12 research outputs found
Evaluation of radiation sensitivity and mating performance of Glossina brevipalpis males
BACKGROUND : Area-wide integrated pest management strategies that include a sterile insect technique
component have been successfully used to eradicate tsetse fly populations in the past. To
ensure the success of the sterile insect technique, the released males must be adequately
sterile and be able to compete with their native counterparts in the wild.
METHODOLOGY/PRINCIPAL FINDINGS : In the present study the radiation sensitivity of colonised Glossina brevipalpis Newstead
(Diptera; Glossinidae) males, treated either as adults or pupae, was assessed. The mating
performance of the irradiated G. brevipalpis males was assessed in walk-in field cages.
Glossina brevipalpis adults and pupae were highly sensitive to irradiation, and a dose of 40
Gy and 80 Gy induced 93% and 99% sterility respectively in untreated females that mated
with males irradiated as adults. When 37 to 41 day old pupae were exposed to a dose of 40
Gy, more than 97% sterility was induced in untreated females that mated with males derived
from irradiated pupae. Males treated as adults with a dose up to 80 Gy were able to compete
successfully with untreated fertile males for untreated females in walk-in field cages.
CONCLUSIONS/SIGNIFICANCE : The data emanating from this field cage study indicates that, sterile male flies derived from
the colony of G. brevipalpis maintained at the Agricultural Research Council-Onderstepoort
Veterinary Institute in South Africa are potential good candidates for a campaign that includes a sterile insect technique component. This would need to be confirmed by open
field studies.The Research was done in collaboration
with the Joint Food and Agriculture Organization/
International Atomic Energy Agency Division of
Nuclear Techniques in Food and Agriculture under
the coordinated research project 17753/R0.http://www.plosntds.orgam2017Veterinary Tropical Disease
A distribution model for Glossina brevipalpis and Glossina austeni in southern Mozambique, Eswatini and South Africa for enhanced area-wide integrated pest management approaches
BACKGROUND : Glossina austeni and Glossina brevipalpis (Diptera: Glossinidae) are the sole cyclical vectors of African trypanosomes in South Africa, Eswatini and southern Mozambique. These populations represent the southernmost distribution of tsetse flies on the African continent. Accurate knowledge of infested areas is a prerequisite to develop and implement efficient and cost-effective control strategies, and distribution models may reduce large-scale, extensive entomological surveys that are time consuming and expensive. The objective was to develop a MaxEnt species distribution model and habitat suitability maps for the southern tsetse belt of South Africa, Eswatini and southern Mozambique. METHODOLOGY/PRINCIPAL FINDINGS : The present study used existing entomological survey data of G. austeni and G. brevipalpis to develop a MaxEnt species distribution model and habitat suitability maps. Distribution models and a checkerboard analysis indicated an overlapping presence of the two species and the most suitable habitat for both species were protected areas and the coastal strip in KwaZulu-Natal Province, South Africa and Maputo Province, Mozambique. The predicted presence extents, to a small degree, into communal farming areas adjacent to the protected areas and coastline, especially in the MatutuÃne District of Mozambique. The quality of the MaxEnt model was assessed using an independent data set and indicated good performance with high predictive power (AUC > 0.80 for both species). CONCLUSIONS/SIGNIFICANCE : The models indicated that cattle density, land surface temperature and protected areas, in relation with vegetation are the main factors contributing to the distribution of the two tsetse species in the area. Changes in the climate, agricultural practices and land-use have had a significant and rapid impact on tsetse abundance in the area. The model predicted low habitat suitability in the Gaza and Inhambane Provinces of Mozambique, i.e., the area north of the MatutuÃne District. This might indicate that the southern tsetse population is isolated from the main tsetse belt in the north of Mozambique. The updated distribution models will be useful for planning tsetse and trypanosomosis interventions in the area.S1 Fig. Uncertainty grid for the habitat suitability index model for Glossina austeni and
Glossina brevipalpis (https://dataverse.harvard.edu/dataset.xhtml?persistentId=doi:10.
7910/DVN/PA7U7L).The Joint Food and Agriculture Organization of the United Nations (FAO)/ International Atomic Energy Agency (IAEA) Centre of Nuclear Techniques in Food and Agriculture and the IAEA’s Department of Technical Cooperation; the IAEA’s Department of Technical Cooperation; the Department of Science and Technology and the GeosAf project.http://www.plosntds.orgam2022Veterinary Tropical Disease
Development and characterization of microsatellite markers for the tsetse species Glossina brevipalpis and preliminary population genetics analyses
Tsetse flies, the vectors of African trypanosomes are of key medical and economic importance and one of the constraints for the development of Africa. Tsetse fly control is one of the most effective and sustainable strategies used for controlling the disease. Knowledge about population structure and level of gene flow between neighbouring populations of the target vector is of high importance to develop appropriate strategies for implementing effective management programmes. Microsatellites are commonly used to identify population structure and assess dispersal of the target populations and have been developed for several tsetse species but were lacking for Glossina brevipalpis. In this study, we screened the genome of G. brevipalpis to search for suitable microsatellite markers and nine were found to be efficient enough to distinguish between different tsetse populations. The availability of these novel microsatellite loci will help to better understand the population biology of G. brevipalpis and to assess the level of gene flow between different populations. Such information will help with the development of appropriate strategies to implement the sterile insect technique (SIT) in the framework of an area-wide integrated pest management (AW-IPM) approach to manage tsetse populations and ultimately address the trypanosomoses problem in these targeted areas
Prevalence of Trypanosoma and Sodalis in wild populations of tsetse flies and their impact on sterile insect technique programmes for tsetse eradication
