Abstract 9: Smooth Muscle Cell Tgfbr2 Deletion in Mice Causes Aortic Hypercontractility and Impaired Endothelium-Dependent Relaxation

Background: Abnormal smooth muscle cell (SMC) TGF-β signaling is proposed as a critical driver in the development of thoracic aortic aneurysms and dissections (TAAD) associated with Marfan and Loeys-Dietz Syndromes as well as nonsyndromic TAAD. However, the mechanisms by which altered SMC TGF-β signaling causes TAAD are poorly understood. Others have proposed that loss of SMC TGF-β signaling causes TAAD by impairing SMC contractility, leading to aortic medial degeneration and dilation. However, mice generated in our lab with deficient SMC TGF-β signaling (due to SMC-specific deletion of the type II TGF-β receptor) have thicker aortic medias and increased mRNA encoding SMC contractile proteins. These observations predict increased contractility. Methods & Results: We addressed this apparent contradiction experimentally by measuring vasomotor function (by tension myography) and contractile protein expression (by immunoblotting) in aortas of mice with normal or deficient SMC TGF-β signaling. Isolated aortic rings from mice with deficient SMC TGF-β signaling showed increased contraction to phenylephrine (Emax: 13.5 mN vs 7.8 mN in controls; p<0.0001; n=19-20) and potassium chloride (Emax: 7.5 mN vs 5.7 mN in controls; p<0.0001; n=19-20). Moreover, levels of smooth muscle myosin heavy chain protein were at least as high in aortas with deficient SMC TGF-β signaling as in control aortas, consistent with their capacity to generate increased contractile force. Surprisingly, aortic segments from mice with deficient SMC TGF-β signaling also had impaired endothelium-dependent relaxation to acetylcholine (Emax: 37% vs 97% in controls; p<0.0001; n=19-20). Endothelium-independent relaxation to sodium nitroprusside was similar between the two groups. CD31 immunostaining of vessel segments revealed equivalent endothelial integrity in both groups. Conclusion: Physiologic SMC TGF-β signaling is an important determinant of both SMC contractility and endothelial function. Disruption of physiologic SMC TGF-β signaling may lead to TAAD through direct effects on SMC as well as through indirect effects on endothelial function. Our results also suggest an unanticipated role for SMC TGF-β signaling in regulating endothelial-mediated vasomotor function.

Architecture of the human renal inner medulla and functional implications

The architecture of the inner stripe of the outer medulla of the human kidney has long been known to exhibit distinctive configurations; however, inner medullary architecture remains poorly defined. Using immunohistochemistry with segment-specific antibodies for membrane fluid and solute transporters and other proteins, we identified a number of distinctive functional features of human inner medulla. In the outer inner medulla, aquaporin-1 (AQP1)-positive long-loop descending thin limbs (DTLs) lie alongside descending and ascending vasa recta (DVR, AVR) within vascular bundles. These vascular bundles are continuations of outer medullary vascular bundles. Bundles containing DTLs and vasa recta lie at the margins of coalescing collecting duct (CD) clusters, thereby forming two regions, the vascular bundle region and the CD cluster region. Although AQP1 and urea transporter UT-B are abundantly expressed in long-loop DTLs and DVR, respectively, their expression declines with depth below the outer medulla. Transcellular water and urea fluxes likely decline in these segments at progressively deeper levels. Smooth muscle myosin heavy chain protein is also expressed in DVR of the inner stripe and the upper inner medulla, but is sparsely expressed at deeper inner medullary levels. In rodent inner medulla, fenestrated capillaries abut CDs along their entire length, paralleling ascending thin limbs (ATLs), forming distinct compartments (interstitial nodal spaces; INSs); however, in humans this architecture rarely occurs. Thus INSs are relatively infrequent in the human inner medulla, unlike in the rodent where they are abundant. UT-B is expressed within the papillary epithelium of the lower inner medulla, indicating a transcellular pathway for urea across this epithelium.

