Identification and characterization of antihemostatic components from hematophagous organisms are useful for the elucidation of the evolutionary mechanisms involved in adaptation to a highly complex host hemostatic system. Although many bioactive components involved in the regulation of the host's hemostatic system have been described, the evolutionary mechanisms of how arthropods adapted to a blood-feeding environment have not been elucidated. This study describes common origins of both blood coagulation inhibitors and platelet aggregation inhibitors (PAIs) from soft ticks of the genus Ornithodoros. Neighbor-joining analysis indicates that fXa, thrombin, and PAIs share a common ancestor. Maximum parsimony analysis and a phylogeny based on root mean square deviation values of alpha-carbon backbone structures suggest a novel evolutionary pathway by which different antihemostatic functions have evolved through a series of paralogous gene duplication events. In this scenario, the thrombin inhibitors preceded the fXa and PAIs. This evolutionary model explains why the tick serine protease inhibitors have inhibition mechanisms that differ from that of the canonical bovine pancreatic trypsin inhibitor (BPTI)-like inhibitors. Higher nonsynonymous-to-synonymous substitution rates indicate positive Darwinian selection for the fXa and PAIs. Comparison with hemostatic inhibitors of hard ticks suggests that the two main tick families have independently evolved novel antihemostatic mechanisms. Independent evolution of these mechanisms in ticks points to a rapid divergence between tick families that could be dated between 120 and 92 MYA. This coincides with current molecular phylogeny views on the early divergence of modern birds and placental mammals in the Late Cretaceous, which suggests that this event might have been a driving force in the evolution of hematophagy in ticks.
Savignygrin, a platelet aggregation inhibitor that possesses the RGD integrin recognition motif, has been purified from the soft tick Ornithodoros savignyi. Two isoforms with similar biological activities differ because of R52G and N60G in their amino acid sequences, indicating a recent gene duplication event. Platelet aggregation induced by ADP (IC 50 , 130 nM), collagen, the thrombin receptor-activating peptide, and epinephrine was inhibited, although platelets were activated and underwent a shape change. The binding of ␣-CD41 (P2) to platelets, the binding of purified ␣ IIb  3 to fibrinogen, and the adhesion of platelets to fibrinogen was inhibited, indicating a targeting of the fibrinogen receptor. In contrast, the adhesion of osteosarcoma cells that express the integrin ␣ v  3 to vitronectin or fibrinogen was not inhibited, indicating the specificity of savignygrin toward ␣ IIb  3 . Savignygrin shows sequence identity to disagregin, a platelet aggregation inhibitor from the tick Ornithodoros moubata that lacks an RGD motif. The cysteine arrangement of savignygrin is similar to that of the bovine pancreatic trypsin inhibitor family of serine protease inhibitors. A homology model based on the structure of the tick anticoagulant peptide indicates that the RGD motif is presented on the substrate-binding loop of the canonical BPTI inhibitors. However, savignygrin did not inhibit the serine proteases fXa, plasmin, thrombin, or trypsin. This is the first report of a platelet aggregation inhibitor that presents the RGD motif using the Kunitz-BPTI protein fold.Integrins are a family of adhesion receptors that propitiates cell-cell and cell-matrix interactions. Numerous physiological processes like hemostasis, fertilization, neuron-neuron interaction, and inflammation are mediated by integrins (1). The functional receptor is expressed as a transmembrane heterodimer consisting of ␣ and  subunits. To date, 17 ␣ and 8  subunits have been identified and form, in various permutations, more than 20 described integrins (2). Different combinations of subunits convey specificity for ligands (collagen-␣ 2  1 , fibronectin-␣ 5  1 , laminin-␣ 6  1 , vitronectin-␣ v  3 , and fibrinogen-␣ IIb  3 ), although ␣ IIb  3 can also recognize fibronectin, vitronectin, von Willebrand's factor, and prothrombin (2). Most ligands recognized by integrins contain the integrin recognition motif RGD (3). Some ligands may also contain other sequences recognized by integrins such as the dodecapeptide sequence HHLGGAKQAGDV from the ␥-chain of fibrinogen that binds to ␣ IIb  3 (4).␣ IIb  3 (GPIIbIIIa) is the major integrin of platelets and the only adhesion receptor capable of mediating platelet aggregation by the binding of fibrinogen or von Willebrand's factor (5-7). On resting platelets, ␣ IIb  3 exists in an inactive conformation that binds irreversibly to the ␥-chain C-terminal dodecapeptide (HHLGGAKQAGDV) of immobilized fibrinogen (5). The unactivated form also has a ligand-binding site accessible to small molecules that contain R...
