The ActA protein of Listeria monocytogenes acts as a nucleator inducing reorganization of the actin cytoskeleton.

Listeria monocytogenes, a facultative intracellular pathogen, employs actin and other microfilament-associated proteins to move through the host cell cytoplasm. Isogenic mutants of L. monocytogenes lacking the surface-bound ActA polypeptide no longer interact with cytoskeletal elements and are, as a consequence, non-motile (Domann et al., 1992, EMBO J., 11, 1981-1990; Kocks et al., 1992, Cell, 68, 521-531). To investigate the interaction of ActA with the microfilament system in the absence of other bacterial factors, the listerial actA gene was expressed in eukaryotic cells. Immunofluorescence studies revealed that the complete ActA, including its C-terminally located bacterial membrane anchor, colocalized with mitochondria in transfected cells. When targeted to mitochondria, the ActA polypeptide recruited actin and alpha-actinin to these cellular organelles with concomitant reorganization of the microfilament system. Removal of the internal proline-rich repeat region of ActA completely abrogated interaction with cytoskeletal components. Our results identify the ActA polypeptide as a nucleator of the actin cytoskeleton and provide the first insights into the molecular nature of such controlling elements in microfilament organization.     

Evidence implicating the 5' untranslated region of Listeria monocytogenes actA in the regulation of bacterial actin-based motility

The ActA protein of Listeria monocytogenes is a major virulence factor, essential for the recruitment and polymerization of host actin filaments that lead to intracellular motility and cell-to-cell spread of bacteria within the infected host. The expression of actA is tightly regulated and is strongly induced only when L. monocytogenes is within the host cytosol. Intracellular induction of actA expression is mediated through a single promoter element that directs the expression of a messenger RNA with a long (150 bp) 5' untranslated region (UTR). Deletion of the actA+3 to +130 upstream region was found to result in bacterial mutants that were no longer capable of intracellular actin recruitment or cell-to-cell spread, thus indicating that this region is important for actA expression. L. monocytogenes strains that contained smaller deletions (21-23 bp) within the actA upstream region demonstrated a range of actA expression levels that coincided with the amount of bacterial cell-to-cell spread observed within infected monolayers. A correlation appeared to exist between levels of actA expression and the ability of L. monocytogenes to transition from uniform actin accumulation surrounding individual bacteria (actin clouds) to directional assembly and the formation of actin tails. Bacterial mutants containing deletions that most significantly altered the predicted secondary structure of the actA mRNA 5' UTR had the largest reductions in actA expression. These results suggest that the actA 5' UTR is required for maximal ActA synthesis and that a threshold level of ActA synthesis must be achieved to promote the transition from bacteria-associated actin clouds to directional actin assembly and movement.     

The actin-polymerization protein from Listeria ivanovii is a large repeat protein which shows only limited amino acid sequence homology to actA from Listeria monocytogenes

Abstract Within infected eukaryotic cells the two pathogenic Listeria species, L. monocytogenes and L. ivanovii , induce polymerization of cellular actin and the formation of a propulsive actin tail at one bacterial pole. For L. monocytogenes it has been shown that the product of the listerial actA gene is required for this process which is regarded as a model for actin-based motility. We have now cloned and sequenced a functionally analogous gene from L. ivanovii ; its product, as deduced from the DNA sequence, is considerably larger (108 kDa) than L. monocytogenes ActA (67 kDa) and shares only a limited amino acid sequence homology (46% similarity on average) with the latter protein. This is the first example of a virulence gene product from L. ivanovii which is significantly different from its L. monocytogenes counterpart. Comparison of the two ActA proteins gives new insight into the structure of this class of actin-polymerization proteins, in particular with respect to their proline-rich repeat region.     

