Cryptic Diversity within the Major Trypanosomiasis Vector Glossina fuscipes Revealed by Molecular Markers

Naomi Dyer; Sophie Ravel; Kwang Shik Choi; Alistair C. Darby; Sandrine Causse; Berisha Kapitano; Martin J.R. Hall; Keith Steen; Pascal Lutumba; Joules Madinga; Stephen Torr; Loyce M. Okedi; Michael J. Lehane; Martin Donnelly

doi:10.1371/journal.pntd.0001266

Cryptic Diversity within the Major Trypanosomiasis Vector Glossina fuscipes Revealed by Molecular Markers

Naomi Dyer
, Sophie Ravel
, Kwang Shik Choi
, Alistair C. Darby
, Sandrine Causse
, Berisha Kapitano
, Martin J.R. Hall
, Keith Steen
, Pascal Lutumba
, Joules Madinga
, Stephen Torr
, Loyce M. Okedi
, Michael J. Lehane
, Martin Donnelly

Vector Biology

Research output: Contribution to journal › Article › peer-review

22 Citations (Scopus)

Abstract

Background

The tsetse fly Glossina fuscipes s.l. is responsible for the transmission of approximately 90% of cases of human African trypanosomiasis (HAT) or sleeping sickness. Three G. fuscipes subspecies have been described, primarily based upon subtle differences in the morphology of their genitalia. Here we describe a study conducted across the range of this important vector to determine whether molecular evidence generated from nuclear DNA (microsatellites and gene sequence information), mitochondrial DNA and symbiont DNA support the existence of these taxa as discrete taxonomic units.

Principal Findings

The nuclear ribosomal Internal transcribed spacer 1 (ITS1) provided support for the three subspecies. However nuclear and mitochondrial sequence data did not support the monophyly of the morphological subspecies G. f. fuscipes or G. f. quanzensis. Instead, the most strongly supported monophyletic group was comprised of flies sampled from Ethiopia. Maternally inherited loci (mtDNA and symbiont) also suggested monophyly of a group from Lake Victoria basin and Tanzania, but this group was not supported by nuclear loci, suggesting different histories of these markers. Microsatellite data confirmed strong structuring across the range of G. fuscipes s.l., and was useful for deriving the interrelationship of closely related populations.

Conclusion/Significance

We propose that the morphological classification alone is not used to classify populations of G. fuscipes for control purposes. The Ethiopian population, which is scheduled to be the target of a sterile insect release (SIT) programme, was notably discrete. From a programmatic perspective this may be both positive, given that it may reflect limited migration into the area or negative if the high levels of differentiation are also reflected in reproductive isolation between this population and the flies to be used in the release programme.

Original language	English
Article number	e1266
Pages (from-to)	e1266
Journal	PLoS Neglected Tropical Diseases
Volume	5
Issue number	8
DOIs	https://doi.org/10.1371/journal.pntd.0001266
Publication status	Published - 9 Aug 2011

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Plos NTD 5 8 e1266Final published version, 619 KBLicence: CC BY

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Dyer, N., Ravel, S., Choi, K. S., Darby, A. C., Causse, S., Kapitano, B., Hall, M. J. R., Steen, K., Lutumba, P., Madinga, J., Torr, S., Okedi, L. M., Lehane, M. J., & Donnelly, M. (2011). Cryptic Diversity within the Major Trypanosomiasis Vector Glossina fuscipes Revealed by Molecular Markers. PLoS Neglected Tropical Diseases, 5(8), e1266. Article e1266. https://doi.org/10.1371/journal.pntd.0001266

@article{58cbb2272a0b40bab37a0204242d4dfa,

title = "Cryptic Diversity within the Major Trypanosomiasis Vector Glossina fuscipes Revealed by Molecular Markers",

abstract = "BackgroundThe tsetse fly Glossina fuscipes s.l. is responsible for the transmission of approximately 90\% of cases of human African trypanosomiasis (HAT) or sleeping sickness. Three G. fuscipes subspecies have been described, primarily based upon subtle differences in the morphology of their genitalia. Here we describe a study conducted across the range of this important vector to determine whether molecular evidence generated from nuclear DNA (microsatellites and gene sequence information), mitochondrial DNA and symbiont DNA support the existence of these taxa as discrete taxonomic units.Principal FindingsThe nuclear ribosomal Internal transcribed spacer 1 (ITS1) provided support for the three subspecies. However nuclear and mitochondrial sequence data did not support the monophyly of the morphological subspecies G. f. fuscipes or G. f. quanzensis. Instead, the most strongly supported monophyletic group was comprised of flies sampled from Ethiopia. Maternally inherited loci (mtDNA and symbiont) also suggested monophyly of a group from Lake Victoria basin and Tanzania, but this group was not supported by nuclear loci, suggesting different histories of these markers. Microsatellite data confirmed strong structuring across the range of G. fuscipes s.l., and was useful for deriving the interrelationship of closely related populations.Conclusion/SignificanceWe propose that the morphological classification alone is not used to classify populations of G. fuscipes for control purposes. The Ethiopian population, which is scheduled to be the target of a sterile insect release (SIT) programme, was notably discrete. From a programmatic perspective this may be both positive, given that it may reflect limited migration into the area or negative if the high levels of differentiation are also reflected in reproductive isolation between this population and the flies to be used in the release programme.",

