Intraclonal mating occurs during tsetse transmission of Trypanosoma brucei
详细信息 查看全文
- 作者:Lori Peacock (1) (2)
Vanessa Ferris (1) (2)
Mick Bailey (2)
Wendy Gibson (1) - 刊名:Parasites & Vectors
- 出版年:2009
- 出版时间:December 2009
- 年:2009
- 卷:2
- 期:1
- 全文大小:1564KB
- 参考文献:1. Jenni L, Marti S, Schweizer J, Betschart B, Lepage RWF, Wells JM, Tait A, Paindavoine P, Pays E, Steinert M: Hybrid formation between African trypanosomes during cyclical transmission. / Nature 1986, 322: 173鈥?75. CrossRef
2. Gibson W, Stevens J: Genetic exchange in the Trypanosomatidae. / Adv Parasitol 1999, 43: 1鈥?6. CrossRef
3. Richner D, Brun R, Jenni L: Production of metacyclic forms by cyclical transmission of West African Trypanosoma (Trypanozoon) brucei isolates from man and animals. / Acta Trop 1988, 45: 309鈥?19.
4. Gibson W, Winters K, Mizen G, Kearns J, Bailey M: Intraclonal mating in Trypanosoma brucei is associated with out-crossing. / Microbiology UK 1997, 143: 909鈥?20. CrossRef
5. Tait A, Buchanan N, Hide G, Turner M: Self-fertilisation in Trypanosoma brucei . / Mol Biochem Parasitol 1996, 76: 31鈥?2. CrossRef
6. Turner CMR, Sternberg J, Buchanan N, Smith E, Hide G, Tait A: Evidence that the mechanism of gene exchange in Trypanosoma brucei involves meiosis and syngamy. / Parasitology 1990, 101: 377鈥?86. CrossRef
7. Gibson W, Peacock L, Ferris V, Williams K, Bailey M: Analysis of a cross between green and red fluorescent trypanosomes. / Biochem Soc Trans 2006, 34: 557鈥?59. CrossRef
8. Gibson W, Peacock L, Ferris V, Williams K, Bailey M: The use of yellow fluorescent hybrids to indicate mating in Trypanosoma brucei . / Parasites and Vectors 2008, 1: 4. CrossRef
9. Kabayo JP: The nature of the nutritional importance of serum-albumin to Glossina morsitans . / J Insect Physiol 1982, 28: 917鈥?23. CrossRef
10. Galun R, Margalit J: Adenine nucleotides as feeding stimulants of tsetse fly Glossina austeni Newst. / Nature 1969, 222: 583鈥?84. CrossRef
11. Peacock L, Ferris V, Bailey M, Gibson W: Multiple effects of the lectin-inhibitory sugars D-glucosamine and N-acetyl-glucosamine on tsetse-trypanosome interactions. / Parasitology 2006, 132: 651鈥?58. CrossRef
12. Macleod ET, Maudlin I, Darby AC, Welburn SC: Antioxidants promote establishment of trypanosome infections in tsetse. / Parasitology 2007, 134: 827鈥?31. CrossRef
13. Gibson WC, Fase-Fowler F, Borst P: Further analysis of intraspecific variation in Trypanosoma brucei using restriction site polymorphisms in the maxi-circle of kinetoplast DNA. / Mol Biochem Parasitol 1985, 15: 21鈥?6. CrossRef
14. Gibson WC, Marshall TFdC, Godfrey DG: Numerical analysis of enzyme polymorphism: a new approach to the epidemiology and taxonomy of trypanosomes of the subgenus Trypanozoon . / Adv Parasitol 1980, 18: 175鈥?46. CrossRef
15. Campbell RE, Tour O, Palmer AE, Steinbach PA, Baird GS, Zacharias DA, Tsien RY: A monomeric red fluorescent protein. / Proc Natl Acad Sci USA 2002, 99: 7877鈥?882. CrossRef
16. Cunningham I: New culture medium for maintenance of tsetse tissues and growth of trypanosomatids. / J Protozool 1977, 24: 325鈥?29.
17. Van der Ploeg LH, Schwartz DC, Cantor CR, Borst P: Antigenic variation in Trypanosoma brucei analysed by electrophoretic separation of chromosome-sized DNA molecules. / Cell 1984, 37: 77鈥?4. CrossRef
18. Thomashow LS, Milhausen M, Rutter M, Agabian N: Tubulin genes are tandemly linked and clustered in the genome of Trypanosoma brucei . / Cell 1983, 32: 35鈥?3. CrossRef
19. Berriman M, Ghedin E, Hertz-Fowler C, Blandin G, Renauld H, Bartholomeu DC, Lennard NJ, Caler E, Hamlin NE, Haas B, / et al.: The genome of the African trypanosome Trypanosoma brucei . / Science 2005, 309: 416鈥?22. CrossRef
20. MacLeod A, Tweedie A, McLellan S, Taylor S, Cooper A, Sweeney L, Turner CMR, Tait A: Allelic segregation and independent assortment in Trypanosoma brucei crosses: Proof that the genetic system is Mendelian and involves meiosis. / Mol Biochem Parasitol 2005, 143: 12鈥?9. CrossRef
21. Peacock L, Ferris V, Bailey M, Gibson W: Dynamics of infection and competition between two strains of Trypanosoma brucei brucei in the tsetse fly observed using fluorescent markers. / Kinetoplastid Biology and Disease 2007, 6: 4. CrossRef - 作者单位:Lori Peacock (1) (2)
Vanessa Ferris (1) (2)
Mick Bailey (2)
Wendy Gibson (1)
1. School of Biological Sciences University of Bristol, BS8 1UG, Bristol, UK
2. Department of Clinical Veterinary Science, University of Bristol, BS40 7DU, Langford, Bristol, UK
文摘
Background Mating in Trypanosoma brucei is a non-obligatory event, triggered by the co-occurrence of different strains in the salivary glands of the vector. Recombinants that result from intra- rather than interclonal mating have been detected, but only in crosses of two different trypanosome strains. This has led to the hypothesis that when trypanosomes recognize a different strain, they release a diffusible factor or pheromone that triggers mating in any cell in the vicinity whether it is of the same or a different strain. This idea assumes that the trypanosome can recognize self and non-self, although there is as yet no evidence for the existence of mating types in T. brucei. Results We investigated intraclonal mating in T. b. brucei by crossing red and green fluorescent lines of a single strain, so that recombinant progeny can be detected in the fly by yellow fluorescence. For strain 1738, seven flies had both red and green trypanosomes in the salivary glands and, in three, yellow trypanosomes were also observed, although they could not be recovered for subsequent analysis. Nonetheless, both red and non-fluorescent clones from these flies had recombinant genotypes as judged by microsatellite and karyotype analyses, and some also had raised DNA contents, suggesting recombination or genome duplication. Strain J10 produced similar results indicative of intraclonal mating. In contrast, trypanosome clones recovered from other flies showed that genotypes can be transmitted with fidelity. When a yellow hybrid clone expressing both red and green fluorescent protein genes was transmitted, the salivary glands contained a mixture of fluorescent-coloured trypanosomes, but only yellow and red clones were recovered. While loss of the GFP gene in the red clones could have resulted from gene conversion, some of these clones showed loss of heterozygosity and raised DNA contents as in the other single strain transmissions. Our observations suggest that many recombinants are non-viable after intraclonal mating. Conclusion We have demonstrated intraclonal mating during fly transmission of T. b. brucei, contrary to previous findings that recombination occurs only when another strain is present. It is thus no longer possible to assume that T. b. brucei remains genetically unaltered after fly transmission.