A chlamydial type III translocated protein is tyrosine-phosphorylated at the site of entry and associated with recruitment of actin.

The obligate intracellular bacterium Chlamydia trachomatis rapidly induces its own entry into host cells. Initial attachment is mediated by electrostatic interactions to heparan sulfate moieties on the host cell, followed by irreversible binding to an unknown secondary receptor. This secondary binding leads to the recruitment of actin to the site of attachment, formation of an actin-rich, pedestal-like structure, and finally internalization of the bacteria. How chlamydiae induce this process is unknown. We have identified a high-molecular-mass tyrosine-phosphorylated protein that is rapidly phosphorylated on attachment to the host cell. Immunoelectron microscopy studies revealed that this tyrosine-phosphorylated protein is localized to the cytoplasmic face of the plasma membrane at the site of attachment of surface-associated chlamydiae. The phosphoprotein was isolated by immunoprecipitation with the antiphosphotyrosine antibody 4G10 and identified as the chlamydial protein CT456, a hypothetical protein with unknown function. The chlamydial protein (Tarp) appears to be translocated into the host cell by type III secretion because it is exported in a Yersinia heterologous expression assay. Phosphotyrosine signaling across the plasma membrane preceded the recruitment of actin to the site of chlamydial attachment and may represent the initial signal transduced from pathogen to the host cell. These results suggest that C. trachomatis internalization is mediated by a chlamydial type III-secreted effector protein.

Expression of the 53 kD forked protein rescues F-actin bundle formation and mutant bristle phenotypes in Drosophila.

forked mutations affect bristle development in Drosophila pupae, resulting in short, thick, gnarled bristles in the adult. The forked proteins are components of 200-300-microm-long actin fiber bundles that are present transiently during pupal development [Petersen et al., 1994: Genetics 136:173-182]. These bundles are composed of segments of 3-10 microm long, and forked protein is localized along the actin fiber bundle segments and accumulates at the junctions connecting them longitudinally. In the forked mutants, f(36a) and f(hd), F-actin bundles are greatly reduced in number and size, and bundle segmentation is absent. The p-element, P[w(+), falter] contains a 5.3-kb fragment of the forked gene that encodes the 53-kD forked protein [Lankenau et al., 1996: Mol Cell Biol 16:3535-3544]. Expression of only the 53-kD forked protein is sufficient to rescue the actin bundle and bristle phenotypes of f(36a) and f(hd) mutant flies. The 5.3-kb forked sequence, although smaller than the 13-kb region previously shown to rescue forked mutants [Petersen et al., 1994: Genetics 136:173-182], does contain the core forked sequence that encodes actin binding and bundling domains in cultured mammalian cells [Grieshaber and Petersen, 1999: J Cell Sci 112:2203-2211]. These data show that the 53-kD forked protein is sufficient for normal bristle development and that the domains shown previously to be important for actin bundling in cell culture may be all that are required for normal actin bundle formation in developing Drosophila bristles.

Novel embryonic genes are preferentially expressed by autonomously replicating rat embryonic and neointimal smooth muscle cells.

We sought to identify and characterize the expression pattern of genes expressed by smooth muscle cells (SMCs) during periods of self-driven replication during vascular development and after vascular injury. Primary screening of a rat embryonic aortic SMC-specific cDNA library was accomplished with an autonomous embryonic SMC-enriched, nonautonomous adult SMC-subtracted cDNA probe. Positive clones were rescreened in parallel with embryonic SMC-specific and adult SMC-specific cDNA probes. We identified 14 clones that hybridized only with the embryonic cDNA ("emb" clones), 11 of which did not share significant homology with sequences in any of the databases. Five of these novel emb genes (emb7, emb8, emb20, emb37, and emb41) were selectively and only transiently reexpressed in vivo by neointimal SMCs during periods of rapid replication. The emb8:embryonic growth-associated protein (EGAP), which was studied the most extensively, was expressed at high levels by cultured, autonomously replicating embryonic and neointimal SMCs but was detected only at low levels even in mitogenically stimulated adult SMCs. Finally, the administration of antisense EGAP oligonucleotides markedly attenuated embryonic and neointimal SMC replication rates. We suggest that autonomous replication of SMCs may be essential for normal vascular morphogenesis and for the vascular response to injury and that these newly identified "embryonic" genes may be part of the molecular machinery that drives this unique growth phenotype.

Dynamics of actin-based movement by Rickettsia rickettsii in vero cells.

