Lethal factor (LF) is a 90 kDa secreted protein encoded by the lef locus on the pXOI plasmid of B. anthracis [26]. The crystal structure of LF has been solved and is reviewed elsewhere [27]. LF is encoded by a 2,427 bp open reading frame that can be divided into three regions: (1) a PA-binding region contained within the first 254 amino acids at the NH₂ terminus, which has a high degree of similarity to the amino terminus of EF, (2) a central region containing a series of five imperfect 19 amino acid repeats, and (3) the remaining C-terminal portion of the protein that exhibits no sequence homology to known proteins (reviewed in [28]). Mutagenesis mapping of LF demonstrated that the C-terminal region is responsible for the enzymatic activity of the protein. Insertions into this region eliminated toxicity without alteration in PA binding [29]. Further analysis of this domain identified a portion (amino acids 686-692; protein sequence HEFGHAV) containing a motif characteristic of metalloproteases (HEXXH, where X is any amino acid) [30].

The presence of a metalloprotease-like motif contained within the catalytic portion of LF suggested LF was a protease. In support of this, protease inhibitors such as bestatin and captopril blocked LF-mediated toxicity of macrophages [30]. Moreover, the substitution of alanine for two residues implicated in zinc binding (H686A and H690A) resulted in LF inactivation as well as reduced zinc binding, and substitution of cysteine for glutamic acid at amino acid 687 (E687C), a residue known to be essential for metalloprotease activity, led to the inactivation of LF [30]. Finally, LF has been shown to bind at least one ⁶⁵Zn atom [30,31], and zinc binding is reduced in inactive LF mutants [30].

To establish a successful infection, B. anthracis must have mechanisms in place to suppress the immune system. LeTx affects various aspects of the immune system including cytokine, dendritic cell and T-cell responses [15,17]. LeTx appears to exert its immunosuppressive effects by blocking the function of phagocytes, resulting in a delay in wound healing and favoring bacterial growth, and by inhibiting cell-mediated immunity, to prevent death of infected macrophages. A well studied major cellular target of LeTx is macrophages, as LeTx was first demonstrated to exhibit cytotoxicity in vitro to murine macrophages [43]. It is now clear that macrophages are not the only target cell of LeTx, particularly in the immune system [44]. Monocytes, dendritic cells, and T cells, among others, all appear to be disregulated, in terms of cytokine secretion, activation, and proliferation, following LeTx treatment. In particular, LeTx is a potent T cell suppressor, both in terms of T cell activation and proliferation, but also in the ability of T cells to migrate and chemotax [45]. The inhibition of T cell chemotaxis likely impairs numerous pathways that contribute to bacterial clearance and wound healing.

The MAPK pathways are central to the activation of both the innate and adaptive immune responses [46]. MAPK activation has been suggested to play a role in macrophage phagocytosis [47,48]. Additionally, MAPK signaling pathways play key roles in activated T cell gene expression, and T cells disrupted in MAPK pathway signaling via LeTx-induced cleavage of MAPKKs have dramatic alterations in the activation of key transcription factors [20,49]. While, activation of the ERK pathway has been shown to be important in T cell maturation, activation, and differentiation [50,51], it is the p38 and JNK pathways that exert the greatest influences on immune responses. Activation of these pathways is important for a variety of immune responses, including initiation, activation, and progression of both the innate and adaptive immunities [52,53]. These pathways can regulate the expression of pro-inflammatory cytokines in macrophages [53], contribute to the development, activation, and proliferation of T cells [54,55], and play roles in dendritic cell migration and activation [56,57].

Vascular damage and dysfunction are hallmarks of anthrax infection; vascular leakage, tissue hemorrhage, and terminal hypotensive shock are commonly associated with anthrax pathology. These effects are likely caused by increased vascular permeability. This has led to studies aimed at identifying potential direct effects of LeTx action on endothelial cells, and suggests that LeTx-mediated MAPKK inhibition may alter endothelial cell function. In support of this, in vitro studies have shown that LeTx can reduce endothelial cell viability and induces apoptosis of endothelial cells [22], as well as induce endothelial barrier dysfunction [23,58].

