The TERE1 protein interacts with mitochondrial TBL2: regulation of trans-membrane potential, ROS/RNS and SXR target genes.

We originally discovered TERE1 as a potential tumor suppressor protein based upon reduced expression in bladder and prostate cancer specimens and growth inhibition of tumor cell lines/xenografts upon ectopic expression. Analysis of TERE1 (aka UBIAD1) has shown it is a prenyltransferase enzyme in the natural bio-synthetic pathways for both vitamin K-2 and COQ10 production and exhibits multiple subcellular localizations including mitochondria, endoplasmic reticulum, and golgi. Vitamin K-2 is involved in mitochondrial electron transport, SXR nuclear hormone receptor signaling and redox cycling: together these functions may form the basis for tumor suppressor function. To gain further insight into mechanisms of growth suppression and enzymatic regulation of TERE1 we isolated TERE1 associated proteins and identified the WD40 repeat, mitochondrial protein TBL2. We examined whether disease specific mutations in TERE1 affected interactions with TBL2 and the role of each protein in altering mitochondrial function, ROS/RNS production and SXR target gene regulation. Biochemical binding assays demonstrated a direct, high affinity interaction between TERE1 and TBL2 proteins; TERE1 was localized to both mitochondrial and non-mitochondrial membranes whereas TBL2 was predominantly mitochondrial; multiple independent single amino acid substitutions in TERE1 which cause a human hereditary corneal disease reduced binding to TBL2 strongly suggesting the relevance of this interaction. Ectopic TERE1 expression elevated mitochondrial trans-membrane potential, oxidative stress, NO production, and activated SXR targets. A TERE1-TBL2 complex likely functions in oxidative/nitrosative stress, lipid metabolism, and SXR signaling pathways in its role as a tumor suppressor.

Generation of a human urinary bladder smooth muscle cell line.

We report a cell line (hBSM) established from human urinary bladder wall smooth muscle that maintains most of the phenotypic characteristics of smooth muscle cells. Cells were dissociated from the muscular layer with collagenase (1 mg/ml) and collected and grown in M199 supplemented with 10% fetal calf serum and 1% antibiotic-antimycotic. Primary cultures were grown for 2 d and small colonies were isolated by placing glass rings around the colonies. These colonies were picked up with a fine-tipped Pasteur pipette and subcultured. This procedure was repeated several times until a culture with a uniform stable morphology was obtained. hBSM cells are elongated with tapered ends, and in high density cultures, they form swirls of cells arranged in parallel. These cells have a doubling time of approximately 72 h. Western blotting and immunofluorescence microscopy revealed stable expression of smooth muscle-specific proteins, including myosin isoforms (N-terminal isoforms SM-A/B and C-terminal isoforms SM1/2), SM22, α-smooth muscle actin, h-caldesmon, Ca(2+)-dependent myosin light chain kinase, and protein kinase G. These cells contract upon exposure to 10 µM bethanechol and this contraction is reversible by washing away the drug. Karyotyping showed tetraploidy with a modal chromosome number of 87, with multiple rearrangements. To our knowledge, the hBSM cell line is the first human cell line established from bladder wall smooth muscle that expresses both N- and C-terminal smooth muscle myosin isoforms. This cell line will provide a valuable tool for studying transcriptional regulation of smooth muscle myosin isoforms and effects of drugs on cellular function.

Partial bladder outlet obstruction induces urethral smooth muscle hypertrophy and decreased force generation.

PURPOSE: PBOO leads to increased urinary frequency, decreased void volume, hypertrophy of the detrusor SM, and alterations in contractile and regulatory proteins. This study was done to determine whether PBOO induced increases in urinary frequency and detrusor SM hypertrophy are associated with an alteration in the contractility and expression of myosin isoforms in urethral SM. MATERIALS AND METHODS: PBOO was surgically induced in male New Zealand White rabbits, and sham operated rabbits served as controls. After surgery, rabbits were kept 12 days, and prior to sacrifice, urine output and voiding frequency were monitored by keeping the animals in metabolic cages for 24 hours. Animals with increased urinary frequency (mean +/- SEM 43 +/- 12 voids per 24 hours) and sham operated rabbits (6 +/- 3 voids per 24 hours) were used for this study. Morphology of the urethra was studied using light and immunofluorescence microscopy. The expression of myosin isoforms was analyzed at the mRNA and protein levels by RT-PCR and Western blotting. RESULTS: The urethral wall and SM of PBOO rabbits showed hypertrophy. The force produced by the longitudinal muscle strips of PBOO animals in response to phenylephrine, KCl, or electrical field stimulation was decreased 50%, 37% and 40%, respectively. Immunofluorescence microscopy revealed a decrease in nerve density. RT-PCR and Western blotting showed a decrease in the expression of myosin isoform SM-B with a concomitant increase in SM-A at the mRNA and protein levels. CONCLUSIONS: Our data show hypertrophy of the urethral wall and SM, and alterations in contraction, innervation, and myosin isoforms in PBOO induced detrusor hypertrophy.

Over expression of smooth muscle specific caldesmon by transfection and intermittent agonist induced contraction alters cellular morphology and restores differentiated smooth muscle phenotype.