Actin-based motility (ABM) is a virulence mechanism exploited by invasive bacterial pathogens in the genera Listeria, Shigella, and Rickettsia. Due to experimental constraints imposed by the lack of genetic tools and their obligate intracellular nature, little is known about rickettsial ABM relative to Listeria and Shigella ABM systems. In this study, we directly compared the dynamics and behavior of ABM of Rickettsia rickettsii and Listeria monocytogenes. A time-lapse video of moving intracellular bacteria was obtained by laser-scanning confocal microscopy of infected Vero cells synthesizing beta-actin coupled to green fluorescent protein (GFP). Analysis of time-lapse images demonstrated that R. rickettsii organisms move through the cell cytoplasm at an average rate of 4.8 +/- 0.6 micrometer/min (mean +/- standard deviation). This speed was 2.5 times slower than that of L. monocytogenes, which moved at an average rate of 12.0 +/- 3.1 micrometers/min. Although rickettsiae moved more slowly, the actin filaments comprising the actin comet tail were significantly more stable, with an average half-life approximately three times that of L. monocytogenes (100.6 +/- 19.2 s versus 33.0 +/- 7.6 s, respectively). The actin tail associated with intracytoplasmic rickettsiae remained stationary in the cytoplasm as the organism moved forward. In contrast, actin tails of rickettsiae trapped within the nucleus displayed dramatic movements. The observed phenotypic differences between the ABM of Listeria and Rickettsia may indicate fundamental differences in the mechanisms of actin recruitment and polymerization.

Relationship between perlecan and tropoelastin gene expression and cell replication in the developing rat pulmonary vasculature.

Smooth-muscle-cell (SMC) replication and extracellular matrix protein expression are two vital and interrelated processes necessary for normal development of the vasculature. To understand better the nature of this relationship in the developing rat lung, we investigated the relationship between SMC proliferation and the expression of perlecan, a basement membrane (BM) heparan sulfate proteoglycan implicated in the control of SMC growth and differentiation, and tropoelastin (TE), a structural matrix protein not known to influence directly the replicative state of SMCs. Using bromodeoxyuridine (BrdU) incorporation to assess DNA synthesis, we first established the time course of SMC proliferation in the hilar pulmonary artery (PA) from embryonic to adult life. We found a labeling index of > 80% during the embryonic period (embryonic Day 13 [e13] to fetal Day 18 [f18]), a dramatic decline to approximately 40% during the fetal period of development, and a steady decrease in proliferation rates following birth such that, by 30 d of age, a labeling index of < 2% was noted. Using in situ hybridization, we found that although peak expression of both perlecan and TE messenger RNA (mRNA) occurred in the fetal and early postnatal periods following the major decrease in cell replication, TE mRNA expression was clearly observed in the PA as early as embryonic Day 14, whereas perlecan transcripts were virtually undetectable until fetal Day 19. Therefore, to evaluate further the relationship between cell replication and perlecan and/or TE gene expression, we used a combined in situ hybridization/BrdU immunohistochemistry technique and demonstrated that, on an individual cell basis, perlecan message was predominantly expressed by nonreplicating (BrdU-negative) PA, whereas TE mRNA was equally expressed in replicating and nonreplicating PA SMCs. Interestingly, a very similar pattern of replication and relationship to perlecan and TE mRNA expression was noted in airway SMCs and epithelial cells. Thus, in the lung as a whole, maximal expression of both the BM protein perlecan and the interstitial matrix protein TE occurs coordinately and follows the period of maximal SMC proliferation. However, in individual SMCs, perlecan mRNA expression varies inversely with DNA synthesis, whereas TE mRNA expression appears independent of the proliferative state of the cell.

Developmental regulation of perlecan gene expression in aortic smooth muscle cells.

