Heterogeneity of microvascular pericytes for smooth muscle type alpha- actin

Microvascular pericytes are believed to be involved in various functions such as regulation of capillary blood flow and endothelial proliferation. Since pericytes represent a morphologically heterogeneous cell population ranging from circular smooth musclelike to elongated fibroblast-like morphology it is possible that regulation of blood flow (via contractility) and control of endothelial proliferation (as well as other metabolic functions) may be accomplished by different subsets of pericytes. In the present study we provide evidence for heterogeneity of pericytes at the molecular level by using two novel technical approaches. These are (a) immunostaining of whole mounts of the microvascular beds of the rat mesentery and bovine retina and (b) immunoblotting studies of microdissected retinal microvessels. We show that pericytes of true capillaries (midcapillaries) apparently lack the smooth muscle isoform of alpha-actin whereas transitional pericytes of pre- and postcapillary microvascular segments do express this isoform. Thus, regulation of capillary blood flow may be accomplished by the smooth muscle-related pre- and postcapillary pericytes whereas the nonmuscle pericytes of true capillaries may play a role in other functions.     

Functional diversity of FGF-2 isoforms by intracellular sorting

Regulation of the subcellular localization of certain proteins is a mechanism for the regulation of their biological activities. FGF-2 can be produced as distinct isoforms by alternative initiation of translation on a single mRNA and the isoforms are differently sorted in cells. High molecular weight FGF-2 isoforms are not secreted from the cell, but are transported to the nucleus where they regulate cell growth or behavior in an intracrine fashion. 18 kDa FGF-2 can be secreted to the extracellular medium where it acts as a conventional growth factor by binding to and activation of cell-surface receptors. Furthermore, following receptor-mediated endocytosis, the exogenous FGF-2 can be transported to the nuclei of target cells, and this is of importance for the transmittance of a mitogenic signal. The growth factor is able to interact with several intracellular proteins. Here, the mode of action and biological role of intracellular FGF-2 are discussed.     

Palmitate-induced apoptosis of microvascular endothelial cells and pericytes

BACKGROUND: Recent observations in the EURODIAB Complications Study demonstrated that markers of insulin resistance are strong risk factors for retinopathy incidence in patients with diabetes. However, the molecular mechanism underlying this remains to be elucidated. In this study, we investigated the influence of palmitate, a major saturated free fatty acid in plasma, on the apoptotic cell death of cultured microvascular endothelial cells (EC) and retinal pericytes. MATERIALS AND METHODS: The intracellular formation of reactive oxygen species (ROS) was detected using the fluorescent probe CM-H(2)DCFDA. DNA synthesis was determined by measuring [(3) H]-thymidine incorporation into cells. DNA fragmentations of EC were quantitatively analyzed in an enzyme-linked immunosorbent assay, and DNA laddering was evaluated on agarose gel electrophoresis. RESULTS: Palmitate increased ROS generation in microvascular EC. Furthermore, palmitate significantly inhibited DNA synthesis and induced apoptotic cell death in EC, which were completely prevented by an antioxidant, N-acetylcysteine. Palmitate up-regulated pericyte mRNA levels of a receptor for advanced glycation end products (AGE), and thereby potentiated the apoptotic effects of AGE on pericytes. CONCLUSIONS: The results suggest that palmitate could induce apoptotic cell death in microvascular EC and pericytes through the overgeneration of intracellular ROS, and thus be involved in the development of diabetic retinopathy.     

In situ analysis of microvascular pericytes in hypertensive rat brains

We used immunofluorescence microscopy and isoactin-specific antibodies to characterize the pattern and prevalence of pericytes within the brain microcirculation. Blood pressures of normotensive, Wistar-Kyoto (WKY) and spontaneously hypertensive (SHR) rats were measured prior to sacrifice and pressure-perfusion fixation. WKY and SHR brains were subdivided into ten major regions prior to ultracryomicrotomy. Sections 0.3-0.5 micron wide were treated with 10-40 micrograms/ml affinity-purified antibodies to the muscle and non-muscle actin isoforms. These localization studies show that there are four times the number of pericyte-rich capillaries in the SHR motor cortex compared to WKY counterparts (59.9 vs. 15.3%). In contrast, the sensory cortex of both rat strains is deficient in muscle actin staining surrounding the capillaries. The most striking difference in pericyte presence and muscle actin antibody staining between the SHR and WKY was observed in the tegmentum of the brainstem. There is nearly a one-to-one coincidence observed in pericyte and capillary profiles present within thin, frozen sections of the SHR midbrain. SHR pons capillaries were also pericyte-enriched. WKY analyses of plastic embedded thin sections confirmed the presence of pericytes and their filament-enriched processes encircling the capillaries of the hypertensive brains. These results suggest that pericytes may play important roles in hypertension and cerebrovascular disease processes.     