Systematic mutational analysis of the amino-terminal domain of the Listeria monocytogenes ActA protein reveals novel functions in actin-based motility

The Listeria monocytogenes ActA protein acts as a scaffold to assemble and activate host cell actin cytoskeletal factors at the bacterial surface, resulting in directional actin polymerization and propulsion of the bacterium through the cytoplasm. We have constructed 20 clustered charged-to-alanine mutations in the NH2-terminal domain of ActA and replaced the endogenous actA gene with these molecular variants. These 20 clones were evaluated in several biological assays for phenotypes associated with particular amino acid changes. Additionally, each protein variant was purified and tested for stimulation of the Arp2/3 complex, and a subset was tested for actin monomer binding. These specific mutations refined the two regions involved in Arp2/3 activation and suggest that the actin-binding sequence of ActA spans 40 amino acids. We also identified a 'motility rate and cloud-to-tail transition' region in which nine contiguous mutations spanning amino acids 165-260 caused motility rate defects and changed the ratio of intracellular bacteria associated with actin clouds and comet tails without affecting Arp2/3 activation. Several unusual motility phenotypes were associated with amino acid changes in this region, including altered paths through the cytoplasm, discontinuous actin tails in host cells and the tendency to 'skid' or dramatically change direction while moving. These unusual phenotypes illustrate the complexity of ActA functions that control the actin-based motility of L. monocytogenes.     

Asymmetric distribution of the Listeria monocytogenes ActA protein is required and sufficient to direct actin-based motility

Listeria monocytogenes is a Gram-positive facultative intracytoplasmic bacterial pathogen that exhibits rapid actin-based motility in eukaryotic cells and in cell-free cytoplasmic extracts. The protein product of the actA gene is required for bacterial movement and is normally expressed in a polarized fashion on the bacterial surface. Here we demonstrate that the ActA protein is sufficient to direct motility in the absence of other L. monocytogenes gene products, and that polarized localization of the protein is required for efficient unidirectional movement. We have engineered a fusion protein combining ActA with the C-terminal domain of the LytA protein of Streptococcus pneumoniae , which mediates high-affinity binding to DEAE-cellulose and to choline moieties present in the S. pneumoniae cell wall. DEAE-cellulose fragments or S. pneumoniae coated uniformly with the ActA/LytA fusion protein nucleate actin filament growth in cytoplasmic extracts, but do not move efficiently. However, when ActA/LytA-coated S. pneumoniae is grown to polarize the distribution of the fusion protein, the bacteria exhibit unidirectional actin-based movement similar to the normal movement of L. monocytogenes .     

Allelic exchange and site-directed mutagenesis probe the contribution of ActA amino-acid variability to phosphorylation and virulence-associated phenotypes among Listeria monocytogenes strains

To test the hypothesis that actA allelic variation contributes to virulence differences among Listeria monocytogenes strains, cell-to-cell spread and intracellular ActA phosphorylation patterns were characterized for 14 wild-type isolates and selected isogenic mutants. Our data show that (i) while actA allelic variation is not responsible for enhanced cell-to-cell spread observed in epidemic clone I strains, actA allelic variation may contribute to reduced plaque size observed in some isolates, (ii) actA sequence alone determines phosphorylation-dependent ActA banding patterns, and (iii) sequence variation at the positively selected ActA residue 498 does not contribute to ActA phosphorylation patterns or to differences in cell-to-cell spread.     

