cell Biochem 276: 143–148, 2005)     

Expression of constitutive heat shock protein-70 in normal (non-stressed) rabbit urinary bladder tissue

The expression of constitutive HSP-70 in the urinary bladder was determined by SDS-PAGE and western blotting using a mouse monoclonal antibody against HSP-70. The western blot analysis showed that the mouse anti-HSP-70 cross-reacted with a 70 kDa protein present in the extracts of the urinary bladder muscle and mucosa. Densitometric scanning of the western blots allowed us to specifically quantitate the relative amounts of the HSP-70. The quantitation of the HSP-70 by combining immunoblotting and densitometry using a laser scanner is reproducible and this technique requires only a small amount of tissue. The amounts of HSP-70 can be estimated from a standard curve of nanogram(ng) of HSP-70 vs absorption from the immunoblots. The amounts of HSP-70 in the muscular and mucosal layers in the body of the urinary bladder are more than those in the base of the bladder. The presence of HSP-70 in the muscle and mucosal epithelium of the bladder was demonstrated by immunohistochemical analysis of freshly removed tissue from the base and the body of bladder from normal animals.     

Control of urinary bladder smooth muscle excitability by the TRPM4 channel modulator 9-phenanthrol

The Ca²⁺-activated monovalent cation selective transient receptor potential melastatin 4 (TRPM4) channel has been recently identified in detrusor smooth muscle (DSM) of the urinary bladder. Two recent publications by our research group provide evidence in support of the novel hypothesis that TRPM4 channels enhance DSM excitability and contractility. This is a critical question as prior studies have primarily targeted hyperpolarizing currents facilitated by K⁺ channels, but the depolarizing component in DSM cells is not well understood. For the first time, we utilized the selective TRPM4 channel inhibitor, 9-phenanthrol, to investigate TRPM4 channel functional effects in DSM at both cellular and tissue levels in rodents. Our new data presented here showed that in rat DSM cells, 9-phenanthrol attenuates spontaneous inward currents in the presence of the muscarinic receptor agonist, carbachol, thus reducing DSM cell excitability. In support of our original hypothesis, we found that TRPM4 channel mRNA levels are much higher in DSM vs. vascular smooth muscle and that inhibition of TRPM4 channels can potentially attenuate DSM excitability. Thus, we postulate the novel concept that selective pharmacological inhibition of TRPM4 channels can limit both excitability and contractility of DSM.     

Metabolic studies on rabbit bladder smooth muscle and mucosa

Recent studies indicate that the mucosa of the urinary bladder may play a major role in the maintenance of normal bladder function. The mucosal surface of the urinary bladder serves as a protective layer against the irritative solutes found in the urine. The integrity of this barrier can be broken by overdistension, anoxia, detergents, alcohols, bacterial infection and by contact with agents to which the mucosa has been sensitized.In view that both anoxia and ischemia can mediate a breakdown in the role of the mucosal layer as a permeability barrier, it is reasonable to assume that this function is dependent on cellular metabolism. As an initial investigation we have compared a variety of biochemical and metabolic parameters between the mucosal layer (consisting of the lamina propria, urothelium, and any connective tissue and vascular tissue within this layer); and the muscularis layer.The results of these studies demonstrated that the rate of glucose metabolism to lactic acid (LA) of the mucosa was more than three-fold greater than that of the smooth muscle. The rate of CO₂ production of the mucosa was 60% greater than that of the unstimulated smooth muscle. The maximal activity of the mitochondrial enzyme citrate synthase was significantly greater in the mucosa than in the smooth muscle, however, the activity of malate dehydrogenase was similar for both tissues. The maximal activity of the cytosolic enzyme creatine kinase was more than two-fold greater in the bladder smooth muscle than in the mucosa; although the affinities of the creatine kinase isoforms of the mucosa were sigificantly greater than those of the muscle.Although the concentrations of ATP and ADP were similar in both muscle and mucosa, the level of creatine phosphate (CP) was over four-fold greater in the bladder muscle while the level of AMP in the muscle was only 58% of that in the mucosal epithelium.In summary, the rate of glucose metabolism was greater in the mucosa than in the smooth muscle although the concentrations of high energy phosphates (ATP+CP) was significantly greater in the smooth muscle. Future studies will be directed at identifying the specific cellular processes within the mucosal layer that relate to the function of the urothelium as a permeability barrier.     

