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Author Report for: Atkinson PW

Title: The whole genome sequence of the Mediterranean fruit fly, Ceratitis capitata (Wiedemann), reveals insights into the biology and adaptive evolution of a highly invasive pest species
Papanicolaou A, Schetelig MF, Arensburger P, Atkinson PW, Benoit JB, Bourtzis K, Castanera P, Cavanaugh JP, Chao H and Handler AM <54 more author(s)> Papanicolaou A, Schetelig MF, Arensburger P, Atkinson PW, Benoit JB, Bourtzis K, Castanera P, Cavanaugh JP, Chao H, Childers C, Curril I, Dinh H, Doddapaneni H, Dolan A, Dugan S, Friedrich M, Gasperi G, Geib S, Georgakilas G, Gibbs RA, Giers SD, Gomulski LM, Gonzalez-Guzman M, Guillem-Amat A, Han Y, Hatzigeorgiou AG, Hernandez-Crespo P, Hughes DS, Jones JW, Karagkouni D, Koskinioti P, Lee SL, Malacrida AR, Manni M, Mathiopoulos K, Meccariello A, Murali SC, Murphy TD, Muzny DM, Oberhofer G, Ortego F, Paraskevopoulou MD, Poelchau M, Qu J, Reczko M, Robertson HM, Rosendale AJ, Rosselot AE, Saccone G, Salvemini M, Savini G, Schreiner P, Scolari F, Siciliano P, Sim SB, Tsiamis G, Urena E, Vlachos IS, Werren JH, Wimmer EA, Worley KC, Zacharopoulou A, Richards S, Handler AM (- 54)
Ref: Genome Biol, 17:192, 2016 : PubMed
Abstract


ESTHER: Papanicolaou_2016_Genome.Biol_17_192
PubMedSearch: Papanicolaou 2016 Genome.Biol 17 192
PubMedID: 27659211

Abstract

BACKGROUND: The Mediterranean fruit fly (medfly), Ceratitis capitata, is a major destructive insect pest due to its broad host range, which includes hundreds of fruits and vegetables. It exhibits a unique ability to invade and adapt to ecological niches throughout tropical and subtropical regions of the world, though medfly infestations have been prevented and controlled by the sterile insect technique (SIT) as part of integrated pest management programs (IPMs). The genetic analysis and manipulation of medfly has been subject to intensive study in an effort to improve SIT efficacy and other aspects of IPM control.
RESULTS: The 479 Mb medfly genome is sequenced from adult flies from lines inbred for 20 generations. A high-quality assembly is achieved having a contig N50 of 45.7 kb and scaffold N50 of 4.06 Mb. In-depth curation of more than 1800 messenger RNAs shows specific gene expansions that can be related to invasiveness and host adaptation, including gene families for chemoreception, toxin and insecticide metabolism, cuticle proteins, opsins, and aquaporins. We identify genes relevant to IPM control, including those required to improve SIT.
CONCLUSIONS: The medfly genome sequence provides critical insights into the biology of one of the most serious and widespread agricultural pests. This knowledge should significantly advance the means of controlling the size and invasive potential of medfly populations. Its close relationship to Drosophila, and other insect species important to agriculture and human health, will further comparative functional and structural studies of insect genomes that should broaden our understanding of gene family evolution.



        

Title: Genome sequence of Aedes aegypti, a major arbovirus vector
Nene V, Wortman JR, Lawson D, Haas B, Kodira C, Tu ZJ, Loftus B, Xi Z, Megy K and Severson DW <85 more author(s)> Nene V, Wortman JR, Lawson D, Haas B, Kodira C, Tu ZJ, Loftus B, Xi Z, Megy K, Grabherr M, Ren Q, Zdobnov EM, Lobo NF, Campbell KS, Brown SE, Bonaldo MF, Zhu J, Sinkins SP, Hogenkamp DG, Amedeo P, Arensburger P, Atkinson PW, Bidwell S, Biedler J, Birney E, Bruggner RV, Costas J, Coy MR, Crabtree J, Crawford M, Debruyn B, Decaprio D, Eiglmeier K, Eisenstadt E, El-Dorry H, Gelbart WM, Gomes SL, Hammond M, Hannick LI, Hogan JR, Holmes MH, Jaffe D, Johnston JS, Kennedy RC, Koo H, Kravitz S, Kriventseva EV, Kulp D, LaButti K, Lee E, Li S, Lovin DD, Mao C, Mauceli E, Menck CF, Miller JR, Montgomery P, Mori A, Nascimento AL, Naveira HF, Nusbaum C, O'Leary S, Orvis J, Pertea M, Quesneville H, Reidenbach KR, Rogers YH, Roth CW, Schneider JR, Schatz M, Shumway M, Stanke M, Stinson EO, Tubio JM, Vanzee JP, Verjovski-Almeida S, Werner D, White O, Wyder S, Zeng Q, Zhao Q, Zhao Y, Hill CA, Raikhel AS, Soares MB, Knudson DL, Lee NH, Galagan J, Salzberg SL, Paulsen IT, Dimopoulos G, Collins FH, Birren B, Fraser-Liggett CM, Severson DW (- 85)
Ref: Science, 316:1718, 2007 : PubMed
Abstract