A role for ActA in epithelial cell invasion by Listeria monocytogenes

We assessed the role of the actin-polymerizing protein, ActA, in host cell invasion by Listeria monocytogenes . An in frame Δ actA mutant was constructed in a hyperinvasive strain of prfA * genotype, in which all genes of the PrfA-dependent virulence regulon, including actA , are highly expressed in vitro . Loss of ActA production in prfA * bacteria reduced entry into Caco-2, HeLa, MDCK and Vero epithelial cells to basal levels. Reintroduction of actA into the Δ actA prfA * mutant fully restored invasiveness, demonstrating that ActA is involved in epithelial cell invasion. ActA did not contribute to internalization by COS-1 fibroblasts and Hepa 1-6 hepatocytes. Expression of actA in Listeria innocua was sufficient to promote entry of this non-invasive species into epithelial cell lines, but not into COS-1 and Hepa 1-6 cells, indicating that ActA directs an internalization pathway specific for epithelial cells. Scanning electron microscopy of infected Caco-2 human enterocytes suggested that this pathway involves microvilli. prfA * bacteria, but not wild-type bacteria (which express PrfA-dependent genes very weakly in vitro ) or prfA *Δ actA bacteria, efficiently invaded differentiated Caco-2 cells via their apical surface. Microvilli played an active role in the phagocytosis of the prfA * strain, and actA was required for their remodelling into pseudopods mediating bacterial uptake. Thus, ActA appears to be a multifunctional virulence factor involved in two important aspects of Listeria pathogenesis: actin-based motility and host cell tropism and invasion.     

L. monocytogenes-induced actin assembly requires the actA gene product, a surface protein.

The intracellular pathogenic bacterium L. monocytogenes can spread directly from cell to cell without leaving the cytoplasm. The mechanism of this movement, generated through bacterially induced actin polymerization, is not understood. By analyzing an avirulent Tn917-lac mutant defective for actin polymerization, we have identified a bacterial component involved in this process. The transposon had inserted in actA, the second gene of an operon. Gene disruption of downstream genes and transformation of the mutant strain with actA showed that the actA gene encodes a surface protein necessary for bacterially induced actin assembly. Our results indicate that it is a 610 amino acid protein with an apparent molecular weight of 90 kd.     

产单核细胞李斯特菌actA基因在大肠杆菌中的表达及其单克隆抗体的研制

利用PCR技术从血清型1/2a的产单核细胞李斯特菌Lm-4株中扩增出actA基因,经克隆筛选和测序鉴定后,构建成该基因的原核表达载体pGEX-6P-1-actA及pET-actA,转入E·coli后,IPTG诱导目的蛋白的表达。SDS-PAGE结果表明,actA基因在两种载体中均获得表达,融合蛋白的大小分别约为120kDa和97kDa。以纯化蛋白为材料进行了ActA单抗的研制,获得4株抗ActA的单克隆抗体杂交瘤细胞株,腹水单抗ELISA效价为1∶5×104~1∶1×105。选取单抗1A5进行Westernblot分析,结果表明单抗1A5能和表达产物进行特异性反应,且与Lm-4多抗血清的Westernblot结果一致。actA基因的原核表达及单抗的研制为研究ActA蛋白的生物学活性及其致病作用奠定了基础。     

Isolation of Listeria monocytogenes mutants with high-level in vitro expression of host cytosol-induced gene products

The facultative intracellular bacterial pathogen Listeria monocytogenes dramatically increases the expression of several key virulence factors upon entry into the host cell cytosol. actA, the protein product of which is required for cell-to-cell spread of the bacterium, is expressed at low to undetectable levels in vitro and increases in expression more than 200-fold after L. monocytogenes escape from the phagosome. To identify bacterial factors that participate in the intracellular induction of actA expression, L. monocytogenes mutants expressing high levels of actA during in vitro growth were selected after chemical mutagenesis. The resulting mutant isolates displayed a wide range of actA expression levels, and many were less sensitive to environmental signals that normally mediate repression of virulence gene expression. Several isolates contained mutations affecting actA gene expression that mapped at least 40 kb outside the PrfA regulon, supporting the existence of additional regulatory factors that contribute to virulence gene expression. Two actA in vitro expression mutants contained novel mutations within PrfA, a key regulator of L. monocytogenes virulence gene expression. PrfA E77K and PrfA G155S mutations resulted in high-level expression of PrfA-dependent genes, increased bacterial invasion of epithelial cells and increased virulence in mice. Both prfA mutant strains were significantly less motile than wild-type L. monocytogenes. These results suggest that, although constitutive activation of PrfA and PrfA-dependent gene expression may enhance L. monocytogenes virulence, it may conversely hamper the bacterium's ability to compete in environments outside host cells.     

