The role of salivary lipocalins in blood feeding by Rhodnius prolixus

In order to overcome host mechanisms that prevent blood loss, the blood-sucking bug Rhodnius prolixus has evolved a complex salivary secretion containing dozens of different proteins. A number of these have been characterized and found to have roles in inhibiting various hemostatic or inflammatory systems. Interestingly, many of these biologically active salivary proteins belong to the lipocalin protein family. A proliferation of lipocalin genes has occurred via gene duplication and subsequent divergence. Functional genomic, proteomic, and functional studies have been performed to probe the role of salivary lipocalins in blood feeding. In the course of these investigations, anticoagulant, antiplatelet, antiinflammatory, and vasodilatory molecules have been described.     

Nitrophorin synthesis is modulated by protein kinase CK2

Rhodnius prolixus is a blood-sucking bug whose saliva contains a family of nitric oxide-carrying proteins named nitrophorins (NPs). Saliva is injected into the host bloodstream during insect feeding. Nitric oxide is then released from NPs and will act on vascular smooth muscle, promoting vasodilation. Epithelial cells of salivary glands then undergo a massive synthesis of antihemostatics including NPs which produces saliva for the next blood meal. Here, we demonstrate the transient activation of a protein kinase in the salivary glands of R. prolixus after a blood meal. Biochemical, immunological, and pharmacological assays were used to identify this enzyme as protein kinase CK2. CK2 is activated after a blood meal and decreases to basal levels when salivary gland refilling is resumed. Inhibition of CK2 blocked [(35)S]methionine incorporation into newly synthesized salivary gland proteins in cultured tissue. Dissected salivary glands were then incubated with the heme fluorescent analog palladium (II) mesoporphyrin IX (Pd-MP) in the presence of a selective cell-permeable CK2 inhibitor, TBB (4,5,6,7-tetrabromobenzotriazole). NP synthesis was quantified based on fluorescence of the Pd-MP group bound to the NP heme pocket. TBB dramatically blocked NP synthesis. Altogether, these data are the first demonstration to show that antihemostatic synthesis in a blood-sucking arthropods is under protein phosphorylation control.     

Overexpression in Escherichia coli and functional reconstitution of the liposome binding ferriheme protein nitrophorin 7 from the bloodsucking bug Rhodnius prolixus

A number of ferriheme proteins, termed nitrophorins (NPs), occur in the saliva of the bloodsucking insect Rhodnius prolixus ('kissing bug'), which is a vector for Chagas' disease. Nitrophorins bind the heme b cofactor in the beta-barrel of their lipocalin fold, which is further anchored through a proximal histidine-Fe(III) bond. The distal Fe(III) coordination site then binds nitric oxide (NO) for delivery into a host's tissues during blood feeding, where, upon NO release, the distal Fe(III) site acts as a histamine trap to delay the victim's immune response. Previously, four nitrophorins from R. prolixus, NP1 to NP4, have been extensively characterized. Recently, another nitrophorin, NP7, was discovered in a cDNA library derived from the same insect. Among the R. prolixus nitrophorins, NP7 was found to be unique in its ability to bind to negatively charged cell surfaces. However, the yield of functional recombinant NP7 was rather low when the established protocol for NP1-4 was followed. Here, we report on a novel expression and reconstitution method for NP7 that yields sufficient amounts of pure protein for extensive characterization (28-fold increase). This method may prove useful for the reconstitution of other proteins with a lipocalin fold.     

A missing metabolic pathway in the cattle tick Boophilus microplus.

