William L. Joyner

Resting Distribution and Stimulated Translocation of Protein Kinase C Isoforms Alpha, Epsilon and Zeta in Response to Bradykinin and TNF in Human Endothelial Cells

Protein kinase C (PKC) has been linked to functional and morphological changes in endothelial cells involved in increased microvessel permeability. Bradykinin and TNF are potent inflammatory mediators which translocate PKC from the cytosol to the membrane of various cell types, including endothelial cells. The PKC isoforms alpha, epsilon and zeta have been demonstrated as the most prominent in human umbilical vein endothelial cells (HUVEC). We propose that bradykinin and TNF cause increased microvascular permeability via a PKC-dependent endothelial cell signalling pathway. HUVEC were incubated at 37 degrees C and 5% CO2 for 1 min, 15 min and 3 h with either bradykinin (1 microM) or TNF (100 U/ml). PMA incubation served as a positive control (100 nM, 15 min). Cytosolic and membrane-bound extracts were obtained by incubation in digitonin (0.5%) and Triton X100 (1%). PKC isoforms were assayed by Western blot and membrane fractions calculated. These experiments revealed that: HUVEC clearly displayed a non-uniform basal membrane fraction distribution of PKC isoforms, with zeta (35.4%) greater than epsilon (30.6%) and both much greater than alpha (8.6%); Bradykinin caused significant translocation of PKC alpha with 15 min and 3 h of treatment but not 1 min; TNF caused dramatic translocation of PKC alpha at 1 min treatment which subsided at 15 min and 3 h but remained significantly elevated; and PMA caused dramatic translocation of alpha and epsilon but not zeta. Treatments of bradykinin and TNF that translocated PKC also showed cytoskeletal rearrangement of rhodamine-phalloidin stained actin, causing it to become more prevalent near cell membranes and concentrated at focal points between cells. These results suggest that PKC alpha may contribute to long term low grade increases in microvessel permeability in response to bradykinin, and that PKC alpha could be involved in both transient and sustained microvessel permeability changes induced by TNF. Also, cytoskeletal actin organization appears to be a downstream pathway in the activation process, possibly leading to alteration in endothelial cell shape and contact points.

Differential role of endothelial function on vasodilator responses in series-arranged arterioles

Both in vitro and in vivo studies have revealed that removal of vascular endothelial cells abolishes the vasodilation to acetylcholine (Ach) but not sodium nitroprusside (SNP). Differential properties of endothelial cells in the series-arranged arterioles to vasodilator responses have not been studied. In this study, the cheek pouch microcirculation from the golden syrian hamster anesthetized with sodium pentobarbital (6 mg/100 g body wt, ip) was prepared for intravital microscopy. Measurements of lumen diameters of small series-arranged arterioles (2nd- and 4th-order) were made before, during, and after topical microapplication of different doses of either Ach or SNP. After control measurements, a light-dye (L-D) technique utilizing sodium fluorescein (FITC-dextran(150K), 50 mg/100 g body wt, iv) and illuminating a discrete area of the arteriole with 490-nm-wavelength light for 3 (4th) or 10 (2nd) min was used to impair endothelial cell function without damaging vascular smooth muscle cells. Responses to vasoactive substances for both 4th-order (10-20 microns) and second-order (30-50 microns) arterioles were retested. Vasodilatory responses to 10(-7) M Ach and SNP also were tested with and without the presence of NG-monomethyl L-arginine (L-NMMA), an inhibitor of EDRF/NO formation. In the control state, Ach and SNP produced a focal, dose-dependent increase in diameter in all arterioles tested. Endothelial impairment by L-D treatment significantly suppressed the vasodilator response to Ach in 4th- but not 2nd-order arterioles, whereas the SNP response was not significantly affected. Consistent with these observations, L-NMMA treatment significantly attenuated Ach-induced vasodilation in 4th-order arterioles, but it had no effect on 2nd-order arterioles. These studies document further the role of the endothelium in local modulation of arteriolar diameter in response to acetylcholine and demonstrate a differential effect for this response in series-arranged microvessels. Thus, there may be a heterogeneous distribution of endothelial cell functions for modulating vasodilator activity in microvessels.