Heparan sulfate proteoglycans (HSPGs) are believed to act as potent endogenous regulators of vascular smooth muscle cell (SMC) replication, migration, gene expression and differentiation. Here we describe the pattern of expression of perlecan, the predominant basement membrane HSPG, during aortic development in the rat. Expression of perlecan mRNA and protein in the aortic SMC was first significantly observed at day e19 (day 19 of embryonic development), a time which marks a dramatic switch in SMC replication rate and growth phenotype. Expression of perlecan message and protein was high throughout fetal and early neonatal life, and it remained readily detectable in the adult aorta. Using a double-labeling technique (in situ hybridization for perlecan message coupled with bromodeoxyuridine immunohistochemistry), we determined the relationship between DNA synthesis and perlecan mRNA expression in individual SMC at days e17-e21; we found that perlecan gene expression was largely limited to non-replicating cells. Consistent with the in vivo data, perlecan mRNA was undetectable in cultured e17 SMC by Northern or RT-PCR analysis, while in cultured adult SMC, perlecan mRNA was significantly higher in non-replicating (serum-starved) cultures compared to replicating cultures. Treatment of growth-arrested adult SMC cultures with heparin caused a further accumulation in perlecan mRNA levels. The data suggest that the expression of perlecan by vascular SMC is regulated by apparent developmental age as well as by cellular growth state. The developmentally times expression of perlecan in the aortic wall may contribute to the establishment and/or maintenance of vascular SMC differentiation and quiescence.

Developmental regulation of angiotensin converting enzyme and angiotensin type 1 receptor in the rat pulmonary circulation.

Factors that influence the development of the normal pulmonary vasculature are poorly understood. Since increased local production of angiotensin II (AII) by angiotensin converting enzyme (ACE) has been implicated in the medial hypertrophy of systemic and pulmonary hypertension, we questioned whether ACE and angiotensin receptor expression may influence the muscularization of the normal pulmonary vasculature during development. The approach employed measurement of lung ACE activity, assessment of local ACE expression by immunohistochemistry, and angiotensin type 1 receptor (AT1) expression by in situ hybridization in rat lungs ranging from 15 days of intrauterine life (term = 21 d) to adulthood. The temporal and spatial pattern of ACE expression was compared with that of the endothelial marker, von Willebrand factor (vWF), and the smooth muscle cell markers, alpha smooth muscle actin and smooth muscle myosin. ACE activity was first detected in lung homogenates on day 17 of gestation (1 +/- 0.2 mU/mg) and increased progressively to term (27.7 +/- 3.2 mU/mg). However, the greatest increase in lung ACE activity to adult levels (379 +/- 25.2 mU/mg) occurred between 2 and 4 wk of postnatal life. Immunohistochemistry demonstrated vWF expression by vascular endothelium throughout the lung as early as day 15 of gestation. In contrast, ACE expression was observed in the endothelium of only hilar pulmonary arteries on day 15 of gestation, and thereafter was noted to be expressed in endothelial cells of progressively more distal arteries, such that by term, endothelial cells of all muscularized arteries expressed ACE. Alveolar capillary ACE expression was not detected until day 20 of gestation, and increased dramatically after birth. Smooth muscle actin expression in lung arteries closely paralleled the expression of endothelial ACE. AT1 receptor mRNA was first expressed in the peripheral lung on day 17 of gestation by non-epithelial undifferentiated mesenchyme. In contrast, AT1 mRNA signal was much reduced in differentiated smooth muscle. We speculate that ACE expression in the fetal lung circulation may influence the muscularization of fetal pulmonary arteries by the interaction of locally produced angiotensin II with the AT1 receptor.

Smooth muscle cells isolated from the neointima after vascular injury exhibit altered responses to platelet-derived growth factor and other stimuli.

A variety of evidence suggests that vascular smooth muscle cells (SMC) exhibit a more immature phenotype when stimulated by injury to replicate in the adult. One growth characteristic common to immature (embryonic, fetal, and neonatal) SMC is a markedly reduced responsiveness to platelet-derived growth factor (PDGF) and other mitogenic stimuli. Here we demonstrate that SMC isolated from the 14-day neointima of experimentally injured carotid arteries exhibit a similar growth phenotype. The proliferative responses of neointimal cells to the BB homodimer of PDGF, which interacts with both forms of the PDGF receptor, were up to twenty-fold less (as assessed by BrdU immunocytochemistry) than that of adult control tunica media cells over a wide range of PDGF concentrations. Paradoxically, these cells expressed abundant mRNA for the alpha- and beta-subunits of the PDGF receptor (by RT-PCR) and expressed abundant PDGF receptor protein (by Western blotting). Addition of PDGF-BB to neointimal SMC induced significant autophosphorylation of the PDGF receptor, suggesting that the PDGF receptors were fully functional. The chemotactic responses of neointimal SMC to PDGF, in in vitro migration assays, were identical to that of control medial cells. The data further establish the existence of vascular SMC phenotypes characterized by a refractoriness to growth stimulation by specific mitogens, and provide further evidence for the reiteration of developmentally regulated programs following vascular injury in vivo.