Last data update: Jan 27, 2025. (Total: 48650 publications since 2009)
Records 1-8 (of 8 Records) |
Query Trace: Bascunan P[original query] |
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Anopheles adult anesthesia, feeding, and sex separation
Leite LN , Bascuñán P , Dotson EM , Benedict MQ . Cold Spring Harb Protoc 2023 The adult stage is the only nonaquatic stage of the Anopheles mosquito. Both male and female Anopheles mosquitoes require access to a source of sugar to survive. In the insectary, a temperature of ∼27°C and 80% relative humidity and a cycle of 12 h light:12 h dark light, ideally with a sunrise and sunset period, are necessary minimum conditions to mimic their natural environment. Laboratory-reared Anopheles can survive for over a month; however, decreased activity and increased mortality may be observed ∼2 wk postemergence depending on the species and health of the colony. Details on how to maintain adults Anopheles are discussed here. Information and considerations on blood and sugar feeding are described. This protocol also provides instructions on how to differentiate male and female adult mosquitoes. |
Anopheles larval rearing
Leite LN , Bascuñán P , Dotson EM , Benedict MQ . Cold Spring Harb Protoc 2023 Mosquito larvae are aquatic and go through four development stages (larval instars L1-L4) before pupation. Species vary in the duration of larval development, and a variety of external factors affect the development rate (e.g., water temperature, food type, and larval density), which are discussed more thoroughly elsewhere. Here, we detail how to rear Anopheles larvae. This protocol describes appropriate distribution of larvae into rearing pans, feeding of larvae, cleaning of pans, and care until pupation. |
Considerations for rearing and maintaining anopheles in the laboratory
Leite LN , Bascuñán P , Dotson EM , Benedict MQ . Cold Spring Harb Protoc 2023 Anopheles mosquitoes can transmit several human pathogens, including viruses such as o'nyong-nyong and parasites including Plasmodium spp. and Wuchereria spp., which cause malaria and filariasis, respectively. Rearing Anopheles species of medical importance under laboratory conditions allows researchers to carry out experiments to better understand their genetics, physiology, and behavior. However, Anopheles species vary in how easily they can be reared in the laboratory, and some species have been difficult to colonize. Once established, members of the important African Anopheles gambiae complex thrive following a standard protocol and are predictable in growth and development rates. Here, we provide useful basic information and guidance to successfully maintain colonies of A. gambiae and other species of Anopheles in a laboratory setting. We also provide an example of a 3-wk rearing schedule that produces sufficient numbers of mosquitoes while minimizing the work required during weekends. In the accompanying protocols, we detail efficient methods and techniques suitable for several species of this genus at the egg, larva, pupae, and adult stages; however, it will be necessary for researchers to adjust methods as needed based on site-specific rearing observations of their particular strains. |
Anopheles egg collection, disinfection, and hatching
Leite LN , Bascuñán P , Dotson EM , Benedict MQ . Cold Spring Harb Protoc 2023 Gravid (i.e., with fully developed eggs), mated Anopheles females typically lay their eggs directly on water ∼48-72 h after a blood meal. Unlike some other mosquito species, Anopheles eggs cannot be desiccated and stored for long durations, and, hence, colonies must be reared continuously. In this protocol, we discuss methods for egg collection, including individual and en masse oviposition; egg disinfection to avoid the transmission of infectious agents to the next generation; and egg hatching for colony maintenance or experimentation. We also include optional methods for estimating life history traits such as fecundity, fertility, and larval mortality rates from egg counts. |
Anopheles pupa collection and sex identification
Leite LN , Bascuñán P , Dotson EM , Benedict MQ . Cold Spring Harb Protoc 2023 For most Anopheles species, larval-pupal metamorphosis commences ∼1 wk after egg hatching. However, depending on the amount of food provided, H(2)O temperature, and larval density, the pupation process can be accelerated or delayed. Synchronous pupation is difficult to accomplish consistently, and, thus, pupae need to be separated from larvae daily. Adult emergence will take place 24-48 h after pupation. Most adults will eclose before the next morning (light cycle) in many species. Here, we provide information on some methods available to collect pupae and to sort pupae by sex. Notably, pupa collection and sorting are some of the most time-consuming procedures of the overall mosquito rearing process. Some methods mentioned here attempt to help reduce work effort and time required. |
Mosquito microevolution drives Plasmodium falciparum dynamics.