The effect of partial outlet obstruction on prostaglandin generation in the rabbit urinary bladder

Partial outlet obstruction of the urinary bladder has been demonstrated to induce specific dysfunctions in cellular and sub-cellular membrane structures within the bladder's smooth muscle and mucosal compartments. Recent studies have linked these membrane dysfunctions to alterations in phospholipid metabolism leading to mobilization of free arachidonic acid, the precursor for synthesis of prostaglandins (PG). The purpose of this study was to determine if partial outlet obstruction of the urinary bladder induces changes in the capacity of bladder smooth muscle and mucosa to generate PG. PG were isolated from control and partially obstructed urinary bladder smooth muscle and mucosa of male New Zealand White (NZW) rabbits. PG concentrations (PGE2, PGF2alpha and PGI2, as its stable metabolite 6-keto-PGF1alpha) were determined after 30 minute incubations using enzyme-linked immunoassay (ELISA) kits. In both control and obstructed rabbit urinary bladders, PG generation was significantly higher in isolated mucosa than muscle tissues. A significantly higher concentration of PGF2alpha, and 6-keto-PGF1alpha was measured in obstructed muscle tissue relative to controls. The concentration of 6-keto-PGF1alpha was also significantly higher than the concentrations measured for PGE2 and PGF2alpha in both control and obstructed smooth muscle samples. The generation of PGE2 was significantly higher in rabbit urinary bladder mucosa than either PGF2alpha or 6-keto-PGF1alpha in both control and obstructed samples. The capacity of obstructed mucosal tissue to generate 6-keto-PGF1alpha was significantly higher than control tissue, while no significant differences in PGE or PGF2alpha generation were noted. These data suggest obstruction of the urinary bladder induce specific elevations in PG in both smooth muscle and mucosal tissues.     

Contraction kinetics and myosin isoform composition in smooth muscle from hypertrophied rat urinary bladder

Mechanical properties and isoform composition of myosin heavy and light chains were studied in hypertrophying rat urinary bladders. Growth of the bladder was induced by partial ligation of the urethra. Preparations were obtained after 10 days. In maximally activated skinned preparations from the hypertrophying tissue, the maximal shortening velocity and the rate of force development following photolytic release of ATP were reduced by about 20 and 25%, respectively. Stiffness was unchanged. The relative content of the basic isoform of the essential 17 kDa myosin light chain was doubled in the hypertrophied tissue. The expression of myosin heavy chain with a 7 amino acid insert at the 25K/50K region was determined using a peptide-derived antibody against the insert sequence. The relative amount of heavy chain with insert was decreased to 50%, in the hypertrophic tissue. The kinetics of the cross-bridge turn-over in the newly formed myosin in the hypertrophic smooth muscle is reduced, which might be related to altered expression of myosin heavy or light chain isoforms. © 1996 Wiley-Liss, Inc.     

The effect of vitamin E on the response of rabbit bladder smooth muscle to hydrogen peroxide

There is increasing evidence that ischemia, reperfusion, and the generation of free radicals are major etiological factors in the progression of bladder dysfunction after partial outlet obstruction. In vitro studies demonstrated that the magnitude of contractile dysfunction following exposure of bladder smooth muscle to hypoxia followed by re-oxygenation was related to the level of lipid peroxidation indicating that membrane lipid peroxidation participated in the contractile failure induced. Recent studies demonstrated that incubation of isolated strips of bladder smooth muscle with hydrogen peroxide (H₂O₂) result in progressive contractile dysfunctions and is associated with progressive increases in MDA (peroxidation product). The current study investigates if feeding rabbits a diet high in vitamin E protects the bladder from the effects of in vitro H₂O₂. Sixty-four male New Zealand White rabbits were separated into two groups: The rabbits in group 1 were fed a normal diet (28 rabbits) whereas the rabbits in group 2 were placed on a diet enriched with -tocopherol (36 rabbits). After 3 weeks on the normal or high E diet, each rabbit was anesthetized and the bladder excised and cut into 6 isolated strips of bladder detrusor. Each strip was mounted in individual 15 ml baths containing oxygenated Tyrode's solution. The contractile responses to field stimulation (FS), carbachol, and KCl were determined. The strips were washed and exposed to one of the following concentrations of hydrogen peroxide (H₂O₂): 0% (control), 0.0625, 0.125, 0.25, 0.5, 1.0 and 3.0% for a period of 1 h. At the end of the hour each strip was washed free of H₂O₂ and a second set of contractile responses were performed and compared to the first set. At the end of the experiment, each strip was frozen and stored at –70°C for analysis of malondialdehyde (MDA) as a measure of peroxidation. In both groups, H₂O₂ produced similar dose dependent decreases in the contractile responses to all forms of stimulation. In the normal-diet group H₂O₂ produced a dose dependent increase in MDA formation, whereas in the high E group there were no increases in MDA at any concentration of H₂O₂. Feeding rabbits a diet high in vitamin E protected the bladder smooth muscle from peroxidation, but had no significant effect on the contractile dysfunctions mediated by direct incubation with H₂O₂.     