Heme proteins are involved in a wide variety of biological reactions, including respiration, oxygen transport and oxygen metabolism [1]. The heme prosthetic group is synthesized in almost all living organisms except for a few pathogenic bacteria and trypanosomatids that use blood as food [2] [3]. There is a general belief that all nucleated animal cells synthesize heme [1] [4]. However, blood-feeding arthropods ingest enormous amounts of vertebrate blood in a single meal and the heme pathway has not been studied in these animals. We have examined heme synthesis in two hematophagous arthropods - the blood-sucking bug Rhodnius prolixus and the cattle tick Boophilus microplus. We show that R. prolixus makes heme and has a fully operative heme biosynthetic pathway, while B. microplus does not. To our knowledge, this is the first report of an animal that does not synthesize its own heme and relies solely on the recovery of heme present in the diet. Because of the inability of Boophilus to synthesize heme and its ability to deal efficiently with large amounts of free heme, we propose this organism as a good model for studying heme transport and reutilization in animal cells.     

Function and evolution of a mosquito salivary protein family

Saliva of blood-sucking arthropods contains a complex and diverse mixture of antihemostatic, antiinflammatory, and immunomodulatory compounds. The D7 salivary family of proteins is abundantly expressed in blood-feeding Diptera and is distantly related to the odorant-binding protein superfamily. In mosquitoes, two subfamilies exist, the long and short D7 proteins. Ticks and kissing bugs evolved salivary lipocalins that act as efficient scavengers of biogenic amines, and a similar function was postulated for the D7 proteins. Accordingly, we expressed the five members of the small D7 family of the African malaria vector Anopheles gambiae and a D7 long form from Aedes aegypti and showed by isothermal microcalorimetry, a modified and very sensitive non-equilibrium chromatography/spectrum distortion method, and by smooth muscle bioassay that four of these five short D7 proteins and the D7 long form bind serotonin with high affinity, as well as histamine and norepinephrine. The nonbinding D7 protein is poorly expressed in the salivary glands and appears to be on the path to becoming a pseudogene. Scavenging of host amines would antagonize their vasoconstrictor, platelet-aggregating, and pain-inducing properties. It appears that counteracting biogenic amines is of strong adaptive value in the convergent evolution of arthropods to hematophagy. This adaptation has been solved independently in ticks, bugs, and mosquitoes by co-option of either member of the lipocalin or, as shown here, by the odorant-binding protein families.     

Oligomerization of nitrophorins

Rhodnius prolixus is a blood-sucking insect that uses a mixture of nitrophorin (NP) proteins to deliver nitric oxide (NO) from the insect saliva to the hosts via a ferric heme coordinated to the protein, causing vasodilatation and anticoagulation to support their feeding. R. prolixus NPs 1-4 are very similar proteins ( approximately 20 kDa) with different NO affinities for stepwise NO release triggered by pH increase and histamine binding in hosts. Ultra-high-resolution X-ray structures of native and mutant NPs and their kinetic analysis already have revealed the fundamental steps of NO binding and release. In this study, we found that NPs can exist in multiple oligomerization states at higher concentrations. The oligomers are characterized by a combination of multiple biophysical methods. The intrinsic features of the oligomerization revealed here led us to propose that this intensive, moderately pH- and ligand-dependent oligomerization of NPs has physiological implications in the facilitation of the efficient storage and release of the highly reactive NO in the insect saliva and the victim, respectively.     

Protein-segment universe exhibiting transitions at intermediate segment length in conformational subspaces

Background

Lipocalins are widely distributed in nature and are found in bacteria, plants, arthropoda and vertebra. In hematophagous arthropods, they are implicated in the successful accomplishment of the blood meal, interfering with platelet aggregation, blood coagulation and inflammation and in the transmission of disease parasites such as Trypanosoma cruzi and Borrelia burgdorferi. The pairwise sequence identity is low among this family, often below 30%, despite a well conserved tertiary structure. Under the 30% identity threshold, alignment methods do not correctly assign and align proteins. The only safe way to assign a sequence to that family is by experimental determination. However, these procedures are long and costly and cannot always be applied. A way to circumvent the experimental approach is sequence and structure analyze. To further help in that task, the residues implicated in the stabilisation of the lipocalin fold were determined. This was done by analyzing the conserved interactions for ten lipocalins having a maximum pairwise identity of 28% and various functions.

