Faculty Bibliography

beta-Catenin plays important roles in mammary development and tumorigenesis through its functions in cell adhesion, signal transduction and regulation of cell-context-specific gene expression. Studies in mice have highlighted the critical role of beta-catenin signaling for stem cell biology at multiple stages of mammary development. Deregulated beta-catenin signaling disturbs stem and progenitor cell dynamics and induces mammary tumors in mice. Recent data showing deregulated beta-catenin signaling in metaplastic and basal-type tumors suggest a similar link to reactivated developmental pathways and human breast cancer. The present review will discuss beta-catenin as a central transducer of numerous signaling pathways and its role in mammary development and breast cancer

The intercalated disk (ID) is a complex structure that electromechanically couples adjoining cardiac myocytes into a functional syncitium. The integrity of the disk is essential for normal cardiac function, but how the diverse elements are assembled into a fully integrated structure is not well understood. In this study, we examined the assembly of new IDs in primary cultures of adult rat cardiac myocytes. From 2 to 5 days after dissociation, the cells flatten and spread, establishing new cell-cell contacts in a manner that recapitulates the in vivo processes that occur during heart development and myocardial remodeling. As cells make contact with their neighbors, transmembrane adhesion proteins localize along the line of apposition, concentrating at the sites of membrane attachment of the terminal sarcomeres. Cx43 gap junctions and ankyrin-G, an essential cytoskeletal component of voltage gated sodium channel complexes, were secondarily recruited to membrane domains involved in cell-cell contacts. The consistent order of the assembly process suggests that there are specific scaffolding requirements for integration of the mechanical and electrochemical elements of the disk. Defining the relationships that are the foundation of disk assembly has important implications for understanding the mechanical dysfunction and cardiac arrhythmias that accompany alterations of ID architecture

A recent study presents a technique allowing one to image transcription from a single gene copy in live cells, and highlights the dynamic nature of transcriptional regulation.

Membrane proteins are critical to cell physiology, playing roles in signaling, trafficking, transport, adhesion, and recognition. Despite their relative abundance in the proteome and their prevalence as targets of therapeutic drugs, structural information about membrane proteins is in short supply. This chapter describes the use of electron crystallography as a tool for determining membrane protein structures. Electron crystallography offers distinct advantages relative to the alternatives of X-ray crystallography and NMR spectroscopy. Namely, membrane proteins are placed in their native membranous environment, which is likely to favor a native conformation and allow changes in conformation in response to physiological ligands. Nevertheless, there are significant logistical challenges in finding appropriate conditions for inducing membrane proteins to form two-dimensional arrays within the membrane and in using electron cryo-microscopy to collect the data required for structure determination. A number of developments are described for high-throughput screening of crystallization trials and for automated imaging of crystals with the electron microscope. These tools are critical for exploring the necessary range of factors governing the crystallization process. There have also been recent software developments to facilitate the process of structure determination. However, further innovations in the algorithms used for processing images and electron diffraction are necessary to improve throughput and to make electron crystallography truly viable as a method for determining atomic structures of membrane proteins.

Zebrafish has emerged in the past 5 years as a model for the study of sleep and wake behaviors. Experimental evidence has shown that periods of behavioral quiescence in zebrafish larvae and adults are sleep-like states, as these rest bouts are regulated by the circadian cycle, are associated with decreases in arousal, and are increased following rest deprivation. Furthermore, zebrafish share with mammals a hypocretin/orexin system that promotes wakefulness, and drugs that alter mammalian sleep have similar effects on zebrafish rest. In this chapter, we review the zebrafish sleep literature and describe a long-term, high-throughput monitoring system for observing sleep and wake behaviors in larval zebrafish.

Patients from the Indian subcontinent have a distinct cardiovascular risk profile with profound health consequences. South Asians tend to develop more severe coronary artery disease at a younger age, and may also suffer from earlier myocardial infarction and heart failure. The genesis of this risk is multi-factorial. One important culprit is increased insulin resistance, possibly due to recently identified genetic polymorphisms. Another possible explanation is subclinical inflammation and a prothrombotic environment, as evidenced by increased levels of homocysteine, plasminogen activator inhibitor-1, and fibrinogen. The lipid profile of South Asians may play a role, as this population is known to have elevated levels of lipoprotein (a), as well as lower levels of HDL. In addition, this HDL may be dysfunctional, as this population may have a higher prevalence of low levels of HDL2b, as well as an increased preponderance of smaller HDL. Current guidelines for primary and secondary prevention have not reflected our growing insight into the unique characteristics of the South Asian population, and may need to evolve to reflect our knowledge