PURPOSE: The thin filament associated protein h-caldesmon (h-CaD) modulates actin myosin interaction and contraction. Bladder outlet obstruction and detrusor hypertrophy are associated with the over expression of the nonmuscle CaD isoform l-CaD. It implies a poorly differentiated state of bladder myocytes and cytoskeletal remodeling in detrusor hypertrophy. We determined if h-CaD expression can be increased in a unique bladder smooth muscle (BSM) cell line derived from obstructed rabbit bladder smooth muscle that over expresses l-CaD. We examined whether the genetic restoration of h-caldesmon is possible in bladder smooth muscle cells by transfection or by agonist mediated contraction and whether this manipulation would alter cellular morphology. MATERIALS AND METHODS: BSM cells were transfected with chicken h-CaD cDNA inserted into a mammalian vector. In another experiment BSM cells underwent intermittent bethanechol induced stimulation. h-CaD mRNA and protein were quantified with reverse transcriptase-polymerase chain reaction and Western blot analyses. Cell morphology was assessed using phase, video and confocal microscopy after double immunostaining with antibodies against alpha-actin and caldesmon. RESULTS: Reverse transcriptase-polymerase chain reaction using primers specific for the transfected vector and h-CaD cDNA confirmed stable transfection of cells and increased content of h-CaD mRNA. Following bethanechol induced intermittent contraction Western blotting revealed 80% relative over expression of h-CaD in treated transfected cell lines (p <0.05) and 74% (not significant) in treated nontransfected controls. Confocal immunofluorescence microscopy revealed CaD in the cytoplasmic filaments co-localized to alpha-actin in the main cell body and perinuclear region in transfected cells, in contrast to the diffuse, irregular distribution of these filaments in control cells. CONCLUSIONS: A unique bladder myocyte cell line was successfully and stably transfected with h-CaD cDNA. We show that agonist induced intermittent contraction preferentially increases h-CaD expression, the predominant CaD in nonobstructed bladder smooth muscle, and the restoration of h-CaD alters cell morphology and the organization of cytoplasmic filaments in cells derived from obstructed rabbit detrusor musculature.

Smooth muscle hypertrophy following partial bladder outlet obstruction is associated with overexpression of non-muscle caldesmon.

Partial bladder outlet obstruction (PBOO) induces remodeling of urinary bladder smooth muscle (detrusor). We demonstrate an increase in bladder wall mass, muscle bundle size, and a threefold increase in the cross-sectional area of detrusor myocytes following PBOO in male New Zealand White rabbits compared to that of controls. Some bladders with detrusor hypertrophy function close to normal (compensated), whereas others were dysfunctional (decompensated), showing high intravesical pressure, large residual urine volume, and voiding difficulty. We analyzed the expression of smooth muscle-specific caldesmon (h-CaD) and non-muscle (l-CaD) by Western blotting, RT-PCR, and real-time PCR. The expression of l-CaD is increased significantly at the mRNA and protein levels in the decompensated bladders compared to that of normal and compensated bladders. The CaD was also co-localized with myosin containing cytoplasmic fibrils in cells dissociated from obstructed bladders and cultured overnight. Our data show that the inability of decompensated bladders to empty, despite detrusor hypertrophy, is associated with an overexpression of l-CaD. The level of l-CaD overexpression might be a useful marker to estimate the degree of detrusor remodeling and contractile dysfunction in PBOO.

Alteration in expression of myosin isoforms in detrusor smooth muscle following bladder outlet obstruction.

Partial urinary bladder outlet obstruction (PBOO) in men, secondary to benign prostatic hyperplasia, induces detrusor smooth muscle (DSM) hypertrophy. However, despite DSM hypertrophy, some bladders become severely dysfunctional (decompensated). Using a rabbit model of PBOO, we found that although DSM from sham-operated bladders expressed nearly 100% of both the smooth muscle myosin heavy chain isoform SM-B and essential light chain isoform LC17a, DSM from severely dysfunctional bladders expressed as much as 75% SM-A and 40% LC17b (both associated with decreased maximum velocity of shortening). DSM from dysfunctional bladder also exhibited tonic-type contractions, characterized by slow force generation and high force maintenance. Immunofluorescence microscopy showed that decreased SM-B expression in dysfunctional bladders was not due to generation of a new cell population lacking SM-B. Metabolic cage monitoring revealed decreased void volume and increased voiding frequency correlated with overexpression of SM-A and LC17b. Myosin isoform expression and bladder function returned toward normal upon removal of the obstruction, indicating that the levels of expression of these isoforms are markers of the PBOO-induced dysfunctional bladders.

Generation of a cell line with smooth muscle phenotype from hypertrophied urinary bladder.

We have established a cell line from hypertrophied rabbit urinary bladder smooth muscle (SM) that stably expresses SM myosin (SMM). These cells, termed BSM, are spindle shaped and form swirls, similar to the "hills and valleys" described for cultured aortic SM cells. Western blotting revealed that BSM expresses the amino-terminal SMM heavy chain isoform SM-B, the carboxy-terminal SM1 and SM2 isoforms, and SM alpha-actin. In addition, they express cGMP-dependent protein kinase G, made by contractile SM cells in vitro but not by noncontractile cells synthesizing extracellular matrix. Immunofluorescence studies indicate a homogeneous population of cells expressing alpha-actin and SMM, including the SM-B isoform, and karyotyping demonstrates a stable 4N chromosomal pattern. These cells also express calcium-dependent myosin light chain kinase and phosphatase activity and contract in response to the muscarinic agonist bethanechol. To our knowledge, BSM is the first visceral SM cell line that expresses the SM-B isoform and might serve as a useful model to study the transcriptional regulation of tissue-specific SMM isoforms in differentiation and pathological SM.