28 research outputs found
Vascular Smooth Muscle Cell Stiffness and Adhesion to Collagen I Modified by Vasoactive Agonists
In vascular smooth muscle cells (VSMCs) integrin-mediated adhesion to extracellular
matrix (ECM) proteins play important roles in sustaining vascular tone and resistance.
The main goal of this study was to determine whether VSMCs adhesion to type I collagen
(COL-I) was altered in parallel with the changes in the VSMCs contractile state induced by
vasoconstrictors and vasodilators. VSMCs were isolated from rat cremaster skeletal muscle
arterioles and maintained in primary culture without passage. Cell adhesion and cell E-modulus
were assessed using atomic force microscopy (AFM) by repetitive nano-indentation of
the AFM probe on the cell surface at 0.1 Hz sampling frequency and 3200 nm Z-piezo travelling
distance (approach and retraction). AFM probes were tipped with a 5 μm diameter
microbead functionalized with COL-I (1mg\ml). Results showed that the vasoconstrictor angiotensin
II (ANG-II; 10−6
) significantly increased (p<0.05) VSMC E-modulus and adhesion
probability to COL-I by approximately 35% and 33%, respectively. In contrast, the vasodilator
adenosine (ADO; 10−4
) significantly decreased (p<0.05) VSMC E-modulus and adhesion
probability by approximately −33% and −17%, respectively. Similarly, the NO donor
(PANOate, 10−6 M), a potent vasodilator, also significantly decreased (p<0.05) the VSMC
E-modulus and COL-I adhesion probability by −38% and −35%, respectively. These observations
support the hypothesis that integrin-mediated VSMC adhesion to the ECM protein
COL-I is dynamically regulated in parallel with VSMC contractile activation. These data suggest
that the signal transduction pathways modulating VSMC contractile activation and relaxation,
in addition to ECM adhesion, interact during regulation of contractile state
Cell motility: the integrating role of the plasma membrane
The plasma membrane is of central importance in the motility process. It defines the boundary separating the intracellular and extracellular environments, and mediates the interactions between a motile cell and its environment. Furthermore, the membrane serves as a dynamic platform for localization of various components which actively participate in all aspects of the motility process, including force generation, adhesion, signaling, and regulation. Membrane transport between internal membranes and the plasma membrane, and in particular polarized membrane transport, facilitates continuous reorganization of the plasma membrane and is thought to be involved in maintaining polarity and recycling of essential components in some motile cell types. Beyond its biochemical composition, the mechanical characteristics of the plasma membrane and, in particular, membrane tension are of central importance in cell motility; membrane tension affects the rates of all the processes which involve membrane deformation including edge extension, endocytosis, and exocytosis. Most importantly, the mechanical characteristics of the membrane and its biochemical composition are tightly intertwined; membrane tension and local curvature are largely determined by the biochemical composition of the membrane and the biochemical reactions taking place; at the same time, curvature and tension affect the localization of components and reaction rates. This review focuses on this dynamic interplay and the feedbacks between the biochemical and biophysical characteristics of the membrane and their effects on cell movement. New insight on these will be crucial for understanding the motility process
Determination of Membrane Protein Transporter Oligomerization in Native Tissue Using Spatial Fluorescence Intensity Fluctuation Analysis
Membrane transporter proteins exist in a complex dynamic equilibrium between various oligomeric states that include monomers, dimers, dimer of dimers and higher order oligomers. Given their sub-optical microscopic resolution size, the oligomerization state of membrane transporters is difficult to quantify without requiring tissue disruption and indirect biochemical methods. Here we present the application of a fluorescence measurement technique which combines fluorescence image moment analysis and spatial intensity distribution analysis (SpIDA) to determine the oligomerization state of membrane proteins in situ. As a model system we analyzed the oligomeric state(s) of the electrogenic sodium bicarbonate cotransporter NBCe1-A in cultured cells and in rat kidney. The approaches that we describe offer for the first time the ability to investigate the oligomeric state of membrane transporter proteins in their native state
Inhibition of phosphatidylinositol 3-kinase enhances mitogenic actions of insulin in endothelial cells RID C-1710-2011 RID B-1970-2008
The concept of “selective insulin resistance” has
emerged as a unifying hypothesis in attempts to reconcile
the influence of insulin resistance with that of hyperinsulinemia
in the pathogenesis of macrovascular
complications of diabetes. To explore this hypothesis in
endothelial cells, we designed a set of experiments to
mimic the “typical metabolic insulin resistance” by
blocking the phosphatidylinositol 3-kinase pathway and
exposing the cells to increasing concentrations of insulin
(“compensatory hyperinsulinemia”). Inhibition of
phosphatidylinositol 3-kinase with wortmannin blocked
the ability of insulin to stimulate increased expression
of endothelial nitric-oxide synthase, did not affect insulin-
induced activation of MAP kinase, and increased the
effects of insulin on prenylation of Ras and Rho proteins.
At the same time, this experimental paradigm resulted
in increased expression of vascular cellular adhesion
molecules-1 and E-selectin, as well as increased
rolling interactions of monocytes with endothelial cells.
We conclude that inhibition of the metabolic branch of
insulin signaling leads to an enhanced mitogenic action
of insulin in endothelial cells