The sterile insect technique (SIT) is an environment friendly and sustainable method to manage insect pests of economic importance through successive releases of sterile irradiated males of the targeted species to a defined area. A mating of a sterile male with a virgin wild female will result in no offspring, and ultimately lead to the suppression or eradication of the targeted population. Tsetse flies, vectors of African Trypanosoma, have a highly regulated and defined microbial fauna composed of three bacterial symbionts that may have a role to play in the establishment of Trypanosoma infections in the flies and hence, may influence the vectorial competence of the released sterile males. Sodalis bacteria seem to interact with Trypanosoma infection in tsetse flies. Field-caught tsetse flies of ten different taxa and from 15 countries were screened using PCR to detect the presence of Sodalis and Trypanosoma species and analyse their interaction. The results indicate that the prevalence of Sodalis and Trypanosoma varied with country and tsetse species. Trypanosome prevalence was higher in east, central and southern African countries than in west African countries. Tsetse fly infection rates with Trypanosoma vivax and T. brucei sspp were higher in west African countries, whereas tsetse infection with T. congolense and T. simiae, T. simiae (tsavo) and T. godfreyi were higher in east, central and south African countries. Sodalis prevalence was high in Glossina morsitans morsitans and G. pallidipes but absent in G. tachinoides. Double and triple infections with Trypanosoma taxa and coinfection of Sodalis and Trypanosoma were rarely observed but it occurs in some taxa and locations. A significant Chi square value (< 0.05) seems to suggest that Sodalis and Trypanosoma infection correlate in G. palpalis gambiensis, G. pallidipes and G. medicorum. Trypanosoma infection seemed significantly associated with an increased density of Sodalis in wild G. m. morsitans and G. pallidipes flies, however, there was no significant impact of Sodalis infection on trypanosome density.The Joint FAO/IAEA Insect Pest Control Subprogramme.https://www.nature.com/srepVeterinary Tropical Disease
Finishing the euchromatic sequence of the human genome
The sequence of the human genome encodes the genetic instructions for human physiology, as well as rich information about human evolution. In 2001, the International Human Genome Sequencing Consortium reported a draft sequence of the euchromatic portion of the human genome. Since then, the international collaboration has worked to convert this draft into a genome sequence with high accuracy and nearly complete coverage. Here, we report the result of this finishing process. The current genome sequence (Build 35) contains 2.85 billion nucleotides interrupted by only 341 gaps. It covers ∼99% of the euchromatic genome and is accurate to an error rate of ∼1 event per 100,000 bases. Many of the remaining euchromatic gaps are associated with segmental duplications and will require focused work with new methods. The near-complete sequence, the first for a vertebrate, greatly improves the precision of biological analyses of the human genome including studies of gene number, birth and death. Notably, the human enome seems to encode only 20,000-25,000 protein-coding genes. The genome sequence reported here should serve as a firm foundation for biomedical research in the decades ahead
Gamma irradiation and male Glossina austeni mating performance
An area-wide integrated pest management (AW-IPM) strategy with a sterile insect technique
(SIT) component has been proposed for the management of African animal trypanosomosis (AAT) in
South Africa. In preparation for the SIT, the mating performance of colony reared Glossina austeni
males under influencing factors such as radiation dose and the development stage that is exposed to
radiation, was assessed under laboratory and semi-field conditions. The radiation sensitivity of G.
austeni colonized 37 years ago when treated as adults and late-stage pupae was determined. Radiation
doses of 80 Gy and 100 Gy induced 97–99% sterility in colony females that mated with colony males
treated as adults or pupae. Males irradiated either as adults or pupae with a radiation dose of 100 Gy
showed similar insemination ability and survival as untreated males. Walk-in field cage assessments
indicated that a dose of up to 100 Gy did not adversely a ect the mating performance of males
irradiated as adults or late stage pupae. Males irradiated as adults formed mating pairs faster than
fertile males and males irradiated as pupae. The mating performance studies indicated that the
colonized G. austeni males irradiated as adults or late stage pupae will still be suited for SIT.IAEAhttp://www.mdpi.com/journal/insectsam2020Veterinary Tropical Disease
Effect of the developmental stage (age of pupa or adult) (β<sub>1</sub>) at time of and dose (β<sub>2</sub>) of irradiation on the survival of the male flies determined at 14 day intervals.
<p>Effect of the developmental stage (age of pupa or adult) (β<sub>1</sub>) at time of and dose (β<sub>2</sub>) of irradiation on the survival of the male flies determined at 14 day intervals.</p
Emergence rate of adult <i>Glossina brevipalpis</i> irradiated as pupae with different doses and on different days Post Larviposition (PL).
<p>Emergence rate of adult <i>Glossina brevipalpis</i> irradiated as pupae with different doses and on different days Post Larviposition (PL).</p
Number of irradiated male (40 or 80 Gy) and untreated male (0 Gy) <i>Glossina brevipalpis</i> that mated with untreated females in a field cage.
<p>Each box shows the group median separating the 25<sup>th</sup> and 75<sup>th</sup> quartiles, capped bars indicate maximum and minimum values, circles indicating the outliners.</p
A distribution model for Glossina brevipalpis and Glossina austeni in Southern Mozambique, Eswatini and South Africa for enhanced area-wide integrated pest management approaches
International audienceBackground Glossina austeni and Glossina brevipalpis (Diptera: Glossinidae) are the sole cyclical vectors of African trypanosomes in South Africa, Eswatini and southern Mozambique. These populations represent the southernmost distribution of tsetse flies on the African continent. Accurate knowledge of infested areas is a prerequisite to develop and implement efficient and cost-effective control strategies, and distribution models may reduce large-scale, extensive entomological surveys that are time consuming and expensive. The objective was to develop a MaxEnt species distribution model and habitat suitability maps for the southern tsetse belt of South Africa, Eswatini and southern Mozambique