That alterations in vascular permeability and endothelial cell function result from MAPK pathway interference is not surprising. The MAPK pathway has been shown to play a pivotal role in vascularization in early embryonic development [59]. Deficiencies in various components of the MAPK cascade, as studied by way of knockout mice, result in defects in embryonic vascularization. For example, MEK1 and ERK2 knockout mice have defective placental vascularization [60,61], defects in MEK5 result in cardiovascular defects [62], and B-Raf knockout mice display extensive vascular defects [63].

It is of interest to note that the initial discovery suggesting MAPKK as the substrate of LF came from a sensitivity screen of the National Cancer Institute’s anti-neoplastic drug screen database, which identified LF as having a similar sensitivity profile against 60 human cancer cell lines as the known MEK inhibitor, PD98059 [32,64]. Not only did this suggest MAPKKs as substrates for LF, but implicated LeTx as a potential novel therapeutic for tumorigenesis.

The MAPK signaling pathways have been intensely studied in terms of their roles in tumor growth and progression due to their implicated actions as regulators of cell proliferation, migration, and apoptosis, all of which are critical steps for tumor growth, survival, and metastasis [65]. In fact, MAPK pathways have been suggested to play critical roles in tumorigenesis based on the fact that they regulate proteolytic enzymes that can promote invasion and progression, migration and motility, which may enhance metastatic potential, and regulation of apoptosis to promote survival, particularly of metastatic cells to distant locations. Not surprisingly, therefore, LeTx was initially shown to inhibit the growth and tumorigenicity of V-12 H-ras transformed NIH 3T3 fibroblasts in vitro [38]. It has since been demonstrated that invivo administration of LeTx by intratumoral administration of LeTx [38,64], as well as by systemic treatment [66,67,68], inhibits tumor growth (Figure 3).

While systemic administration of LeTx reduced tumor growth in xenograft models, it also substantially reduced tumor vascular content, indicating that MAPKK signaling is important for vascularization of tumors invivo [38,67,68]. Importantly, as tumor vascularization is driven by the release of angio-proliferative growth factors from tumor cells that induce angiogenesis, analysis of tumor xenografts revealed that LeTx treatment decreased the release of a number of angio-proliferative factors, including basic fibroblast growth factor (bFGF), interleukin-8 (IL-8), and vascular endothelial growth factor (VEGF) [68], the same cytokines noted as strong correlates of disease-free and overall survival in other tumors such as melanoma [69].

Recently, PA alone has been reported to inhibit tumor angiogenesis [70]. However, these effects are only evident at relatively elevated concentrations, and by use of a mutant form of PA that is resistant to furin activation. At concentrations associated with LF-impaired angiogenesis (i.e., 10-100 fold lower), wild-type PA alone or in combination with catalytically inactive LF has no measurable effect on angiogenesis [64,68]. Interestingly, the extracellular domain of anthrax toxin receptors (ANTXR) contains a von Willebrand factor type A (vWFA) domain, a conserved ligand binding that mediates extracellular matrix associations [71]. These domains within ANTXR have since been shown to associate with specific extracellular matrix proteins such as gelatin and type 1 collagen for TEM8 [72], and collagen type IV and laminin for CMG2 [73]. As PA-binding to these receptors could interfere with extracellular matrix interactions by ANTXR, elevated levels of extracellular PA may disrupt endothelial cell adhesion, leading to impaired angiogenesis.

