Phenotypic traits of individuals in a long-term colony of Anopheles (Nyssorhynchus) aquasalis (Diptera: Culicidae) show variable susceptibility to Plasmodium and suggest cryptic speciation.

Anopheles aquasalis is an important malaria vector in coastal regions of South America and islands of the Caribbean. In its original description, the species was divided into two varieties, based on the scaling patterns of their hind-tarsomere 2. Specimens from our 25-year established colony, used for Plasmodium experimental infections, still exhibit both scaling tarsomere patterns. This study examined the DNA sequence of the nuclear Internal Transcribed Spacer 2 (ITS2) and susceptibility to Plasmodium, looking for differences among the phenotypes 30BS and 50BS. One hundred mosquitoes, 25 males and 25 females of each sex, and phenotype were analyzed. Twenty-seven novel haplotypes were identified. Three were found in both phenotypes (30BS and 50BS) regardless of gender. Among the other 27 genotypes, we observed a male-oriented bias in both phenotypic categories. Evaluation of Plasmodium yoelii N67 infections, based on oocyst counts, showed a higher susceptibility of 30BS compared with 50BS. Future studies need to be conducted to evaluate if these genotype assortments among the phenotypic groups reflect differences in fitness, mating, and their susceptibility to infection by Plasmodium parasites.

Tripartite interactions: Leishmania, microbiota and Lutzomyia longipalpis.

The microbial consortium associated with sandflies has gained relevance, with its composition shifting throughout distinct developmental stages, being strongly influenced by the surroundings and food sources. The bacterial components of the microbiota can interfere with Leishmania development inside the sandfly vector. Microbiota diversity and host-microbiota-pathogen interactions regarding New World sandfly species have yet to be thoroughly studied, particularly in Lutzomyia longipalpis, the primary vector of visceral leishmaniasis in Brazil.The native microbiota of different developmental stages and physiological conditions of Lu. longipalpis (Lapinha Cave), was described by culturing and 16s rRNA gene sequencing. The 16s rRNA sequencing of culture-dependent revealed 13 distinct bacterial genera (Bacillus, Enterococcus, Erwinia, Enterobacter, Escherichia, Klebsiella, Lysinibacillus, Pseudocitrobacter, Providencia, Pseudomonas, Serratia, Staphylococcus and Solibacillus). The in vitro and in vivo effects of each one of the 13 native bacteria from the Lu. longipalpis were analyzed by co-cultivation with promastigotes of L.i. chagasi, L. major, L. amazonensis, and L. braziliensis. After 24 h of co-cultivation, a growth reduction observed in all parasite species. When the parasites were co-cultivated with Lysinibacillus, all parasites of L. infantum chagasi and L. amazonensis died within 24 hours. In the in vivo co-infection of L.chagasi, L. major and L. amazonensis with the genera Lysinibacillus, Pseudocitrobacter and Serratia it was possible to observe a significant difference between the groups co-infected with the bacterial genera and the control group.These findings suggest that symbiont bacteria (Lysinibacillus, Serratia, and Pseudocitrobacter) are potential candidates for paratransgenic or biological control. Further studies are needed to identify the nature of the effector molecules involved in reducing the vector competence for Leishmania.

Vertical Transmission of Zika Virus (Flaviviridae, Flavivirus) in Amazonian Aedes aegypti (Diptera: Culicidae) Delays Egg Hatching and Larval Development of Progeny.