Results

It was determined that two hydrophobic clusters of residues are conserved by analysing the ten lipocalin structures and sequences. One cluster is internal to the barrel, involving all strands and the 3₁₀ helix. The other is external, involving four strands and the helix lying parallel to the barrel surface. These clusters are also present in RaHBP2, a unusual "outlier" lipocalin from tick Rhipicephalus appendiculatus. This information was used to assess assignment of LIR2 a protein from Ixodes ricinus and to build a 3D model that helps to predict function. FTIR data support the lipocalin fold for this protein.

Conclusion

By sequence and structural analyzes, two conserved clusters of hydrophobic residues in interactions have been identified in lipocalins. Since the residues implicated are not conserved for function, they should provide the minimal subset necessary to confer the lipocalin fold. This information has been used to assign LIR2 to lipocalins and to investigate its structure/function relationship. This study could be applied to other protein families with low pairwise similarity, such as the structurally related fatty acid binding proteins or avidins.     

Purification, cloning, expression, and mechanism of action of a novel platelet aggregation inhibitor from the salivary gland of the blood-sucking bug, Rhodnius prolixus

Rhodnius prolixus aggregation inhibitor 1 (RPAI-1), a 19-kDa protein isolated from the salivary gland of R. prolixus, was purified by strong cation exchange and reverse-phase high performance liquid chromatographies. Based on 49 amino-terminal amino acid sequences of RPAI-1, primers were produced to generate probes to screen an R. prolixus salivary gland cDNA library. A phage containing the full-length clone of RPAI-1 codes for a mature protein of 155 amino acids. RPAI-1 shows sequence homology to triabin and pallidipin, lipocalins from Triatoma pallidipennis. The cDNA sequence was cloned in Pet17B Escherichia coli expression vector, producing an active peptide. RPAI-1 inhibits human platelet-rich plasma aggregation triggered by low concentrations of ADP, collagen, arachidonic acid, thromboxane A(2) mimetics (U46619), and very low doses of thrombin and convulxin. Here we show that ADP is the target of RPAI-1 since (i) RPAI-1 inhibits ADP-dependent large aggregation formation and secretion triggered by U46619, without affecting Ca(2+) increase and shape change; (ii) ADP restored the inhibition of U46619-induced platelet aggregation by RPAI-1, (iii) PGE(1)-induced increase of cAMP (which is antagonized by U46619 in an ADP-dependent manner) was restored by RPAI-1, (iv) RPAI-1 inhibits low concentrations of ADP-mediated responses of indomethacin-treated platelets, and (v) RPAI-1 binds to ADP, as assessed by large zone chromatography. RPAI-1 affects neither integrin alpha(2)beta(1)- nor glycoprotein VI-mediated platelet responses. We conclude that RPAI-1 is the first lipocalin described that inhibits platelet aggregation by a novel mechanism, binding to ADP.     

Exploring the sialome of the blood-sucking bug Rhodnius prolixus

Rhodnius prolixus is a Hemiptera that feeds exclusively on vertebrate blood in all life stages. Its salivary glands produce potent pharmacological substances that counteract host hemostasis, including anti-clotting, anti-platelet, and vasodilatory substances. To obtain a further insight into the salivary biochemical and pharmacological complexity of this insect, a cDNA library was randomly sequenced, and salivary gland homogenates were fractionated by HPLC to obtain aminoterminal sequences of abundantly expressed proteins. Results indicate a remarkable expansion of the lipocalin family in Rhodnius salivary glands, among other protein sequences described. A summary of 31 new full length proteins deducted from their mRNA sequence is described, including several new members of the nitrophorin, triabin, and pallidipin families. The electronic version of the complete tables is available at http://www.ncbi.nlm.nih.gov/projects/vectors/rhodnius_prolixus.     