MAPK pathway signaling has previously been shown to play essential roles in vascularization during tumorigenesis, specifically by modulating the release of and response to VEGF, which is recognized as a critical growth factor in angiogenesis [74]. MEK activity regulates VEGF expression at the transcriptional and post-transcriptional levels [75]. The ERK pathway has been demonstrated to be critical in the control of VEGF expression [76] and to mediate VEGF-induced proliferation via the endothelial-specific receptor, VEGFR2 [77], while JNK and p38 have been shown to regulate VEGF expression [75]. MEK signaling pathways are also activated in response to VEGF, whereby treatment of endothelial cells with VEGF results in activation of ERK1/2 [78], as well as p38 [79]. Insight into the in vivo functions of MAPKKs has been implicated by the effect of MAPKK inhibitors on tumor vascularization. For example, expression of an inactive Raf-1 mutant in endothelial cells blocks growth and vascularization of melanomas in mice [80], while BAY 43-9006 (Sorafenib), a compound that inhibits B-Raf and c-Raf, (MAPKKK isoforms that activate MEK1 and MEK2), also reduces tumor vascularization in vivo [81]. More recently, expression of dominant negative MKK1 in tumor endothelium has been shown to disrupt growth and vascularization of colorectal adenocarcinoma xenografts [82].

Whereas in vitro studies of LeTx pointed to a role for MAPK signaling in regulating VEGF expression in tumor cells, a different picture emerged from in vivo studies in which it was noted that tumors deficient in anthrax toxin receptor expression were still sensitive to LeTx treatment, resulting in decreased tumor growth in vivo [83]. Furthermore, vital imaging, performed on fibrosarcoma xenografts using high-resolution ultrasound, demonstrated that MEK inhibition through LeTx treatment led to a striking and rapid reduction in tumor perfusion within 24 h of LeTx treatment [68]. While its ability to reduce tumor vascularization may be linked to decreased tumor-cytokine production, the ability of LeTx to block growth of receptor deficient tumors, as well as the rapid reduction in perfusion following LeTx administration, strongly argues that MEK inhibition by LeTx inhibits tumor vascularization not by direct action on tumor cells, but through a stromal component of the tumor, perhaps endothelial cells.

To further investigate the effects of LeTx on neovascularization, a mouse model of retinal vascular growth and neovascularization has been adapted [84]. Retinal vasculature forms in a well-characterized and highly reproducible manner, providing a convenient system to evaluate contributions to vascular formation and development. Due to vascular growth in two dimensions, the retina provides a convenient model to directly observe developmental angiogenesis, as well as a useful model to monitor and quantify changes in vascular growth. Retinal vascular development is intensely studied, especially in the context of retinopathies, whereby abnormal vascular growth (termed neovascularization) in the retina can lead to blindness. Common retinopathies of this nature include retinopathy of prematurity (ROP) and diabetic retinopathy (DR), which are characterized by retinal neovascularization [85], and age-related macular degeneration (AMD), which is characterized by pathological outgrowth of new vessels from the choroid into the subretinal space [86]. VEGF has been shown to play a central role as a stimulator of both retinal and choroidal neovascularization, whereby inhibition of VEGF can block both types of neovascularization in the eye [86,87,88]. In fact, intravitreal injections of agents that block VEGF function have been shown to stabilize and even potentially improve vision in patients with AMD [89].

Previously published reports suggest a role for the signaling of the MAPK pathways during both vascular development and disease progression in the retina. It has been demonstrated in vitro that while the Ras/Raf/MEK/ERK pathway activated proliferation of retinal pigmented epithelial (RPE) cells [90], the JNK and p38 MAPK pathways have been characterized for their role in RPE cell death [91]. Furthermore, an increase of ERK activation was detected in a rat model of ROP, and intravitreous injection of ERK inhibitors reduced retinal neovascularization in this invivo model system [92]. Increased MAPK activation has been reported in retinal ischemia-reperfusion models [93,94], and recently, the JNK pathway has been shown to play a key role in retinal neovascularization in a mouse model of ROP [95]. It has since been demonstrated that LeTx delays the sprouting angiogenesis and branching morphogenesis during developmental vascularization in the murine retina [84], and appears to inhibit both neovascularization and revascularization following oxygen-induced retinopathy [96]. These data suggest that MAPK signaling pathways could be a source of novel targets for therapeutic intervention of ocular diseases that have an angiogenic component.