Zika virus (ZIKV) has emerged as a globally important arbovirus and has been reported from all states of Brazil. The virus is primarily transmitted to humans through the bite of an infective Aedes aegypti (Linnaeus, 1762) or Aedes albopictus (Skuse, 1895). However, it is important to know if ZIKV transmission also occurs from Ae. aegypti through infected eggs to her offspring. Therefore, a ZIKV and dengue virus (DENV) free colony was established from eggs collected in Manaus and maintained until the third-fourth generation in order to conduct ZIKV vertical transmission (VT) experiments which used an infectious bloodmeal as the route of virus exposure. The eggs from ZIKV-infected females were allowed to hatch. The resulting F1 progeny (larvae, pupae, and adults) were quantitative polymerase chain reaction (qPCR) assayed for ZIKV. The viability of ZIKV vertically transmitted to F1 progeny was evaluated by cultivation in C6/36 cells. The effects of ZIKV on immature development of Ae. aegypti was assessed and compared with noninfected mosquitoes. AmazonianAe. aegypti were highly susceptible to ZIKV infection (96.7%), and viable virus passed to their progeny via VT. Moreover, eggs from the ZIKV-infected mosquitoes had a significantly lower hatch rate and the slowest hatching. In addition, the larval development period was slower when compared to noninfected, control mosquitoes. This is the first study to illustrate VT initiated by oral infection of the parental population by using mosquitoes, which originated from the field and a ZIKV strain that is naturally circulating in-country. Additionally, this study suggests that ZIKV present in the Ae. aegypti can modify the mosquito life cycle. The data reported here suggest that VT of ZIKV to progeny from naturally infected females may have a critical epidemiological role in the dissemination and maintenance of the virus circulating in the vector.

Bacterial diversity of wild-caught Lutzomyia longipalpis (a vector of zoonotic visceral leishmaniasis in Brazil) under distinct physiological conditions by metagenomics analysis.

BACKGROUND: The leishmaniases are a group of diseases caused by protozoans of the genus Leishmania, which are transmitted by the bite of phlebotomine sand flies. In the New World, Lutzomyia longipalpis is the most important vector of visceral leishmaniasis and is a proven vector for Leishmania infantum chagasi in Brazil. During development within the vector, Leishmania can interact with a variety of microorganisms such as fungi and bacteria. The presence of bacteria in the midgut of sand flies can influence the development and survival of the parasite. RESULTS: The bacteria-targeted metagenomic analysis revealed different community compositions between the distinct physiological stages of those tested. The amplicon-oriented metagenomic profiling revealed 64 bacterial genera and 46 families. By crossing the taxa indices from each experimental condition a core composed of 6 genera was identified (Enterobacter, Serratia, Stenotrophomonas, Enhydrobacter, Pseudomonas and Chryseobacterium). CONCLUSIONS: The observed dynamic nature of the bacterial community expands the knowledge pertaining to the tripartite host-microbiota-pathogen interactions. Further studies addressing how laboratory and field collected communities differ are critical to successfully develop control strategies based on bacterial symbionts and paratransgenesis, as already tested in other arthropod vectors.

Bacterial diversity of the American sand fly Lutzomyia intermedia using high-throughput metagenomic sequencing.

BACKGROUND: Parasites of the genus Leishmania cause a broad spectrum of diseases, collectively known as leishmaniasis, in humans worldwide. American cutaneous leishmaniasis is a neglected disease transmitted by sand fly vectors including Lutzomyia intermedia, a proven vector. The female sand fly can acquire or deliver Leishmania spp. parasites while feeding on a blood meal, which is required for nutrition, egg development and survival. The microbiota composition and abundance varies by food source, life stages and physiological conditions. The sand fly microbiota can affect parasite life-cycle in the vector. METHODS: We performed a metagenomic analysis for microbiota composition and abundance in Lu. intermedia, from an endemic area in Brazil. The adult insects were collected using CDC light traps, morphologically identified, carefully sterilized, dissected under a microscope and the females separated into groups according to their physiological condition: (i) absence of blood meal (unfed = UN); (ii) presence of blood meal (blood-fed = BF); and (iii) presence of developed ovaries (gravid = GR). Then, they were processed for metagenomics with Illumina Hiseq Sequencing in order to be sequence analyzed and to obtain the taxonomic profiles of the microbiota. RESULTS: Bacterial metagenomic analysis revealed differences in microbiota composition based upon the distinct physiological stages of the adult insect. Sequence identification revealed two phyla (Proteobacteria and Actinobacteria), 11 families and 15 genera; 87 % of the bacteria were Gram-negative, while only one family and two genera were identified as Gram-positive. The genera Ochrobactrum, Bradyrhizobium and Pseudomonas were found across all of the groups. CONCLUSIONS: The metagenomic analysis revealed that the microbiota of the Lu. intermedia female sand flies are distinct under specific physiological conditions and consist of 15 bacterial genera. The Ochrobactrum, Bradyrhizobium and Pseudomonas were the common genera. Our results detailing the constituents of Lu. intermedia native microbiota contribute to the knowledge regarding the bacterial community in an important sand fly vector and allow for further studies to better understand how the microbiota interacts with vectors of human parasites and to develop tools for biological control.