Angiotensin II binding sites in the hamster brain: localization and subtype distribution.

This study was designed to characterize the distribution of angiotensin II (AII) binding sites in the hamster brain. Brain sections were incubated with [125I][sar1,ile8]-angiotensin II in the absence and presence of angiotensin II receptor subtype selective compounds, losartan (AT1 subtype) and PD123177 (AT2 subtype). Binding was quantified by densitometric analysis of autoradiograms and localized by comparison with adjacent thionein stained sections. The distribution of AII binding sites was similar to that found in the rat, with some exceptions. [125I][sar1,ile8]-angiotensin II binding was not evident in the subthalamic nucleus and thalamic regions, inferior olive, suprachiasmatic nucleus, and piriform cortex of the hamster, regions of prominent binding in the rat brain. However, intense binding was observed in the interpeduncular nucleus and the medial habenula of the hamster, nuclei void of binding in the rat brain. Competition with receptor subtype selective compounds revealed a similar AII receptor subtype profile in brain regions where binding is evident in both species. One notable exception is the medial geniculate nucleus, predominately AT1 binding sites in the hamster but AT2 in the rat. Generally, the AII binding site distribution in the hamster brain parallels that of the other species studied, particularly in brain regions associated with cardiovascular and dipsogenic functions. Functional correlates for AII binding sites have not been elucidated in the majority of brain regions and species mismatches might provide clues in this regard.

Osteopontin stimulates apoptosis in adult cardiac myocytes via the involvement of CD44 receptors, mitochondrial death pathway, and endoplasmic reticulum stress

Increased osteopontin (OPN) expression associates with increased myocyte apoptosis and myocardial dysfunction. The objective of this study was to identify the receptor for OPN and get insight into the mechanism by which OPN induces cardiac myocyte apoptosis. Adult rat ventricular myocytes (ARVMs) and transgenic mice expressing OPN in a myocyte-specific manner were used for in vitro and in vivo studies. Treatment with purified OPN (20 nM) protein or adenoviral-mediated OPN expression induced apoptosis in ARVMs. OPN co-immunoprecipitated with CD44 receptors, not with β1 or β3 integrins. Proximity ligation assay confirmed interaction of OPN with CD44 receptors. Neutralizing anti-CD44 antibodies inhibited OPN-stimulated apoptosis. OPN activated JNKs and increased expression of Bax and levels of cytosolic cytochrome c, suggesting involvement of mitochondrial death pathway. OPN increased endoplasmic reticulum (ER) stress, as evidenced by increased expression of Gadd153 and activation of caspase-12. Inhibition of JNKs using SP600125 or ER stress using salubrinal or caspase-12 inhibitor significantly reduced OPN-stimulated apoptosis. Expression of OPN in adult mouse heart in myocyte-specific manner associated with decreased left ventricular function and increased myocyte apoptosis. In the heart, OPN expression increased JNKs and caspase-12 activities, and expression of Bax and Gadd153. Thus, OPN, acting via CD44 receptors, induces apoptosis in myocytes via the involvement of mitochondrial death pathway and ER stress.

Extracellular Ubiquitin Increases Expression of Angiogenic Molecules and Stimulates Angiogenesis in Cardiac Microvascular Endothelial Cells

Extracellular Ub is an immune modulator that plays a role in suppression of inflammation, organ injury, myocyte apoptosis, and fibrosis. The purpose of this study was to investigate the effects of extracellular Ub on the process of cardiac angiogenesis. CMECs and aortic tissue were isolated from rats to measure changes in angiogenic protein levels and to assess angiogenic responses to extracellular Ub. In CMECs, extracellular Ub increased protein levels of VEGF‐A and MMP‐2, known angiogenesis regulators. CMECs demonstrated enhanced rearrangement of fibrillar actin and migration in response to Ub treatment. Ub‐treated CMECs demonstrated an increase in tube network formation which was inhibited by the CXCR4 receptor antagonist, AMD3100. Methylated Ub, unable to form polyubiquitin chains, enhanced tube network formation. Aortic ring sprouting assays demonstrated that Ub increases microvessel sprouting in the Matrigel. The results of our study suggest a novel role for extracellular Ub in cardiac angiogenesis, providing evidence that extracellular Ub, at least in part acting via the CXCR4 receptor, has the potential to facilitate the process of angiogenesis in myocardial endothelial cells.

