Assessment of Anopheles salivary antigens as individual exposure biomarkers to species-specific malaria vector bites.

BACKGROUND: Malaria transmission occurs during the blood feeding of infected anopheline mosquitoes concomitant with a saliva injection into the vertebrate host. In sub-Saharan Africa, most malaria transmission is due to Anopheles funestus s.s and to Anopheles gambiae s.l. (mainly Anopheles gambiae s.s. and Anopheles arabiensis). Several studies have demonstrated that the immune response against salivary antigens could be used to evaluate individual exposure to mosquito bites. The aim of this study was to assess the use of secreted salivary proteins as specific biomarkers of exposure to An. gambiae and/or An. funestus bites. METHODS: For this purpose, salivary gland proteins 6 (SG6) and 5'nucleotidases (5'nuc) from An. gambiae (gSG6 and g-5'nuc) and An. funestus (fSG6 and f-5'nuc) were selected and produced in recombinant form. The specificity of the IgG response against these salivary proteins was tested using an ELISA with sera from individuals living in three Senegalese villages (NDiop, n = 50; Dielmo, n = 38; and Diama, n = 46) that had been exposed to distinct densities and proportions of the Anopheles species. Individuals who had not been exposed to these tropical mosquitoes were used as controls (Marseille, n = 45). RESULTS: The IgG responses against SG6 recombinant proteins from these two Anopheles species and against g-5'nucleotidase from An. gambiae, were significantly higher in Senegalese individuals compared with controls who were not exposed to specific Anopheles species. Conversely, an association was observed between the level of An. funestus exposure and the serological immune response levels against the f-5'nucleotidase protein. CONCLUSION: This study revealed an Anopheles salivary antigenic protein that could be considered to be a promising antigenic marker to distinguish malaria vector exposure at the species level. The epidemiological interest of such species-specific antigenic markers is discussed.

Implication of haematophagous arthropod salivary proteins in host-vector interactions.

The saliva of haematophagous arthropods contains an array of anti-haemostatic, anti-inflammatory and immunomodulatory molecules that contribute to the success of the blood meal. The saliva of haematophagous arthropods is also involved in the transmission and the establishment of pathogens in the host and in allergic responses. This survey provides a comprehensive overview of the pharmacological activity and immunogenic properties of the main salivary proteins characterised in various haematophagous arthropod species. The potential biological and epidemiological applications of these immunogenic salivary molecules will be discussed with an emphasis on their use as biomarkers of exposure to haematophagous arthropod bites or vaccine candidates that are liable to improve host protection against vector-borne diseases.

Acquired resistance to trimethoprim-sulfamethoxazole during Whipple disease and expression of the causative target gene.

BACKGROUND: Whipple disease is a chronic infection caused by Tropheryma whipplei. Trimethoprim-sulfamethoxazole is recommended for treatment of Whipple disease but is associated with treatment failure. T. whipplei is resistant in vitro to trimethoprim, because the gene targeted by this agent is missing. METHODS: A patient experienced clinical failure during treatment with trimethoprim-sulfamethoxazole. The gene encoding the enzyme putatively believed to be dihydropteroate synthase (DHPS), the target of sulfamethoxazole, was amplified and sequenced for 20 T. whipplei strains from our laboratory and for isolates recovered from a case patient at the time of diagnosis and the time of treatment failure. An Escherichia coli knockout strain for this gene was complemented with the sequences from a susceptible strain and from isolates recovered from the case patient. Susceptibilities of complemented E. coli to sulfamethoxazole were tested. RESULTS: The target gene was identified among genes encoding a unique trifunctional enzyme in which DHPS is combined with the 2 preceding enzymes of the folate biosynthesis pathway. Changes in the amino acid sequence of putative DHPS were detected in the case patient. Gene complementation showed that the gene encoding putative DHPS restored the folate biosynthesis pathway and susceptibility to sulfamethoxazole, whereas the mutated sequence was associated with sulfamethoxazole resistance. CONCLUSIONS: Antibiotic susceptibility of fastidious bacteria such as T. whipplei can be evaluated by means of gene complementation techniques. Mutations in the target gene of sulfamethoxazole appear during treatment.