The unrelated surface proteins ActA of Listeria monocytogenes and lcsA of Shigella flexneri are sufficient to confer actin-based motility on Listeria innocua and Escherichia coli respectively

Listeria monocytogenes and Shigella flexneri are two unrelated facultative intracellular pathogens which spread from cell to cell by using a similar mode of intracellular movement based on continuous actin assembly at one pole of the bacterium. This process requires the asymmetrical expression of the ActA surface protein in L. monocytogenes and the lcsA (VirG) surface protein in S. flexneri . ActA and lcsA share no sequence homology. To assess the role of the two proteins in the generation of actin-based movement, we expressed them in the genetic context of two non-actin polymerizing, non-pathogenic bacterial species, Listeria innocua and Escherichia coli . In the absence of any additional bacterial pathogenicity determinants, both proteins induced actin assembly and propulsion of the bacteria in cytoplasmic extracts from Xenopus eggs, as visualized by the formation of characteristic actin comet tails. E. coli expressing lcsA moved about two times faster than Listeria and displayed longer actin tails. However, actin dynamics (actin filament distribution and filament half-lives) were similar in lcsA- and ActA-induced actin tails suggesting that by using unrelated surface molecules, L. monocytogenes and S. flexneri move intracellularly by interacting with the same host cytoskeleton components or by interfering with the same host cell signal transduction pathway.     

ActA from Listeria monocytogenes can interact with up to four Ena/VASP homology 1 domains simultaneously

The facultative intracellular human pathogenic bacterium Listeria monocytogenes actively recruits host actin to its surface to achieve motility within infected cells. The bacterial surface protein ActA is solely responsible for this process by mimicking fundamental steps of host cell actin dynamics. ActA, a modular protein, contains an N-terminal actin nucleation site and a central proline-rich motif of the 4-fold repeated consensus sequence FPPPP (FP(4)). This motif is specifically recognized by members of the Ena/VASP protein family. These proteins additionally recruit the profilin-G-actin complex increasing the local concentration of G-actin close to the bacterial surface. By using analytical ultracentrifugation, we show that a single ActA molecule can simultaneously interact with four Ena/VASP homology 1 (EVH1) domains. The four FP(4) sites have roughly equivalent affinities with dissociation constants of about 4 microm. Mutational analysis of the FP(4) motifs indicate that the phenylalanine is mandatory for ActA-EVH1 interaction, whereas in each case exchange of the third proline was tolerated. Finally, by using sedimentation equilibrium centrifugation techniques, we demonstrate that ActA is a monomeric protein. By combining these results, we formulate a stoichiometric model to describe how ActA enables Listeria to utilize efficiently resources of the host cell microfilament for its own intracellular motility.     

Listeria monocytogenes ActA protein interacts with phosphatidylinositol 4,5-bisphosphate in vitro

The N-terminal region of the Listeria monocytogenes ActA protein, in conjunction with host cell factors, is sufficient for actin polymerization at the bacterial surface. Previous data suggested that ActA could protect barbed ends from capping proteins. We tested this hypothesis by actin polymerization experiments in the presence of the ActA N-terminal fragment and capping protein. ActA does not protect barbed ends from capping protein. In contrast, this polypeptide prevents PIP(2) from inhibiting the capping activity of capping protein. Gel filtration and tryptophan fluorescence experiments showed that the purified ActA N-terminal fragment binds to PIP(2) and PIP, defining phosphoinositides as novels ligands for this functional domain of ActA. Phosphoinositide binding to the N-terminal region of ActA may induce conformational changes in ActA and/or facilitate binding of other cell components, important for ActA-induced actin polymerization.     