Gildenhard M , Rono EK , Diarra A , Boissière A , Bascunan P , Carrillo-Bustamante P , Camara D , Krüger H , Mariko M , Mariko R , Mireji P , Nsango SE , Pompon J , Reis Y , Rono MK , Seda PB , Thailayil J , Traorè A , Yapto CV , Awono-Ambene P , Dabiré RK , Diabaté A , Masiga D , Catteruccia F , Morlais I , Diallo M , Sangare D , Levashina EA . Nat Microbiol 2019 4 (6) 941-947 ![]() ![]() Malaria, a major cause of child mortality in Africa, is engendered by Plasmodium parasites that are transmitted by anopheline mosquitoes. Fitness of Plasmodium parasites is closely linked to the ecology and evolution of its anopheline vector. However, whether the genetic structure of vector populations impacts malaria transmission remains unknown. Here, we describe a partitioning of the African malaria vectors into generalists and specialists that evolve along ecological boundaries. We next identify the contribution of mosquito species to Plasmodium abundance using Granger causality tests for time-series data collected over two rainy seasons in Mali. We find that mosquito microevolution, defined by changes in the genetic structure of a population over short ecological timescales, drives Plasmodium dynamics in nature, whereas vector abundance, infection prevalence, temperature and rain have low predictive values. Our study demonstrates the power of time-series approaches in vector biology and highlights the importance of focusing local vector control strategies on mosquito species that drive malaria dynamics. |
Mating-regulated atrial proteases control reinsemination rates in Anopheles gambiae females.
Bascuñán P , Gabrieli P , Mameli E , Catteruccia F . Sci Rep 2020 10 (1) 21974 ![]() Anopheles gambiae mosquitoes are the most important vectors of human malaria. The reproductive success of these mosquitoes relies on a single copulation event after which the majority of females become permanently refractory to further mating. This refractory behavior is at least partially mediated by the male-synthetized steroid hormone 20-hydroxyecdysone (20E), which is packaged together with other seminal secretions into a gelatinous mating plug and transferred to the female atrium during mating. In this study, we show that two 20E-regulated chymotrypsin-like serine proteases specifically expressed in the reproductive tract of An. gambiae females play an important role in modulating the female susceptibility to mating. Silencing these proteases by RNA interference impairs correct plug processing and slows down the release of the steroid hormone 20E from the mating plug. In turn, depleting one of these proteases, the Mating Regulated Atrial Protease 1 (MatRAP1), reduces female refractoriness to further copulation, so that a significant proportion of females mate again. Microscopy analysis reveals that MatRAP1 is localized on a previously undetected peritrophic matrix-like structure surrounding the mating plug. These data provide novel insight into the molecular mechanisms shaping the post-mating biology of these important malaria vectors. |
Trials of the automated particle counter for laboratory rearing of mosquito larvae
Benedict MQ , Bascuñán P , Hunt CM , Aviles EI , Rotenberry RD , Dotson EM . PLoS One 2020 15 (11) e0241492 As a means of obtaining reproducible and accurate numbers of larvae for laboratory rearing, we tested a large-particle flow-cytometer type device called the 'Automated Particle Counter' (APC). The APC is a gravity-fed, self-contained unit that detects changes in light intensity caused by larvae passing the detector in a water stream and controls dispensing by stopping the flow when the desired number has been reached. We determined the accuracy (number dispensed compared to the target value) and precision (distribution of number dispensed) of dispensing at a variety of counting sensitivity thresholds and larva throughput rates (larvae per second) using < 1-day old Anopheles gambiae and Aedes aegypti larvae. All measures were made using an APC algorithm called the 'Smoothed Z-Score' which allows the user to define how many standard deviations (Z scores) from the baseline light intensity a particle's absorbance must exceed to register a count. We dispensed a target number of 100 An. gambiae larvae using Z scores from 2.5-8 and observed no difference among them in the numbers dispensed for scores from 2.5-6, however, scores of 7 and 8 under-counted (over-dispensed) larvae. Using a Z score ≤ 6, we determined the effect of throughput rate on the accuracy of the device to dispense An. gambiae larvae. For rates ≤ 98 larvae per second, the accuracy of dispensing a target of 100 larvae was - 2.29% ± 0.72 (95% CI of the mean) with a mode of 99 (49 of 348 samples). When using a Z score of 3.5 and rates ≤ 100 larvae per second, the accuracy of dispensing a target of 100 Ae. aegypti was - 2.43% ± 1.26 (95% CI of the mean) with a mode of 100 (6 of 42 samples). No effect on survival was observed on the number of An. gambiae first stage larvae that reached adulthood as a function of dispensing. |
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