Genomic study of Anopheles (Nyssorhynchus) aquasalis, Curry 1932. A Neotropical human malaria vector

A malária humana é uma doença provocada por parasitas do gênero Plasmodium, os quais na natureza requerem de um mosquito anofelíno para completar o seu ciclo de vida e serem transmitidos a um hospedeiro humano. Nas Américas, o Brasil tem a maior incidência de malária, sendo responsável por 41% dos casos. Com o aparecimento do sequenciamento de nova geração e das ferramentas bioinformática relacionados, grandes avanços foram alcançados em relação à montagem de genomas e transcriptomas de anofelinos, assim como na exploração de estratégias de paratransgenesis para interromper a transmissão da malária. No entanto, os vetores neotropicais da malária encontram-se longe dos vetores da África e Ásia no que refere a estes conhecimentos. Este estudo é parte de um esforço contínuo para montar o genoma do Anopheles aquasalis, um vetor neotropical da malária humana, que atualmente posiciona-se como um excelente modelo de transmissão da malária no Brasil. Em paralelo ao sequenciamento do genoma, e para maximizar os dados gerados, optamos por focar em duas tarefas pontuais e viáveis: explorar a diversidade e composição do consórcio bacteriano associado ao anofelino; assim como montar e caracterizar o genoma mitocondrial desta espécie.

O sequenciamento metagenômico ̈shotgun ̈ e o programa MG-RAST foram utilizados para fazer um ̈screening ̈ das bactérias associadas à pupas de A .aquasalis criadas em laboratório. O consórcio bacteriano predito é composto por 74 gêneros contendo bactérias marinhas e bioluminescentes. No nível taxonômico de família bacteriana, identificamos 14 OTUs compartilhadas entre anofelinos americanos e africanos. Além disso, foram comparadas cinco comunidades bacterianas associadas a duas espécies de anofelinos: A. aquasalis e Anopheles gambiae. Foi identificada uma associação significativa (NPMANOVA p <0,05) entre a composição da comunidade bacteriana e o ambiente aquático (laboratório ou condições semi-naturais) nas quais cada hospedeiro anofelino foi criado. Atualmente, o entendimento da filogenia do gênero Anopheles é limitado e as informações sobre o tempo de divergência dentro da linhagem de mosquitos é escassa.

Apresentamos a sequencia de 15,393 pb correspondente ao genoma mitocondrial de A. aquasalis. Quando comparado com outros mitogenomas anofelinos relevantes, observou-se alta similaridade na composição dos genomas assim como características estruturais conservadas. Através de análises Bayesianas, reconstruímos as relações filogenéticas e estimamos a data de divergência entre 22 anofelinos e outras espécies de dípteros. Descobrimos que o mais recente ancestral entre as subfamílias Nyssorhynchus e Anopheles +Cellia existiu ~ 83 milhões anos atrás (MYA). Estimou-se que A. aquasalis divergiu do complexo do Anopheles albitarisis faz ~ 28 MYA, e faz ~ 38 MYA do Anopheles darlingi. A distribuição estreita e o peculiar nicho ecológico do A. aquasalis, além de considerar a sua adaptação a ambientes larvários com água salobra fizeram nos perguntar se a sua história evolutiva deixou uma marca na arquitetura do seu genoma, assim como sobre a estrutura da comunidade bacteriana associada a este anofelino.