Bladder smooth muscle organ culture preparation maintains the contractile phenotype

Smooth muscle cells, when subjected to culture, modulate from a contractile to a secretory phenotype. This has hampered the use of cell culture for molecular techniques to study the regulation of smooth muscle biology. The goal of this study was to develop a new organ culture model of bladder smooth muscle (BSM) that would maintain the contractile phenotype and aid in the study of BSM biology. Our results showed that strips of BSM subjected to up to 9 days of organ culture maintained their contractile phenotype, including the ability to achieve near-control levels of force with a temporal profile similar to that of noncultured tissues. The technical aspects of our organ culture preparation that were responsible, in part, for the maintenance of the contractile phenotype were a slight longitudinal stretch during culture and subjection of the strips to daily contraction-relaxation. The tissues contained viable cells throughout the cross section of the strips. There was an increase in extracellular collagenous matrix, resulting in a leftward shift in the passive length-tension relationship. There were no significant changes in the content of smooth muscle-specific α-actin, calponin, h-caldesmon, total myosin heavy chain, protein kinase G, Rho kinase-I, or the ratio of SM1 to SM2 myosin isoforms. Moreover the organ cultured tissues maintained functional voltage-gated calcium channels and large-conductance calcium-activated potassium channels. Therefore, we propose that this novel BSM organ culture model maintains the contractile phenotype and will be a valuable tool for the use in cellular/molecular biology studies of bladder myocytes.

Chemokine-like receptor 1 regulates skeletal muscle cell myogenesis

The chemokine-like receptor-1 (CMKLR1) is a G protein-coupled receptor that is activated by chemerin, a secreted plasma leukocyte attractant and adipokine. Previous studies identified that CMKLR1 is expressed in skeletal muscle in a stage-specific fashion during embryogenesis and in adult mice; however, its function in skeletal muscle remains unclear. Based on the established function of CMKLR1 in cell migration and differentiation, we investigated the hypothesis that CMKLR1 regulates the differentiation of myoblasts into myotubes. In C2C12 mouse myoblasts, CMKLR1 expression increased threefold with differentiation into multinucleated myotubes. Decreasing CMKLR1 expression by adenoviral-delivered small-hairpin RNA (shRNA) impaired the differentiation of C2C12 myoblasts into mature myotubes and reduced the mRNA expression of myogenic regulatory factors myogenin and MyoD while increasing Myf5 and Mrf4. At embryonic day 12.5 (E12.5), CMKLR1 knockout (CMKLR1−/−) mice appeared developmentally delayed and displayed significantly lower wet weights and a considerably diminished myotomal component of somites as revealed by immunolocalization of myosin heavy chain protein compared with wild-type (CMKLR1+/+) mouse embryos. These changes were associated with increased Myf5 and decreased MyoD protein expression in the somites of E12.5 CMKLR1−/− mouse embryos. Adult male CMKLR1−/− mice had significantly reduced bone-free lean mass and weighed less than the CMKLR1+/+ mice. We conclude that CMKLR1 is essential for myogenic differentiation of C2C12 cells in vitro, and the CMKLR1 null mice have a subtle skeletal muscle deficit beginning from embryonic life that persists during postnatal life.

Differentiation-dependent PTPIP51 Expression in Human Skeletal Muscle Cell Culture

Protein tyrosine phosphatase-interacting protein 51 (PTPIP51) expression was analyzed in proliferating and differentiating human myogenic cells cultured in vitro. Satellite cell cultures derived from four different individuals were used in this study. To analyze the expression of PTPIP51, myoblasts were cultured under conditions promoting either proliferation or differentiation. In addition, further differentiation of already-differentiated myobtubes was inhibited by resubmitting the cells to conditions promoting proliferation. PTPIP51 protein and mRNA were investigated in samples taken at defined time intervals by immunostaining, immunoblotting, in situ hybridization, and PCR. Image analyses of fluorescence immuno-stainings were used to quantify PTPIP51 in cultured myoblasts and myotubes. Myoblasts grown in the presence of epidermal and fibroblast growth factors (EGF and FGF), both promoting proliferation, expressed PTPIP51 on a basic level. Differentiation to multinuclear myotubes displayed a linear increase in PTPIP51 expression. The rise in PTPIP51 protein was paralleled by an augmented expression of muscle-specific proteins, namely, sarcoplasmic reticulum Ca2+ ATPase and myosin heavy-chain protein, both linked to a progressive state of myotubal differentiation. This differentiation-induced increase in PTPIP51 was partly reversible by resubmission of differentiated myotubes to conditions boosting proliferation. The results clearly point toward a strong association between PTPIP51 expression and differentiation in human muscle cells. (J Histochem Cytochem 57:425–435, 2009)