Mechanisms of spatial segregation of actin isoforms

Actin sequences are conserved to a much greater degree than those in almost any other proteins, so that two cytoplasmic isoforms differ by only four of 374 amino acid residues. Nevertheless, the results of biochemical, immunocytochemical and molecular biology experiments demonstrate that appearance, amount and localization of actin isoforms are strongly controlled by cell machinery. Although at the early stages of cell differentiation expression of any actin gene is potentially possible, under normal physiological conditions, while differentiation proceeds, synthesis of specific actin isoforms is temporally regulated and the produced proteins are segregated spatially. Pathological situations of tissue injury or mammalian disease correlate either with up- and down-regulation of distinct actin genes returning to a fetal gene program or with a failure to sort actin isoforms. Different actin isoforms cannot substitute for each other, and changes in expression of specific actin genes are accompanied by alterations in cell structure and function suggesting that specific actin isoforms perform unique cellular functions. This article summarizes the data on segregation of actin isoforms in cell compartments and analyses the mechanisms suggested to explain spatial segregation of cytoplasmic actin isoforms within a cell.     

Mechanisms of spatial segregation of actin isoforms

Actin sequences are conserved to a much greater degree than those of almost any other proteins, such that two cytoplasmic isoforms differ by only 4 out of 374 amino acid residues. Nevertheless, the results of biochemical, immunocytochemical, and molecular biology experiments demonstrate that the appearance, amount, and localization of actin isoforms are strongly controlled by the cellular machinery. Although at the early stages of cell differentiation expression of any actin gene is potentially possible, under normal physiological conditions, while differentiation proceeds, synthesis of specific actin isoforms is temporally regulated and the produced proteins are segregated spatially. Pathological situations of a tissue injury or a mammalian disease correlate either with up-and down-regulation of distinct actin genes returning to a fetal gene program or with a failure to sort actin isoforms. Different actin isoforms cannot substitute for each other, and changes in the expression of specific actin genes are accompanied by alterations in cell structure and function, suggesting that specific actin isoforms perform unique cellular functions. This article summarizes the data on the segregation of actin isoforms in cell compartments and analyzes the mechanisms suggested to explain spatial segregation of cytoplasmic actin isoforms in the cell.     

The functional importance of multiple actin isoforms

Actin is a protein that plays an important role in cell structure, cell motility, and the generation of contractile force in both muscle and nonmuscle cells. In many organisms, multiple forms of actin, or isoactins, are found. These are products of different genes and have different, although very similar, amino acid sequences. Furthermore, these isoactins are expressed in a tissue specific fashion that is conserved across species, suggesting that their presence is functionally important and their behavior can be distinguished quantitatively from one another in vitro. In muscle cells, they are differentially distributed within the cell and some are specifically associated with structures such as costameres, mitochondria, and neuromuscular junctions. There is also good evidence for specific isoactin function in microvascular pericytes and in the intestinal brush border. However, the necessity of specific isoactins for various functions has not yet been conclusively demonstrated.     

Differential arginylation of actin isoforms: the mystery of the actin N-terminus

Actin is one of the most abundant, essential and well studied intracellular proteins, yet its regulation in vivo is still not completely understood. One of the mysteries around actin concerns the existence of multiple actin isoforms that are extremely similar to each other except for their N-termini but have been shown in multiple studies to preferentially incorporate into different actin networks and are suggested to have different roles in vivo. The mechanisms of this actin isoform segregation are unknown. My colleagues and I recently showed that beta but not gamma actin in cultured fibroblasts undergoes N-terminal arginylation, which regulates actin polymerization and lamella formation in motile cells. Here, I propose that arginylation could be a general mechanism that regulates actin isoform segregation in vivo and participates in the formation of loose beta-actin network at the leading edge of the cell.     

Expression of actin isoforms in developing rat intestinal epithelium

A minimum of six very similar but distinct actin isoforms are encoded by the mammalian genome. Developmental regulation of these genes results in a tissue-specific distribution of the isoforms in the adult. Using a panel of actin specific monoclonal antibodies (MAb), we recently reported the expression of two unique actin isoforms in adult rat intestinal brush border. In this report, we examine the developmental expression of these and other actin isoforms in rat intestinal epithelial cells. Isoforms containing the HUC 1-1 and/or C4 epitopes are present by day 15 of gestation and are continuously expressed throughout adult life. Unexpectedly, the gamma-enteric smooth muscle isoactin, defined by the B4 epitope, is transiently expressed in these non-muscle cells late in gestation. The alpha-vascular smooth muscle isoform, however, is not expressed in intestinal epithelial cells during development and, as previously reported, both smooth muscle isoforms are absent in epithelial cells of adult intestine. In addition, we demonstrate that although multiple isoforms are expressed simultaneously in these cells, they are not uniformly distributed at the subcellular level, suggesting that the cell recognizes the actin isoforms as functionally distinct entities.     