雄性大鼠膀胱出口梗阻两种模型制作方法的比较研究

目的 通过采用耻骨后膀胱颈和会阴途径球部尿道部分结扎两种方法,建立雄性大鼠膀胱出口部分梗阻（paritial bladder outlet obstraction,pBOO）模型,并对所建模型进行鉴定和比较,为pBOO后膀胱重构（bladder reconstruction）的深入研究提供一种成活率高,复制性和稳定性较好的动物模型.方法 80只健康雄性Wistar大鼠随机分为三组：I组为假手术组（对照组）,20只;II组为耻骨后途径膀胱颈部分结扎组,30只;III组为会阴途径球部尿道部分结扎组,30只.依据梗阻时间分别将I组、II组、III组大鼠随机分为2周组和4周组,于术后2周和4周对大鼠行尿动力学检测后,完整切除膀胱测其重量,将精囊腺组织和部分膀胱用4%甲醛固定,HE染色观察组织学变化.结果 II组和III组成活率分别为73.3%和80.0%,二者无统计学意义;I组、II组、III组建模手术时间分别为（9.75±2.29）、（17.33±3.54）、（10.77±2.44）min,II组与I组和III组比较差异均有统计学意义;I组、II组、III组的2周组和4周组逼尿肌漏尿点压（detrusor leak point pressure,DLPP）分别为（26.31±2.32）、（27.34±3.93）、（24.68±2.39）mmHg和（26..42±2.41）、（34.23±3.01）、（32.63±3.20）mmHg,I组与II组和III组的4周组比较差异有统计学意义,II组和III组的2周组和4周组比较差异均有统计学意义.结论 耻骨后途经膀胱颈部分结扎和会阴途径球部尿道部分结扎两种方法都能成功建立雄性大鼠pBOO模型,与耻骨后途径相比,会阴途径成活率高,手术操作时间短,复制性和稳定性好.     

Prostaglandins and cyclic nucleotides in the urinary bladder of a rabbit model of partial bladder outlet obstruction

Bladder outlet obstruction (BOO) is a common disorder that is associated with altered bladder structure and function. For example, it is well established that BOO results in hypertrophy and hyperplasia of the bladder smooth muscle as well as detrusor instability. Since prostaglandins (PGs) and cyclic nucleotides (cyclic AMP [cAMP] and cyclic GMP [cGMP]) mediate both smooth muscle tone and proliferation, it is reasonable to suggest that changes in their levels may be involved in the pathophysiology of BOO-associated bladder disorders. Hence, the objective of this study was to investigate cyclic AMP, cyclic GMP and prostaglandins in the bladder of a rabbit model of BOO. BOO was induced in adult male New Zealand White rabbits. After 3 weeks, urinary bladders were excised, weighed and cut into segments. They were then incubated with stimulators of PGs, cAMP and cGMP and the formation of PGs, cAMP and cGMP were measured using radioimmunoassays. There was a significant increase in the obstructed bladder weights (P=0.002). The formation of PGE2, PGI2, cAMP and cGMP was significantly diminished in the detrusor (P<0.05) and bladder neck (P<0.05) in the BOO bladders compared to age-matched controls. Since PGE2, PGI2, cAMP and cGMP are known to inhibit the proliferation of smooth muscle cells (SMCs), the decreased synthesis of these factors, in BOO, may play a role in bladder SMC hypertrophy/hyperplasia. Our study points to the possible use of drugs that modulate the NO-cGMP and/or PG-cAMP axes in BOO-associated bladder pathology.     