ESTHER: Nene_2007_Science_316_1718
PubMedSearch: Nene 2007 Science 316 1718
PubMedID: 17510324
Gene_locus related to this paper: aedae-ACHE, aedae-ACHE1, aedae-glita, aedae-q0iea6, aedae-q0iev6, aedae-q0ifn6, aedae-q0ifn8, aedae-q0ifn9, aedae-q0ifp0, aedae-q0ig41, aedae-q1dgl0, aedae-q1dh03, aedae-q1dh19, aedae-q1hqe6, aedae-Q8ITU8, aedae-Q8MMJ6, aedae-Q8T9V6, aedae-q16e91, aedae-q16f04, aedae-q16f25, aedae-q16f26, aedae-q16f28, aedae-q16f29, aedae-q16f30, aedae-q16gq5, aedae-q16iq5, aedae-q16je0, aedae-q16je1, aedae-q16je2, aedae-q16ks8, aedae-q16lf2, aedae-q16lv6, aedae-q16m61, aedae-q16mc1, aedae-q16mc6, aedae-q16mc7, aedae-q16md1, aedae-q16ms7, aedae-q16nk5, aedae-q16rl5, aedae-q16rz9, aedae-q16si8, aedae-q16t49, aedae-q16wf1, aedae-q16x18, aedae-q16xp8, aedae-q16xu6, aedae-q16xw5, aedae-q16xw6, aedae-q16y04, aedae-q16y05, aedae-q16y06, aedae-q16y07, aedae-q16y39, aedae-q16y40, aedae-q16yg4, aedae-q16z03, aedae-q17aa7, aedae-q17av1, aedae-q17av2, aedae-q17av3, aedae-q17av4, aedae-q17b28, aedae-q17b29, aedae-q17b30, aedae-q17b31, aedae-q17b32, aedae-q17bm3, aedae-q17bm4, aedae-q17bv7, aedae-q17c44, aedae-q17cz1, aedae-q17d32, aedae-q17g39, aedae-q17g40, aedae-q17g41, aedae-q17g42, aedae-q17g43, aedae-q17g44, aedae-q17gb8, aedae-q17gr3, aedae-q17if7, aedae-q17if9, aedae-q17ig1, aedae-q17ig2, aedae-q17is4, aedae-q17l09, aedae-q17m26, aedae-q17mg9, aedae-q17mv4, aedae-q17mv5, aedae-q17mv6, aedae-q17mv7, aedae-q17mw8, aedae-q17mw9, aedae-q17nw5, aedae-q17nx5, aedae-q17pa4, aedae-q17q69, aedae-q170k7, aedae-q171y4, aedae-q172e0, aedae-q176i8, aedae-q176j0, aedae-q177k1, aedae-q177k2, aedae-q177l9, aedae-j9hic3, aedae-q179r9, aedae-u483, aedae-j9hj23, aedae-q17d68, aedae-q177c7, aedae-q0ifp1, aedae-a0a1s4fx83, aedae-a0a1s4g2m0, aedae-q1hr49

Abstract

We present a draft sequence of the genome of Aedes aegypti, the primary vector for yellow fever and dengue fever, which at approximately 1376 million base pairs is about 5 times the size of the genome of the malaria vector Anopheles gambiae. Nearly 50% of the Ae. aegypti genome consists of transposable elements. These contribute to a factor of approximately 4 to 6 increase in average gene length and in sizes of intergenic regions relative to An. gambiae and Drosophila melanogaster. Nonetheless, chromosomal synteny is generally maintained among all three insects, although conservation of orthologous gene order is higher (by a factor of approximately 2) between the mosquito species than between either of them and the fruit fly. An increase in genes encoding odorant binding, cytochrome P450, and cuticle domains relative to An. gambiae suggests that members of these protein families underpin some of the biological differences between the two mosquito species.



