Faculty Bibliography

In vitro mechanical cell stimulators are used for the study of the effect of mechanical stimulation on anchorage-dependent cells. We developed a new mechanical cell stimulator, which uses stepper motor technology and computer control to achieve a high degree of accuracy and repeatability. This device also uses high-performance plastic components that have been shown to be noncytotoxic, dimensionally stable, and resistant to chemical degradation from common culture laboratory chemicals. We show that treatment with glow discharge for 25 s at 20 mA is sufficient to modify the surface of the rubber to allow proper adhesion for polymerization of aligned collagen. We show through finite element analysis that the middle area of the membrane, away from the clamped ends, is predictable, homogeneous, and has negligible shear strain. To test the efficacy of the mechanical stretch, we examined the effect of mechanical stimulation on the production of beta(1)-integrin by neonatal rat cardiac fibroblasts. Mechanical stimulation was tested in the range of 0-12% stretch and 0-10-cycles/min stretch frequency. The fibroblasts respond with an increase in beta(1)-integrin at 3% stretch and a decrease at 6 and 12% stretch. Stretch frequency was found to not significantly effect the concentration of beta(1)-integrin. These studies yield a new and improved mechanical cell stimulator and demonstrate that mechanical stimulation has an effect on the expression of beta(1)-integrin.

Dynamic interactions between cells and the extracellular matrix are essential in the regulation of a number of cellular processes including migration, adhesion, proliferation and differentiation. A variety of factors have been identified which modulate these interactions including transforming growth factor-beta, platelet-derived growth factor and others. Insulin-like growth factors have been shown to regulate collagen production by heart fibroblasts; however, the effects of this growth factor on the interactions of heart fibroblasts with the extracellular matrix have not been examined. The present studies were carried out to determine the effects of IGF-I on the ability of fibroblasts to interact with the extracellular matrix and to begin to determine the mechanisms of this response. These experiments illustrate that IGF-I treatment results in increased migration, collagen reorganization and gel contraction by heart fibroblasts. IGF-I has been shown to activate both the mitogen-activated protein kinase and phophatidylinositol-3 kinase pathways in isolated cells. Experiments with pharmacological antagonists of these pathways indicate that the mitogen-activated protein kinase pathway is essential for IGF-I stimulated collagen gel contraction by fibroblasts. These studies illustrate that IGF-I modulates the ability of fibroblasts to interact with the collagen matrix and that activation of multiple signaling pathways by IGF-I may produce distinct downstream responses in these cells.

The extracellular matrix (ECM) consists of a variety of components including collagens, glycoproteins, proteoglycans, proteases and growth factors/cytokines. Cells respond to these components using a variety of receptors. This article details the observations, supporting the hypothesis that cells have a dynamic interaction with the surrounding ECM. Alteration of the ECM is reflected in both cellular function and behavior.

We have examined how different degrees (0.5%, 1.0%, 2.5%, 5.0%, and 10.0%) and directions of stretch regulate the turnover and accumulation of contractile proteins in cultured neonatal cardiac myocytes (NCMs). In pulse-chase experiments, stellate-shaped NCMs with random arrays of myofibrils (MFs) exhibited a threshold response to stretch. With respect to unstretched controls, the turnover of the contractile protein pool was suppressed 50% to 100% in stellate NCMs stretched 1.0% to 5.0% and was unaltered in stellate NCMs stretched 0.5% or 10.0%. The posttranslational metabolism of myosin heavy chain (MHC) and actin was regulated in parallel with the total contractile protein pool. The turnover of the cytoplasmic protein pool remained unchanged in response to stretch. NCMs plated onto an aligned matrix of type I collagen expressed an elongated, rod-like cell shape. The MFs of these cells were distributed in parallel with one another along a single unique axis. The tissue-like pattern of organization of these cultures made it possible to assay how specific directions of stretch affected cardiac protein turnover and MF organization. In pulse-chase experiments, stretch in parallel with the MFs did not alter the turnover of the total contractile protein pool, the cytoplasmic protein pool, MHC, or actin. The total cellular concentration of MHC and actin remained constant, and MF alignment was not overtly affected. In contrast, even modest degrees of stretch across the short axis of the MFs suppressed total contractile protein turnover, the turnover of MHC and actin, and promoted the accumulation of these MF subunits. The parallel alignment of MFs deteriorated in myocytes stretched greater than 5%. The characteristic response of aligned myocytes to stretch was not affected by the contractile state of the cells. Isoproterenol (ISO) treatment in concert with stretch in parallel with the MFs modestly accelerated contractile protein turnover. Conversely, contractile protein turnover was suppressed in cells treated with ISO and stretched across the short axis of the MFs. Contractile arrest with nifedipine (NIFED) accelerated total myofibrillar protein turnover. Stretch across the short axis, but not in parallel with the MFs, suppressed protein turnover in cells treated with NIFED. The turnover of the cytosolic proteins remained constant under all conditions assayed. These data suggest that specific directions of stretch may play a crucial role in regulating MF organization and the metabolism of contractile proteins in the cardiac myocyte.