Respiration and sodium transport in rabbit urinary bladder

Respiration of rabbit urinary bladder was measured in free-floating pieces and in short-circuited pieces mounted in an Ussing chamber. Ouabain, amiloride, and potassium-free saline inhibited respiration approx. 20%; sodium-free saline depressed respiration approx. 40–50%. The coupling ratio between respiration and transport in short-circuited tissues was about two sodium ions per molecule O₂. Chloride-free saline depressed mean oxygen consumption 21% in free-floating tissue pieces; 4-acetamido-4′-isothiocyanostilbene-2,2′-disulfonic acid (SITS) and furosemide had no effect. The effect of chloride-free saline in short-circuited tissues was variable; in tissues with low transport rates, respiration was stimulated about 21% while in tissue with high transport rates respiration was reduced about 24%. Nystatin and monensin, both of which markedly increase the conductance of cell membranes with a concomitant increase in sodium entry, stimulated respiration. These data indicate that 50–60% of the total oxygen consumption is not influenced by sodium, 20–25% is linked to (Na⁺ + K⁺)-ATPase transport, while the remaining 25–30% is sodium-dependent but not ouabain-inhibitable.     

Alterations in the contractile phenotype of the bladder: lessons for understanding physiological and pathological remodelling of smooth muscle

The contractile properties of the urinary bladder are changed by the conditions of normal development and partial bladder outlet obstruction. This change in the contractile phenotype is accompanied by changes in the regulatory cascades and filaments that regulate contractility. This review focuses on such changes during the course of normal development and in response to obstruction. Our goal is to discuss the experimental evidence that has accumulated from work in animal models and correlate these findings with the human voiding phenotype.     

Reversal of muscle hypertrophy in the rat urinary bladder after removal of urethral obstruction

We studied the ultrastructure of the bladder musculature after first inducing hypertrophy by means of urethral obstruction and subsequently removing the obstruction. With hypertrophy the bladder musculature increases ten-fold or more in volume; after de-obstruction approximately 4/5 of the hypertrophic muscle weight and volume is lost within six weeks. In spite of this very large decrease in muscle mass there is no degeneration of muscle cells or nerve endings or of other cell types in the de-obstructed bladder either at 5 days or at 6 weeks. The individual muscle cells are smaller in size than in the hypertrophic bladder but still larger than control muscle cells. The decrease in muscle cell size is more substantial than the decrease in muscle cell surface. There are no lysosomes or other signs of intracellular degradation in any cells of the muscle layer. The musculature contains a very large amount of intercellular material, mainly collagen. This study documents the great plasticity of the musculature in the reduction of muscle mass after de-obstruction. However, some of the fine structural features are almost as different from the controls as in the hypertrophic muscle.     

Serum response factor, its cofactors, and epithelial-mesenchymal signaling in urinary bladder smooth muscle formation

Little is known about the mechanism of bladder smooth muscle differentiation. We hypothesize that epithelial-mesenchymal signaling induces the expression of smooth muscle proteins in bladder mesenchyme resulting in smooth muscle differentiation. We confirmed that smooth muscle differentiation in the mouse urinary bladder occurs first at gestational day 14 (E14) based upon immunohistochemical localization of smooth muscle alpha-actin (SMAA). To investigate murine bladder smooth muscle differentiation and epithlelial-mesenchymal signaling in the developing bladder, we analyzed gene expression profiles of intact embryonic murine bladders and separated epithelial and mesenchymal components at embryonic days E13, E14, E15, E16, and postnatal day 1 (P1). Using cDNA microarray, we identified regulators of vascular smooth muscle differentiation in bladder mesenchyme, including serum response factor (SRF) and its cofactors, ELK1 and SRF accessory protein (SAP)1, as well as two SRF-associated pathways, angiotension receptor II and transforming growth factor- beta2. Immunohistochemistry showed diffuse expression of SRF in the bladder at E12 with localization of expression to the peripheral mesenchyme at E13 and E14. Our results suggest that bladder smooth muscle differentiation may share a similar gene expression program as occurs during vascular smooth muscle differentiation. The unique structure of the urinary bladder makes it an ideal model for studies of smooth muscle differentiation and epithelial-mesenchymal signaling.