Nitrophorins: nitrite disproportionation reaction and other novel functionalities of insect heme-based nitric oxide transport proteins

Nitrophorins (NPs) comprise a unique class of heme proteins used by the blood-sucking insect Rhodnius prolixus to deliver the signaling gas molecule NO into the blood vessel of a host during feeding. Upon NO release, histamine can be scavenged by coordination to the heme iron. Although the protein is of similar size as the mammalian globin monomers and shares the same cofactor and proximal histidine coordination, nitrophorin structure, in contrast, is almost entirely composed of a β-barrel. Comparison of the NO and histamine association constants with the concentrations of both compounds invivo raises concerns about the very simple ligand release model in case of at least some of the NPs. Therefore, novel functionalities of the NPs were sought. As a result, catalysis of the nitrite disproportionation reaction was found, which leads to the formation of NO with nitrite as the sole substrate. This is the first example of a ferriheme protein that can perform this reaction. Furthermore, although NPs stabilize the ferriheme state, a peroxidase reactivity of the cofactor involving the higher oxidation state iron (Compound I/II) was studied with the potential to catalyze the oxidation of histamine and norepinephrine. In contrast to many other heme proteins including the globins, the ferroheme state was found to be extremely sensitive to O(2) , which is a consequence of the much lower reduction potential of the NPs, so that the 1-electron reduction of O(2) to O (?-)(2) becomes a thermodynamically favored process. Altogether, the detailed study of the NPs gives insight into the structure-function relationships required for the targeted delivery of diatomic gas molecules in biology. Moreover, the comparison of the structure-function relationships of the NPs (NO transporters) with those of the globins (O(2) transporters) will help to elucidate the architectural requirement for the respective tasks.     

Structure, function, and evolution of biogenic amine-binding proteins in soft ticks

Two highly abundant lipocalins, monomine and monotonin, have been isolated from the salivary gland of the soft tick Argas monolakensis and shown to bind histamine and 5-hydroxytryptamine (5-HT), respectively. The crystal structures of monomine and a paralog of monotonin were determined in the presence of ligands to compare the determinants of ligand binding. Both the structures and binding measurements indicate that the proteins have a single binding site rather than the two sites previously described for the female-specific histamine-binding protein (FS-HBP), the histamine-binding lipocalin of the tick Rhipicephalus appendiculatus. The binding sites of monomine and monotonin are similar to the lower, low affinity site of FS-HBP. The interaction of the protein with the aliphatic amine group of the ligand is very similar for the all of the proteins, whereas specificity is determined by interactions with the aromatic portion of the ligand. Interestingly, protein interaction with the imidazole ring of histamine differs significantly between the low affinity binding site of FS-HBP and monomine, suggesting that histamine binding has evolved independently in the two lineages. From the conserved features of these proteins, a tick lipocalin biogenic amine-binding motif could be derived that was used to predict biogenic amine-binding function in other tick lipocalins. Heterologous expression of genes from salivary gland libraries led to the discovery of biogenic amine-binding proteins in soft (Ornithodoros) and hard (Ixodes) tick genera. The data generated were used to reconstruct the most probable evolutionary pathway for the evolution of biogenic amine-binding in tick lipocalins.     

Kinetics and equilibria in ligand binding by nitrophorins 1-4: evidence for stabilization of a nitric oxide-ferriheme complex through a ligand-induced conformational trap