Polyamines are ubiquitous components of all living cells, and their depletion usually causes cytostasis, a strategy employed for treatment of West African trypanosomiasis. To evaluate polyamine depletion as an anti-malarial strategy, cytostasis caused by the co-inhibition of S-adenosylmethionine decarboxylase/ ornithine decarboxylase in Plasmodium falciparum was studied with a comprehensive transcriptome, proteome, and metabolome investigation. Highly synchronized cultures were sampled just before and during cytostasis, and a novel zero time point definition was used to enable interpretation of results in lieu of the developmentally regulated control of gene expression in P. falciparum. Transcriptome analysis revealed the occurrence of a generalized transcriptional arrest just prior to the growth arrest due to polyamine depletion. However, the abundance of 538 transcripts was differentially affected and included three perturbation-specific compensatory transcriptional responses as follows: the increased abundance of the transcripts for lysine decarboxylase and ornithine aminotransferase and the decreased abundance of that for S-adenosylmethionine synthetase. Moreover, the latter two compensatory mechanisms were confirmed on both protein and metabolite levels confirming their biological relevance. In contrast with previous reports, the results provide evidence that P. falciparum responds to alleviate the detrimental effects of polyamine depletion via regulation of its transcriptome and subsequently the proteome and metabolome.Polyamines such as putrescine, spermidine, and spermine are small organic compounds containing two or more amino groups. At physiological pH, these polycations interact electrostatically with numerous anionic macromolecules, thereby stabilizing DNA, RNA, nucleoside triphosphates (e.g. ATP), phospholipids, and proteins (1, 2). These interactions with polyamines can alter DNA conformation, regulate replication and transcription, strengthen membranes, regulate ion channels, and protect DNA and phospholipids from oxidative stress (1-5). Yet polyamines are also implicated in apoptosis (5). Polyamine depletion generally causes cytostasis or growth arrest, which implies that these molecules are involved in cell cycle progression and regulation, and it is speculated that polyamines regulate cyclin degradation (1, 6, 7). Therefore, polyamines are essential for cellular growth, differentiation, and macromolecular synthesis and are ubiquitous components of all living cells, except two orders of Archaea (1). Polyamine metabolism is particularly important in rapidly proliferating cells and has been exploited in the treatment of cancer (1) and parasitic diseases (8). Polyamine metabolism of the malaria parasite Plasmodium falciparum is also a potential target for therapeutic intervention (9, 10).Polyamine and methionine metabolism are closely connected. This is particularly evident in Plasmodium where the two rate-limiting enzymes of polyamine biosynthesis, ornithine decarboxylase (ODC) 2 and S-adenosylme...
The origins of tick toxicoses remain a subject of controversy because no molecular data are yet available to study the evolution of tick-derived toxins. In this study we describe the molecular structure of toxins from the soft tick, Ornithodoros savignyi. The tick salivary gland proteins (TSGPs) are four highly abundant proteins proposed to play a role in salivary gland granule biogenesis of the soft tick O. savignyi, of which the toxins TSGP2 and TSGP4 are a part. They were assigned to the lipocalin family based on sequence similarity to known tick lipocalins. Several other tick lipocalins were also identified using Smith-Waterman database searches, bringing the tick lipocalin family up to 20. Phylogenetic analysis showed that most tick lipocalins group within genus-specific clades, suggesting that gene duplication and divergence of tick lipocalin function occurred after tick speciation, most probably during the evolution of a hematophagous lifestyle. TSGP2 and TSGP3 show high sequence identity and group terminal to moubatin, an inhibitor of collagen-induced platelet aggregation from the tick, O. moubata. However, no platelet aggregation inhibitory activity is associated with the TSGPs using ADP or collagen as agonists, suggesting that TSGP2 and TSGP3 duplicated after divergence of O. savignyi and O. moubata. This timing is supported by the absence of TSGP2-4 in the salivary gland extracts of O. moubata. The absence of TSGP2 and TSGP4 in salivary gland extracts from O. moubata correlates with the nontoxicity of this tick species. The implications of this study are that the various forms of tick toxicoses do not have a common origin, but must have evolved independently in those tick species that cause pathogenesis.
Malaria remains the world's most devastating tropical infectious disease with as many as 40% of the world population living in risk areas. The widespread resistance of Plasmodium parasites to the costeffective chloroquine and antifolates has forced the introduction of more costly drug combinations, such as Coartem ® . In the absence of a vaccine in the foreseeable future, one strategy to address the growing malaria problem is to identify and characterize new and durable antimalarial drug targets, the majority of which are parasite proteins. Biochemical and structure-activity analysis of these proteins is ultimately essential in the characterization of such targets but requires large amounts of functional protein. Even though heterologous protein production has now become a relatively routine endeavour for most proteins of diverse origins, the functional expression of soluble plasmodial proteins is highly problematic and slows the progress of antimalarial drug target discovery. Here the status quo of heterologous production of plasmodial proteins is presented, constraints are highlighted and alternative strategies and hosts for functional expression and annotation of plasmodial proteins are reviewed.
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