Microvascular permeability to macromolecules and its dynamic modulation

Abstract This article presents current aspects of transvascular exchange for solutes and water in the microcirculation. Also discussed are various concepts concerning the modulation of the barrier in inflammatory-like states, as well as information describing the receptor-operated channels in endothelial cells and their processing.

Exogenous ubiquitin modulates chronic β-adrenergic receptor-stimulated myocardial remodeling: role in Akt activity and matrix metalloproteinase expression.

β-Adrenergic receptor (β-AR) stimulation increases extracellular ubiquitin (UB) levels, and extracellular UB inhibits β-AR-stimulated apoptosis in adult cardiac myocytes. This study investigates the role of exogenous UB in chronic β-AR-stimulated myocardial remodeling. l-Isoproterenol (ISO; 400 μg·kg(-1)·h(-1)) was infused in mice in the presence or absence of UB (1 μg·g(-1)·h(-1)). Left ventricular (LV) structural and functional remodeling was studied 7 days after infusion. UB infusion enhanced serum UB levels. In most parts, UB alone had no effect on morphometric or functional parameters. Heart weight-to-body weight ratios were increased to a similar extent in the ISO and UB + ISO groups. Echocardiographic analyses showed increased percent fractional shortening, ejection fraction, and LV circumferential stress and fiber-shortening velocity in the ISO group. These parameters were significantly lower in UB + ISO vs. ISO. Isovolumic contraction and relaxation times and ejection time were significantly lower in ISO vs. UB + ISO. The increase in the number of TUNEL-positive myocytes and fibrosis was significantly higher in ISO vs. UB + ISO. Activation of Akt was higher, whereas activation of GSK-3β and JNKs was lower in UB + ISO vs ISO. Expression of MMP-2, MMP-9, and TIMP-2 was higher in UB + ISO vs ISO. In isolated cardiac fibroblasts, UB enhanced expression of MMP-2 and TIMP-2 in the presence of ISO. Neutralizing UB antibodies negated the effects of UB on MMP-2 expression, whereas recombinant UB enhanced MMP-2 expression. UB activated Akt, and inhibition of Akt inhibited UB + ISO-mediated increases in MMP-2 expression. Thus, exogenous UB plays an important role in β-AR-stimulated myocardial remodeling with effects on LV function, fibrosis, and myocyte apoptosis.

Heterogeneity of Endothelial Cell Function for Angiotensin Conversion in Serial-Arranged Arterioles

The involvement of the endothelial cell in the vasoconstriction induced by angiotensin I and II (AI, AII), and norepinephrine (NE) was studied in microvessels of the hamster cheek pouch before and after the following procedures: endothelial impairment by light-dye treatment, inhibition of angiotensin-converting enzyme (ACE), blockade of endothelium-derived relaxing factor (EDRF) and inhibiting prostaglandin (PG) synthesis. The results showed that in large 2nd-order arterioles, endothelial impairment did not affect the vasoconstrictor activity of AII and NE, nor did it alter ACE activity. However, in small 4th-order arterioles, endothelial impairment significantly reduced angiotensin conversion without altering the vasoconstrictor responses to either AII or NE. Thus, the endothelium plays differential roles in the modulation of local angiotensin conversion in these distinct segments of serial-arranged arterioles. Furthermore, it is unlikely that the vasoconstrictor response to AII in these arterioles is modulated by the endothelium through a pathway involving the release of EDRF or PGs.