        

Title: The genome sequence of the malaria mosquito Anopheles gambiae
Holt RA, Subramanian GM, Halpern A, Sutton GG, Charlab R, Nusskern DR, Wincker P, Clark AG, Ribeiro JM and Hoffman SL <113 more author(s)> Holt RA, Subramanian GM, Halpern A, Sutton GG, Charlab R, Nusskern DR, Wincker P, Clark AG, Ribeiro JM, Wides R, Salzberg SL, Loftus B, Yandell M, Majoros WH, Rusch DB, Lai Z, Kraft CL, Abril JF, Anthouard V, Arensburger P, Atkinson PW, Baden H, de Berardinis V, Baldwin D, Benes V, Biedler J, Blass C, Bolanos R, Boscus D, Barnstead M, Cai S, Center A, Chaturverdi K, Christophides GK, Chrystal MA, Clamp M, Cravchik A, Curwen V, Dana A, Delcher A, Dew I, Evans CA, Flanigan M, Grundschober-Freimoser A, Friedli L, Gu Z, Guan P, Guigo R, Hillenmeyer ME, Hladun SL, Hogan JR, Hong YS, Hoover J, Jaillon O, Ke Z, Kodira C, Kokoza E, Koutsos A, Letunic I, Levitsky A, Liang Y, Lin JJ, Lobo NF, Lopez JR, Malek JA, McIntosh TC, Meister S, Miller J, Mobarry C, Mongin E, Murphy SD, O'Brochta DA, Pfannkoch C, Qi R, Regier MA, Remington K, Shao H, Sharakhova MV, Sitter CD, Shetty J, Smith TJ, Strong R, Sun J, Thomasova D, Ton LQ, Topalis P, Tu Z, Unger MF, Walenz B, Wang A, Wang J, Wang M, Wang X, Woodford KJ, Wortman JR, Wu M, Yao A, Zdobnov EM, Zhang H, Zhao Q, Zhao S, Zhu SC, Zhimulev I, Coluzzi M, della Torre A, Roth CW, Louis C, Kalush F, Mural RJ, Myers EW, Adams MD, Smith HO, Broder S, Gardner MJ, Fraser CM, Birney E, Bork P, Brey PT, Venter JC, Weissenbach J, Kafatos FC, Collins FH, Hoffman SL (- 113)
Ref: Science, 298:129, 2002 : PubMed
Abstract


ESTHER: Holt_2002_Science_298_129
PubMedSearch: Holt 2002 Science 298 129
PubMedID: 12364791
Gene_locus related to this paper: anoga-a0nb77, anoga-a0nbp6, anoga-a0neb7, anoga-a0nei9, anoga-a0nej0, anoga-a0ngj1, anoga-a7ut12, anoga-a7uuz9, anoga-ACHE1, anoga-ACHE2, anoga-agCG44620, anoga-agCG44666, anoga-agCG45273, anoga-agCG45279, anoga-agCG45511, anoga-agCG46741, anoga-agCG47651, anoga-agCG47655, anoga-agCG47661, anoga-agCG47690, anoga-agCG48797, anoga-AGCG49362, anoga-agCG49462, anoga-agCG49870, anoga-agCG49872, anoga-agCG49876, anoga-agCG50851, anoga-agCG51879, anoga-agCG52383, anoga-agCG54954, anoga-AGCG55021, anoga-agCG55401, anoga-agCG55408, anoga-agCG56978, anoga-ebiG239, anoga-ebiG2660, anoga-ebiG5718, anoga-ebiG5974, anoga-ebiG8504, anoga-ebiG8742, anoga-glita, anoga-nrtac, anoga-q5tpv0, anoga-Q5TVS6, anoga-q7pm39, anoga-q7ppw9, anoga-q7pq17, anoga-Q7PQT0, anoga-q7q8m4, anoga-q7q626, anoga-q7qa14, anoga-q7qa52, anoga-q7qal7, anoga-q7qbj0, anoga-f5hl20, anoga-q7qkh2, anoga-a0a1s4h1y7, anoga-q7q887

Abstract

Anopheles gambiae is the principal vector of malaria, a disease that afflicts more than 500 million people and causes more than 1 million deaths each year. Tenfold shotgun sequence coverage was obtained from the PEST strain of A. gambiae and assembled into scaffolds that span 278 million base pairs. A total of 91% of the genome was organized in 303 scaffolds; the largest scaffold was 23.1 million base pairs. There was substantial genetic variation within this strain, and the apparent existence of two haplotypes of approximately equal frequency ("dual haplotypes") in a substantial fraction of the genome likely reflects the outbred nature of the PEST strain. The sequence produced a conservative inference of more than 400,000 single-nucleotide polymorphisms that showed a markedly bimodal density distribution. Analysis of the genome sequence revealed strong evidence for about 14,000 protein-encoding transcripts. Prominent expansions in specific families of proteins likely involved in cell adhesion and immunity were noted. An expressed sequence tag analysis of genes regulated by blood feeding provided insights into the physiological adaptations of a hematophagous insect.