Syndapin isoforms participate in receptor-mediated endocytosis and actin organization

Syndapin I (SdpI) interacts with proteins involved in endocytosis and actin dynamics and was therefore proposed to be a molecular link between the machineries for synaptic vesicle recycling and cytoskeletal organization. We here report the identification and characterization of SdpII, a ubiquitously expressed isoform of the brain-specific SdpI. Certain splice variants of rat SdpII in other species were named FAP52 and PACSIN 2. SdpII binds dynamin I, synaptojanin, synapsin I, and the neural Wiskott-Aldrich syndrome protein (N-WASP), a stimulator of Arp2/3 induced actin filament nucleation. In neuroendocrine cells, SdpII colocalizes with dynamin, consistent with a role for syndapin in dynamin-mediated endocytic processes. The src homology 3 (SH3) domain of SdpI and -II inhibited receptor-mediated internalization of transferrin, demonstrating syndapin involvement in endocytosis in vivo. Overexpression of full-length syndapins, but not the NH(2)-terminal part or the SH3 domains alone, had a strong effect on cortical actin organization and induced filopodia. This syndapin overexpression phenotype appears to be mediated by the Arp2/3 complex at the cell periphery because it was completely suppressed by coexpression of a cytosolic COOH-terminal fragment of N-WASP. Consistent with a role in actin dynamics, syndapins localized to sites of high actin turnover, such as filopodia tips and lamellipodia. Our results strongly suggest that syndapins link endocytosis and actin dynamics.     

Tropomyosin and actin isoforms modulate the localization of tropomyosin strands on actin filaments

Tropomyosin is present in virtually all eucaryotic cells, where it functions to modulate actin-myosin interaction and to stabilize actin filament structure. In striated muscle, tropomyosin regulates contractility by sterically blocking myosin-binding sites on actin in the relaxed state. On activation, tropomyosin moves away from these sites in two steps, one induced by Ca(2+) binding to troponin and a second by the binding of myosin to actin. In smooth muscle and non-muscle cells, where troponin is absent, the precise role and structural dynamics of tropomyosin on actin are poorly understood. Here, the location of tropomyosin on F-actin filaments free of troponin and other actin-binding proteins was determined to better understand the structural basis of its functioning in muscle and non-muscle cells. Using electron microscopy and three-dimensional image reconstruction, the association of a diverse set of wild-type and mutant actin and tropomyosin isoforms, from both muscle and non-muscle sources, was investigated. Tropomyosin position on actin appeared to be defined by two sets of binding interactions and tropomyosin localized on either the inner or the outer domain of actin, depending on the specific actin or tropomyosin isoform examined. Since these equilibrium positions depended on minor amino acid sequence differences among isoforms, we conclude that the energy barrier between thin filament states is small. Our results imply that, in striated muscles, troponin and myosin serve to stabilize tropomyosin in inhibitory and activating states, respectively. In addition, they are consistent with tropomyosin-dependent cooperative switching on and off of actomyosin-based motility. Finally, the locations of tropomyosin that we have determined suggest the possibility of significant competition between tropomyosin and other cellular actin-binding proteins. Based on these results, we present a general framework for tropomyosin modulation of motility and cytoskeletal modelling.     

Polarized distribution of actin isoforms in gastric parietal cells.