author = "Naomi Dyer and Sophie Ravel and Choi, \{Kwang Shik\} and Darby, \{Alistair C.\} and Sandrine Causse and Berisha Kapitano and Hall, \{Martin J.R.\} and Keith Steen and Pascal Lutumba and Joules Madinga and Stephen Torr and Okedi, \{Loyce M.\} and Lehane, \{Michael J.\} and Martin Donnelly",

year = "2011",

month = aug,

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doi = "10.1371/journal.pntd.0001266",

language = "English",

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Dyer, N, Ravel, S, Choi, KS, Darby, AC, Causse, S, Kapitano, B, Hall, MJR, Steen, K, Lutumba, P, Madinga, J, Torr, S, Okedi, LM, Lehane, MJ & Donnelly, M 2011, 'Cryptic Diversity within the Major Trypanosomiasis Vector Glossina fuscipes Revealed by Molecular Markers', PLoS Neglected Tropical Diseases, vol. 5, no. 8, e1266, pp. e1266. https://doi.org/10.1371/journal.pntd.0001266

TY - JOUR

T1 - Cryptic Diversity within the Major Trypanosomiasis Vector Glossina fuscipes Revealed by Molecular Markers

AU - Dyer, Naomi

AU - Ravel, Sophie

AU - Choi, Kwang Shik

AU - Darby, Alistair C.

AU - Causse, Sandrine

AU - Kapitano, Berisha

AU - Hall, Martin J.R.

AU - Steen, Keith

AU - Lutumba, Pascal

AU - Madinga, Joules

AU - Torr, Stephen

AU - Okedi, Loyce M.

AU - Lehane, Michael J.

AU - Donnelly, Martin

PY - 2011/8/9

Y1 - 2011/8/9

N2 - BackgroundThe tsetse fly Glossina fuscipes s.l. is responsible for the transmission of approximately 90% of cases of human African trypanosomiasis (HAT) or sleeping sickness. Three G. fuscipes subspecies have been described, primarily based upon subtle differences in the morphology of their genitalia. Here we describe a study conducted across the range of this important vector to determine whether molecular evidence generated from nuclear DNA (microsatellites and gene sequence information), mitochondrial DNA and symbiont DNA support the existence of these taxa as discrete taxonomic units.Principal FindingsThe nuclear ribosomal Internal transcribed spacer 1 (ITS1) provided support for the three subspecies. However nuclear and mitochondrial sequence data did not support the monophyly of the morphological subspecies G. f. fuscipes or G. f. quanzensis. Instead, the most strongly supported monophyletic group was comprised of flies sampled from Ethiopia. Maternally inherited loci (mtDNA and symbiont) also suggested monophyly of a group from Lake Victoria basin and Tanzania, but this group was not supported by nuclear loci, suggesting different histories of these markers. Microsatellite data confirmed strong structuring across the range of G. fuscipes s.l., and was useful for deriving the interrelationship of closely related populations.Conclusion/SignificanceWe propose that the morphological classification alone is not used to classify populations of G. fuscipes for control purposes. The Ethiopian population, which is scheduled to be the target of a sterile insect release (SIT) programme, was notably discrete. From a programmatic perspective this may be both positive, given that it may reflect limited migration into the area or negative if the high levels of differentiation are also reflected in reproductive isolation between this population and the flies to be used in the release programme.

AB - BackgroundThe tsetse fly Glossina fuscipes s.l. is responsible for the transmission of approximately 90% of cases of human African trypanosomiasis (HAT) or sleeping sickness. Three G. fuscipes subspecies have been described, primarily based upon subtle differences in the morphology of their genitalia. Here we describe a study conducted across the range of this important vector to determine whether molecular evidence generated from nuclear DNA (microsatellites and gene sequence information), mitochondrial DNA and symbiont DNA support the existence of these taxa as discrete taxonomic units.Principal FindingsThe nuclear ribosomal Internal transcribed spacer 1 (ITS1) provided support for the three subspecies. However nuclear and mitochondrial sequence data did not support the monophyly of the morphological subspecies G. f. fuscipes or G. f. quanzensis. Instead, the most strongly supported monophyletic group was comprised of flies sampled from Ethiopia. Maternally inherited loci (mtDNA and symbiont) also suggested monophyly of a group from Lake Victoria basin and Tanzania, but this group was not supported by nuclear loci, suggesting different histories of these markers. Microsatellite data confirmed strong structuring across the range of G. fuscipes s.l., and was useful for deriving the interrelationship of closely related populations.Conclusion/SignificanceWe propose that the morphological classification alone is not used to classify populations of G. fuscipes for control purposes. The Ethiopian population, which is scheduled to be the target of a sterile insect release (SIT) programme, was notably discrete. From a programmatic perspective this may be both positive, given that it may reflect limited migration into the area or negative if the high levels of differentiation are also reflected in reproductive isolation between this population and the flies to be used in the release programme.

U2 - 10.1371/journal.pntd.0001266

DO - 10.1371/journal.pntd.0001266

M3 - Article

SN - 1935-2727

VL - 5

SP - e1266

JO - PLoS Neglected Tropical Diseases

JF - PLoS Neglected Tropical Diseases

IS - 8

M1 - e1266

ER -

Cryptic Diversity within the Major Trypanosomiasis Vector Glossina fuscipes Revealed by Molecular Markers

Abstract

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