The formation and structure of the extracellular matrix (ECM) that makes up the cardiac interstitum is well known yet the underlying mechanisms that regulate the interstitum are poorly known. This review focuses on the role of the cardiac fibroblast in the formation and regulation of the ECM components during cardiac development and in response to physiological and pathological stimulation. The role of ECM receptors (integrins), cellular phenotype, and chemical and mechanical signaling by cardiac fibroblasts are discussed.

An elaborate series of morphogenetic events must be precisely coordinated during development to promote the formation of the elaborate three-dimensional structure of the normal heart. In this study we focus on discussing how interconnections between the cardiac myocyte and its surrounding environment regulate cardiac form and function. In vitro experiments from our laboratories provide direct evidence that cardiac cell shape is regulated by a dynamic interaction between constituents of the extracellular matrix (ECM) and by specific members of the integrin family of matrix receptors. Our data indicates that phenotypic information is stored in the tertiary structure and chemical identity of the ECM. This information appears to be actively communicated and transduced by the α1β1 integrin molecule into an intracellular signal that regulates cardiac cell shape and myofibrillar organization. In this study we have assessed the phenotypic consequences of suppressing the expression and accumulation of the α1 integrin molecule in aligned cultures of cardiac myocytes. In related experiments we have examined how the overexpression of α2 and α5 integrin, integrins normally not present or present at very low copy number on the cell surface of neonatal cardiac myocytes, affect cardiac protein metabolism. We also consider how biochemical signals and the mechanical signals mediated by the integrins may converge on common intracellular signaling pathways in the heart. Experiments with the whole embryo culture system indicate that angiotensin II, a peptide that carries information concerning cardiac load, plays a role in controling cardiac looping and the proliferation of myofibrils during development.

We previously reported on the value of fostering independence in first year medical students (MIs), and on the means we use to achieve this goal. A follow-up analysis has been completed on the use of computer programs (A.D.A.M.^R and Human Anatomy^R), and on the use of fourth year (MIV) medical students as teaching assistants. Dedicated computers were placed in the Anatomy lab five years ago, and use tracked at that time with self-reporting questionnaires. The findings show that the relatively low levels of use seen initially has stayed constant, with 48% of the class reporting using the programs once or never. We provide an introduction to the programs at the start of the course, but do not actively use the programs, or program modules, in our lectures; rather, the programs are there for students to use in addition to many other teaching aids (e.g., videos, models, bones, plastinated sections, radiograms). In rating all components of the course from most to least useful, students uniformly rated the atlases and cadaver dissections as most useful, followed by lectures and textbooks. Midrange in value were bones, models, and cross sections, while the computer programs, video dissections, and radiology presentations were ranked lowest. The MIVs were ranked below textbooks and lectures, but their "moral support" ranked as highly as 'help in lab' and help after hours (evenings and weekends). While it is difficult to assess how individual components of the course affect outcomes, it is clear from the MIs' self-reporting that direct contact with the anatomy (cadavers vs. two-dimensional pictures) and with teachers (MIVs vs. a program) is preferred and therefore more likely to have a positive impact on student learning.

Tropomodulin is a tropomyosin-binding protein that terminates "pointed-end" actin filament polymerization. To test the hypothesis that regulation of tropomodulin:actin filament stoichiometry is critical for maintenance of actin filament length, tropomodulin levels were altered in cells by infection with recombinant adenoviral expression vectors, which produce either sense or antisense tropomodulin mRNA. Neonatal rat cardiomyocytes were infected, and sarcomeric actin filament organization was examined. Confocal microscopy indicated that overexpression of tropomodulin protein shortened actin filaments and caused myofibril degeneration. In contrast, decreased tropomodulin content resulted in the formation of abnormally long actin filament bundles. Despite changes in myofibril structure caused by altered tropomodulin expression, total protein turnover of the cardiomyocytes was unaffected. Biochemical analyses of infected cardiomyocytes indicated that changes in actin distribution, rather than altered actin content, accounted for myofibril reorganization. Ultrastructural analysis showed thin-filament disarray and revealed the presence of leptomeres after tropomodulin overexpression. Tropomodulin-mediated effects constitute a novel mechanism to control actin filaments, and our findings demonstrate that regulated tropomodulin expression is necessary to maintain stabilized actin filament structures in cardiac muscle cells.