产单核细胞李斯特菌actA/plcB缺失株的构建及其生物学特性

产单核细胞李斯特菌的毒力因子与该菌在细胞间扩散、传播有着直接的关系,其中肌动蛋白聚集因子ActA是细菌由细胞浆扩散至相邻细胞所必须的因子,而广谱磷脂酶C则参与具有双层膜吞噬体的裂解过程.[方法]本研究中利用同源重组技术成功构建了毒力因子ActA和PC-PLC双缺失的突变株,[目的]并对突变株的毒力和免疫应答潜能进行评价.[结果]Western blot和磷脂酶活性测定实验,分别从蛋白质水平上证实actA和plcB基因的缺失.突变株的毒力显著降低,对小鼠半数致死剂量比野生型菌株提高约10 3倍,但仍然保持较好地诱导T细胞应答的能力,并且能完全保护野生型细菌致死剂量的攻击.实验结果不仅表明ActA和PC-PLC是产单核细胞李斯特菌的重要毒力因子,而且证实安全性提高的突变株依然保持有较强地诱导细胞免疫应答的能力.[结论]因此,该突变株的获得不仅对李斯特菌病的预防具有重要作用,而且为构建预防人类和动物疫病的疫苗载体奠定了基础,此外对于阐明LM毒力因子的致病机理与免疫保护作用提供了条件.     

Three regions within ActA promote Arp2/3 complex-mediated actin nucleation and Listeria monocytogenes motility

The Listeria monocytogenes ActA protein induces actin-based motility by enhancing the actin nucleating activity of the host Arp2/3 complex. Using systematic truncation analysis, we identified a 136-residue NH(2)-terminal fragment that was fully active in stimulating nucleation in vitro. Further deletion analysis demonstrated that this fragment contains three regions, which are important for nucleation and share functional and/or limited sequence similarity with host WASP family proteins: an acidic stretch, an actin monomer-binding region, and a cofilin homology sequence. To determine the contribution of each region to actin-based motility, we compared the biochemical activities of ActA derivatives with the phenotypes of corresponding mutant bacteria in cells. The acidic stretch functions to increase the efficiency of actin nucleation, the rate and frequency of motility, and the effectiveness of cell-cell spread. The monomer-binding region is required for actin nucleation in vitro, but not for actin polymerization or motility in infected cells, suggesting that redundant mechanisms may exist to recruit monomer in host cytosol. The cofilin homology sequence is critical for stimulating actin nucleation with the Arp2/3 complex in vitro, and is essential for actin polymerization and motility in cells. These data demonstrate that each region contributes to actin-based motility, and that the cofilin homology sequence plays a principal role in activation of the Arp2/3 complex, and is an essential determinant of L. monocytogenes pathogenesis.     

Listeria monocytogenes Exploits Normal Host Cell Processes to Spread from Cell to Cell✪

The bacterial pathogen, Listeria monocytogenes, grows in the cytoplasm of host cells and spreads intercellularly using a form of actin-based motility mediated by the bacterial protein ActA. Tightly adherent monolayers of MDCK cells that constitutively express GFP-actin were infected with L. monocytogenes, and intercellular spread of bacteria was observed by video microscopy. The probability of formation of membrane-bound protrusions containing bacteria decreased with host cell monolayer age and the establishment of extensive cell-cell contacts. After their extension into a recipient cell, intercellular membrane-bound protrusions underwent a period of bacterium-dependent fitful movement, followed by their collapse into a vacuole and rapid vacuolar lysis. Actin filaments in protrusions exhibited decreased turnover rates compared with bacterially associated cytoplasmic actin comet tails. Recovery of motility in the recipient cell required 1-2 bacterial generations. This delay may be explained by acid-dependent cleavage of ActA by the bacterial metalloprotease, Mpl. Importantly, we have observed that low levels of endocytosis of neighboring MDCK cell surface fragments occurs in the absence of bacteria, implying that intercellular spread of bacteria may exploit an endogenous process of paracytophagy.     