Nitrophorins 1-4 (NP1-4) are ferriheme proteins from the blood-sucking insect Rhodnius prolixus that transport nitric oxide (NO) to the victim, sequester histamine, and inhibit blood coagulation. Here, we report kinetic and thermodynamic analyses for ligand binding by all four proteins and their reduction potentials. All four undergo biphasic association and dissociation reactions with NO. The initial association is fast (1.5-33 microM(-)(1) s(-)(1)) and similar to that of elephant metmyoglobin. However, unlike in metmyoglobin, a slower second phase follows ( approximately 50 s(-)(1)), and the stabilized final complexes are resistant to autoreduction (E degrees = +3 to +154 mV vs normal hydrogen electrode). NO dissociation begins with a slow, pH-dependent step (0.02-1.4 s(-)(1)), followed by a faster phase that is again similar to that of metmyoglobin (3-52 s(-)(1)). The equilibrium dissociation constants are quite small (1-850 nM). NP1 and NP4 display larger release rate constants and smaller association rate constants than NP2 and NP3, leading to values for K(d) that are about 10-fold greater. The results are discussed in light of the recent crystal structures of NP1, NP2, and NP4, which display open, polar distal pockets, and of NP4-NO, which displays an NO-induced conformational change that leads to expulsion of solvent and complete burial of the NO ligand in a now nonpolar distal pocket. Taken together, the results suggest that tighter NO binding in the nitrophorins is due to the trapping of the molecule in a nonpolar distal pocket rather than through formation of particularly strong Fe-NO or hydrogen bonds.     

Biochemical and functional characterization of recombinant Rhodnius prolixus platelet aggregation inhibitor 1 as a novel lipocalin with high affinity for adenosine diphosphate and other adenine nucleotides

The Rhodnius prolixus aggregation inhibitor 1 (RPAI-1) is a novel blood-sucking salivary molecule that binds to ADP and attenuates platelet aggregation. In this report, we determine the binding constants and specificity of RPAI-1 for adenine nucleotides and its functional significance. By the Hummel-Dreyer method of equilibrium gel filtration, we show that RPAI-1 binds ADP with a K(0.5) of 48.6 plus minus 12.2 nM. RPAI-1 also displays high-affinity binding to ATP, AMP, Ado, AP4A, and alpha,beta Met ADP; however, RPAI-1 does not bind to inosine, guanosine, uridine, or cytidine. Binding is not modified by EDTA, indicating that Ado structure but not phosphate groups or Ca(2+) is necessary for binding. By computer simulation, we show that RPAI-1 is more effective in scavenging low but not high concentrations of ADP, in contrast to R. prolixus apyrase. RPAI-1 inhibits in vitro the ADP-dependent platelet-rich plasma aggregation by collagen (COLL), TRAP, PAF, and A23187 but did not block platelet aggregation by ristocetin or phorbol myristate acetate (PMA) and only slightly attenuated that by convulxin. RPAI-1 prolongs the closure time as assessed with PFA-100, when COLL-Epi but not COLL-ADP cartridges are employed. RPAI-1 also affects platelet-mediated hemostasis time and COLL-induced thrombus formation at high shear as assessed with the Clot Signature Analyzer. We conclude that RPAI-1 exerts an antiplatelet effect due to scavenging of low concentrations of ADP in vitro and in vivo. RPAI-1 is the first lipocalin described so far with unique specificity for adenine nucleotides.     

Ligand-induced heme ruffling and bent no geometry in ultra-high-resolution structures of nitrophorin 4

The nitrophorins are a family of proteins that use ferric heme to transport nitric oxide (NO) from the salivary glands of blood-sucking insects to their victims, resulting in vasodilation and reduced blood coagulation. We have refined atomic resolution structures of nitrophorin 4 (NP4) from Rhodnius prolixus complexed with NO (1.08 A) and NH(3) (1.15 A), yielding a highly detailed picture of the iron coordination sphere. In NP4-NO, the NO nitrogen is coordinated to iron (Fe-N distance = 1.66 A) and is somewhat bent (Fe-N-O angle = 156 degrees ), with bending occurring in the same plane as the proximal histidine ring. The Fe(NO)(heme)(His) coordination geometry is unusual but consistent with an Fe(III) oxidation state that is stabilized by a highly ruffled heme. Heme ruffling occurs in both structures, apparently due to close contacts between the heme and leucines 123 and 133, but increases on binding NO even though the steric contacts have not changed. We also report the structure of NP4 in complexes with histamine (1.50 A) and imidazole (1.27 A). Unexpectedly, two mobile loops that rearrange to pack against the bound NO in NP4-NO, also rearrange in the NP4-imidazole complex. This conformational change is apparently driven by the nonpolar nature of the NO and imidazole (as bound) ligands. Taken together, the desolvation of the NO binding pocket through a change in protein conformation, and the bending of the NO moiety, possibly through protein-assisted heme ruffling, may lead to a nitrosyl-heme complex that is unusually resistant to autoreduction.     