Purpose: Survival of bone implants depends on biological fixation, and prosthesis loosening can be catastrophic leading to replacement of prostheses. Inflammation and osteoclast-mediated bone resorption in response to wear particles near prostheses contribute to loosening. Because we have demonstrated that adenosine A_2Areceptor activation is anti-inflammatory and prevents osteoclast formation and function we hypothesized that adenosine A_2Areceptor agonists might prevent osteoclast-mediated bone resorption at the site of prosthesis wear in a calvarial model of wear particle-induced bone resorption. Methods: Eighteen C57Bl/6 mice age 6-8 weeks were anesthetized by intraperitoneal injection of ketamine and xylazine and a 1cm midline sagittal incision was made over the calvarium anterior to the line connecting both ears. Six animals received no particles (control), and 12 received 15 ml of polyethylene particle suspension. Of the 12 mice receiving particulate, 6 were injected subcutaneously at the surgical site with 20 ml of 10 muM CGS21680 (A_2Areceptor agonist), and 6 mice were injected with saline 0.9%, beginning immediately after incision closure and continuing every other day until sacrifice. Animals were sacrificed after 14 days and the calvaria were removed, fixed, and prepared for microCT and histological staining with TRAP. Results: Histologic examination of calvaria demonstrated lymphocytic infiltration in both particle-exposed groups. TRAP staining revealed a reduction in osteoclast differentiation after treatment with CGS21680. mCT showed pitting and increased porosity in both particle-exposed groups compared to controls, although in CGS21680-treated mice the reduction in cortical bone was significantly less than in the untreated particle-exposed mice (p<0.01). Control bone volume/trabecular volume was significantly greater (p<0.005) than in either particulate group, however, calvarial bone from CGS21680-treated mice had significantly greater mean bone volume than did the untreated group (p<0.0005). Trabecular thickness was significantly reduced in both CGS21680-treated and untreated particle-exposed groups as compared to control mice (p<0.05). Finally, digital morphometric analysis of microCTs reveals that CGS21680 significantly reduced the area of bone pitting compared to control particle-treated mice (p<0.05). (Table presented) Conclusions: Adenosine A_2Areceptor activation reduces inflammation and bone destruction due to prosthetic wear particles. This observation suggests that delivery of an adenosine A_2Aagonist in the cement may enhance orthopedic implant survival, delaying or eliminating the need for revision arthroplasty surgery

Purpose: Organ injury induced by antibodies characteristic of Sjogren Syndrome and Systemic Lupus Erythematosus, while varied in the adult and fetus, may share in common a link between apoptosis and ultimate fibrosis. In congenital heart block (CHB), binding of maternal anti-Ro/La antibodies to apoptotic cardiocytes impairs their removal by healthy cardiocytes and increases uPA/uPAR-dependent plasmin activation. Immunological staining of CHB hearts reveals AV node TGFb staining and TGFb activation promotes fibroblast trans-differentiation, a scarring phenotype. Since the uPA/uPAR system plays a role in TGFb activation, this study evaluated whether anti-Ro/La binding to apoptotic cardiocytes via plasmin activation stimulates TGFb and promotes a profibrosing phenotype. Methods and Results: Initial analysis showed increased TGFb in supernatants from co-cultures of healthy cards and apoptotic cards incubated with IgG fractions from mothers whose sera contain anti-Ro/La antibodies and who had a child with CHB (apo-CHB-IgG) compared to co-cultures of healthy cards and apoptotic cards incubated with control IgG (apo-nl-IgG). Using a luciferase bioassay of active TGFb, supernatants from co-cultures of healthy cards and apo-CHB-IgG cards exhibited increased levels of active TGFb compared to those cocultured with apo-nl-IgG cards (511pg/ml CHB-IgG RLU vs 217 nl-IgG RLU; p=0.007; n=7). Abrogation of RLU via anti-TGFb antibody or TGFb inhibitor (SB431542) confirmed TGFb activation was solely due to TGFb. Significantly increased uPA levels (903 pg/ml vs 508 pg/ml; p =0.01; n=5) and uPA activity (0.8 units vs 0.04 units; p=0.005; n=3) were demonstrated in supernatants generated from coculture of healthy cards and apo CHB-IgG cards compared to healthy cards and apo nl-IgG, respectively. To determine whether uPA activity was responsible for TGFb activation, coculture experiments were conducted in which the apo-CHB-IgG cards were treated with anti-uPAR or anti-uPA antibodies or the plasmin inhibitor aprotinin prior to coculturing with healthy cards. In all instances treatments attenuated TGFb activation and uPA activity. To evaluate the profibrotic role of the observed TGFb activation, supernatants from either apo-CHB-IgG or apo-nl-IgG cocultures with healthy cards were applied to serum deprived cardiac fibroblasts. Only supernatants derived from cocultures of healthy cards and apo-CHB-IgG cardiocytes promoted transdifferentiation as evidenced by increased SMAc staining, an effect that was decreased when fibroblasts were treated with supernatants where cocultures were pretreated with uPAR antibodies. Supporting the hypothesis that increased uPA activity is causally related to the pathogenesis of CHB, cord blood samples from 12 of 18 children with CHB exhibited increased uPA activity and uPAR cleavage compared to 4 of 14 non CHB children exposed to maternal anti-Ro antibodies. Conclusions: These data suggest that binding of anti-Ro/La antibodies to apoptotic cardiocytes by virtue of increased uPAR-dependent uPA activity trigger TGFb activation thus initiating and amplifying a cascade of events that promote myofibroblast transdifferentiation and scar

It is known that apolipoprotein E (ApoE) is essential for normal lipid metabolism. ApoE is the major apolipoprotein in the central nervous system and plays a key role in neurobiology by mediating the transport of cholesterol, phospholipids, and sulfatides. We therefore examined APOE epsilon2, epsilon3, and epsilon4 knock-in mice, using electrospray ionization mass spectrometry to determine if APOE genotype or age leads to altered levels in the brain of a number of glycerophospholipids (phosphatidylinositol, PI; phosphatidylethanolamine, PE; phosphatidic acid, PA, phosphatidylserine, PS; phosphatidylcholine, PC), sphingolipids (sphingomyelin, SM; ceramide, Cer), cholesterol, and triacylglycerols. We observed slight changes within individual PI, PE, PC, Cer, and SM lipid levels in APOE epsilon2 and epsilon4 mice compared to APOE epsilon3 mice. However, overall, we did not observe any major effects in APOE epsilon4 knock-in mice for the levels of the glycerophospholipids measured, as compared to APOE epsilon2 and epsilon3 mice. Our findings indicate that variations in ApoE isoforms do not per se affect bulk lipid homeostasis in the brain. These findings indicate that APOE epsilon4 is not associated with disturbances in brain sterol or sphingolipids in the absence of environmental factors