The actin genes encode several structurally similar, but perhaps functionally different, protein isoforms that mediate contractile function in muscle cells and determine the morphology and motility in nonmuscle cells. To reveal the isoform profile in the gastric monomeric actin pool, we purified actin from the cytosol of gastric epithelial cells by DNase I affinity chromatography followed by two-dimensional gel electrophoresis. Actin isoforms were identified by Western blotting with a monoclonal antibody against all actin isoforms and two isoform-specific antibodies against cytoplasmic beta-actin and gamma-actin. Densitometry revealed a ratio for beta-actin/gamma-actin that equaled 0.73 +/- 0.09 in the cytosol. To assess the distribution of actin isoforms in gastric glandular cells in relation to ezrin, a putative membrane-cytoskeleton linker, we carried out double immunofluorescence using actin-isoform-specific antibodies and ezrin antibody. Immunostaining confirmed that ezrin resides mainly in canaliculi and apical plasma membrane of parietal cells. Staining for the beta-actin isoform was intense along the entire gland lumen and within the canaliculi of parietal cells, thus predominantly near the apical membrane of all gastric epithelial cells, although lower levels of beta-actin were also identified near the basolateral membrane. The gamma-actin isoform was distributed heavily near the basolateral membrane of parietal cells, with much less intense staining of parietal cell canaliculi and no staining of apical membranes. Within parietal cells, the cellular localization of beta-actin, but not gamma-actin, isoform superimposed onto that of ezrin. In a search for a possible selective interaction between actin isoforms and ezrin, we carried out immunoprecipitation experiments on gastric membrane extracts in which substantial amounts of actin were co-eluted with ezrin from an anti-ezrin affinity column. The ratio of beta-actin/gamma-actin in the immunoprecipitate (beta/gamma = 2.14 +/- 0.32) was significantly greater than that found in the cytosolic fraction. In summary, we have shown that beta- and gamma-actin isoforms are differentially distributed in gastric parietal cells. Furthermore, our data suggest a preferential, but not exclusive, interaction between beta-actin and ezrin in gastric parietal cells. Finally, our results suggest that the beta- and gamma-actin-based cytoskeleton networks might function separately in response to the stimulation of acid secretion.     

Functional design in the actin cytoskeleton

Changes in cell shape, anchorage and motility are all associated with the dynamic reorganisation of the architectural arrays of actin filaments that make up the actin cytoskeleton. The relative expression of these functionally different actin filament arrays is intimately linked to the pattern of contacts that a cell develops with its extracellular substrate. Cell polarity is acquired by the development of an asymmetric pattern of substrate contacts, effected in a specific, site-directed manner by the delivery of adhesion-site modulators along microtubules.     

The role of actin isoforms in somatic embryogenesis in Norway spruce

Background  

Somatic embryogenesis in spruce is a process of high importance for biotechnology, yet it comprises of orchestrated series of events whose cellular and molecular details are not well understood. In this study, we examined the role of actin cytoskeleton during somatic embryogenesis in Norway spruce line AFO 541 by means of anti-actin drugs.     

How calcium signals in myocytes and pericytes are integrated across in situ microvascular networks and control microvascular tone

The microcirculation is the site of gas and nutrient exchange. Control of central or local signals acting on the myocytes, pericytes and endothelial cells within it, is essential for health. Due to technical problems of accessibility, the mechanisms controlling Ca²⁺ signalling and contractility of myocytes and pericytes in different sections of microvascular networks in situ have not been investigated. We aimed to investigate Ca²⁺ signalling and functional responses, in a microcirculatory network in situ. Using live confocal imaging of ureteric microvascular networks, we have studied the architecture, morphology, Ca²⁺ signalling and contractility of myocytes and pericytes. Ca²⁺ signals vary between distributing arcade and downstream transverse and precapillary arterioles, are modified by agonists, with sympathetic agonists being ineffective beyond transverse arterioles. In myocytes and pericytes, Ca²⁺ signals arise from Ca²⁺ release from the sarcoplasmic reticulum through inositol 1,4,5-trisphosphate-induced Ca²⁺ release and not via ryanodine receptors or Ca²⁺ entry into the cell. The responses in pericytes are less oscillatory, slower and longer-lasting than those in myocytes. Myocytes and pericytes are electrically coupled, transmitting Ca²⁺ signals between arteriolar and venular networks dependent on gap junctions and Ca²⁺ entry via L-type Ca²⁺ channels. Endothelial Ca²⁺ signalling inhibits intracellular Ca²⁺ oscillations in myocytes and pericytes via L-arginine/nitric oxide pathway and intercellular propagating Ca²⁺ signals via EDHF. Increases of Ca²⁺ in pericytes and myocytes constrict all vessels except capillaries. These data reveal the structural and signalling specializations allowing blood flow to be regulated by myocytes and pericytes.     

Functional diversity among spectrin isoforms

The purpose of this review on spectrin is to examine the functional properties of this ubiquitous family of membrane skeletal proteins. Major topics include spectrin-membrane linkages, spectrin-filament linkages, the subcellular localization of spectrins in various cell types and a discussion of major functional differences between erythroid and nonerythroid spectrins. This includes a summary of studies from our own laboratories on the functional and structural comparison of avian spectrin isoforms which are comprised of a common alpha subunit and a tissue-specific beta subunit. Consequently, the observed differences among these spectrins can be assigned to differences in the properties of the beta subunits.