LaXp180, a mammalian ActA-binding protein, identified with the yeast two-hybrid system, co-localizes with intracellular Listeria monocytogenes

The Listeria monocytogenes surface protein ActA is an important virulence factor required for listerial intracellular movement by inducing actin polymerization. The only host cell protein known that directly interacts with ActA is the phosphoprotein VASP, which binds to the central proline-rich repeat region of ActA. To identify additional ActA-binding proteins, we applied the yeast two-hybrid system to search for mouse proteins that interact with ActA. A mouse cDNA library was screened for ActA-interacting proteins (AIPs) using ActA from strain L. monocytogen es EGD as bait. Three different AIPs were identified, one of which was identical to the human protein LaXp180 (also called CC1). Binding of LaXp180 to ActA was also demonstrated in vitro using recombinant histidine-tagged LaXp180 and recombinant ActA. Using an anti-LaXp180 antibody and fluorescence microscopy, we showed that LaXp180 co-localizes with a subset of intracellular, ActA-expressing L. monocytogenes but was never detected on intracellularly growing but ActA-deficient mutants. Furthermore, LaXp180 binding to intracellular L. monocytogenes was asymmetrical and mutually exclusive with F-actin polymerization on the bacterial surface. LaXp180 is a putative binding partner of stathmin, a protein involved in signal transduction pathways and in the regulation of microtubule dynamics. Using immunofluorescence, we showed that stathmin co-localizes with intracellular ActA-expressing L. monocytogenes .     

Targeting of Listeria monocytogenes ActA protein to the plasma membrane as a tool to dissect both actin-based cell morphogenesis and ActA function.

Actin assembly on the surface of Listeria monocytogenes in the cytoplasm of infected cells provides a model to study actin-based motility and changes in cell shape. We have shown previously that the ActA protein, exposed on the bacterial surface, is required for polarized nucleation of actin filaments. To investigate whether plasma membrane-associated ActA can control the organization of microfilaments and cell shape, variants of ActA, in which the bacterial membrane signal had been replaced by a plasma membrane anchor sequence, were produced in mammalian cells. While both cytoplasmic and membrane-bound forms of ActA increased the F-actin content, only membrane-associated ActA caused the formation of plasma membrane extensions. This finding suggests that ActA acts as an actin filament nucleator and shows that permanent association with the inner face of the plasma membrane is required for changes in cell shape. Based on the observation that the amino-terminal segment of ActA and the remaining portion which includes the proline-rich repeats cause distinct phenotypic modifications in transfected cells, we propose a model in which two functional domains of ActA cooperate in the nucleation and dynamic turnover of actin filaments. The present approach is a new model system to dissect the mechanism of action of ActA and to further investigate interactions of the plasma membrane and the actin cytoskeleton during dynamic changes of cell shape.     

FbpA, a novel multifunctional Listeria monocytogenes virulence factor

Listeria monocytogenes is a Gram-positive intracellular bacterium responsible for severe opportunistic infections in humans and animals. Signature-tagged mutagenesis (STM) was used to identify a gene named fbpA, required for efficient liver colonization of mice inoculated intravenously. FbpA was also shown to be required for intestinal and liver colonization after oral infection of transgenic mice expressing human E-cadherin. fbpA encodes a 570-amino-acid polypeptide that has strong homologies to atypical fibronectin-binding proteins. FbpA binds to immobilized human fibronectin in a dose-dependent and saturable manner and increases adherence of wild-type L. monocytogenes to HEp-2 cells in the presence of exogenous fibronectin. Despite the lack of conventional secretion/anchoring signals, FbpA is detected using an antibody generated against the recombinant FbpA protein on the bacterial surface by immunofluorescence, and in the membrane compartment by Western blot analysis of cell extracts. Strikingly, FbpA expression affects the protein levels of two virulence factors, listeriolysin O (LLO) and InlB, but not that of InlA or ActA. FbpA co-immunoprecipitates with LLO and InlB, but not with InlA or ActA. Thus, FbpA, in addition to being a fibronectin-binding protein, behaves as a chaperone or an escort protein for two important virulence factors and appears as a novel multifunctional virulence factor of L. monocytogenes.