Insect natural products and processes: new treatments for human disease

In this overview, some of the more significant recent developments in bioengineering natural products from insects with use or potential use in modern medicine are described, as well as in utilisation of insects as models for studying essential mammalian processes such as immune responses to pathogens. To date, insects have been relatively neglected as sources of modern drugs although they have provided valuable natural products, including honey and silk, for at least 4-7000 years, and have featured in folklore medicine for thousands of years. Particular examples of Insect Folk Medicines will briefly be described which have subsequently led through the application of molecular and bioengineering techniques to the development of bioactive compounds with great potential as pharmaceuticals in modern medicine. Insect products reviewed have been derived from honey, venom, silk, cantharidin, whole insect extracts, maggots, and blood-sucking arthropods. Drug activities detected include powerful antimicrobials against antibiotic-resistant bacteria and HIV, as well as anti-cancer, anti-angiogenesis and anti-coagulant factors and wound healing agents. Finally, the many problems in developing these insect products as human therapeutic drugs are considered and the possible solutions emerging to these problems are described.     

Harmfulness of parasitic insects and acarines to mammals and birds

The paper summarizes the results of investigations on the harmfulness of the blood-sucking arthropods and ectoparasites to terrestrial vertebrates. Pathogenicity of parasitic arthropods strongly depends on the type of parasitism. Harmfulness to the hosts is analyzed separately in blood-sucking dipterans, ixodid ticks, gadflies, and both temporary (fleas and bugs) and permanent (biting lice, lice, acariform mites) ectoparasites. The pathogenicity of parasitic arthropods for the host organism is conditioned by the direct loss of blood and tissues, toxic effect of the arthropod’s saliva, and allergic reactions. Indirect injury from parasites is associated with deterioration of the host’s nutrition and loss of weight and viability. Pathogenicity for the host not resulting in its death is typical of parasitic arthropods, except for heavy attacks by blood-sucking Diptera which may lead to death of domesticated and wild animals. Most data on the pathogenicity of arthropods for vertebrates refer to domesticated animals. Annual losses to the world livestock breeding attributed to insects and acarines amount to several billion dollars. Direct evidence of ectoparasite pathogenicity to wild animals and effect on the host’s vital functions, reproduction, and population numbers in particular, is limited and unconvincing.     

Comparative sialomics between hard and soft ticks: implications for the evolution of blood-feeding behavior

Ticks evolved various mechanisms to modulate their host's hemostatic and immune defenses. Differences in the anti-hemostatic repertoires suggest that hard and soft ticks evolved anti-hemostatic mechanisms independently, but raise questions on the conservation of salivary gland proteins in the ancestral tick lineage. To address this issue, the sialome (salivary gland secretory proteome) from the soft tick, Argas monolakensis, was determined by proteomic analysis and cDNA library construction of salivary glands from fed and unfed adult female ticks. The sialome is composed of approximately 130 secretory proteins of which the most abundant protein folds are the lipocalin, BTSP, BPTI and metalloprotease families which also comprise the most abundant proteins found in the salivary glands. Comparative analysis indicates that the major protein families are conserved in hard and soft ticks. Phylogenetic analysis shows, however, that most gene duplications are lineage specific, indicating that the protein families analyzed possibly evolved most of their functions after divergence of the two major tick families. In conclusion, the ancestral tick may have possessed a simple (few members for each family), but diverse (many different protein families) salivary gland protein domain repertoire.