| Gene Symbol | Dgri\GH15459 |
| Entrez Gene ID | 6558293 |
| Full Name | GH15459 gene product from transcript GH15459-RA |
| Synonyms | GH15459,dgri_GLEANR_15243 |
| Gene Type | protein-coding |
| Organism | Drosophila grimshawi |
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Dgri\GH15459 cDNA ORF clone, Drosophila grimshawi
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Gene
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Clones
gRNAs
The following Dgri\GH15459 gene cDNA ORF clone sequences were retrieved from the NCBI Reference Sequence Database (RefSeq). These sequences represent the protein coding region of the Dgri\GH15459 cDNA ORF which is encoded by the open reading frame (ORF) sequence. ORF sequences can be delivered in our standard vector, pcDNA3.1+/C-(K)DYK or the vector of your choice as an expression/transfection-ready ORF clone. Not the clone you want? Click here to find your clone.
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Reference Sequences (Refseq)
CloneID ODj14135 Clone ID Related Accession (Same CDS sequence) XM_001983607.1 Accession Version XM_001983607.1 Latest version! Documents for ORF clone product in default vector Sequence Information ORF Nucleotide Sequence (Length: 3342bp)
Protein sequence
SNPVector pcDNA3.1-C-(k)DYK or customized vector 
User ManualClone information Clone Map MSDSTag on pcDNA3.1+/C-(K)DYK C terminal DYKDDDDK tags ORF Insert Method CloneEZ™ Seamless cloning technology Insert Structure linear Update Date 1323014400000 Organism Drosophila grimshawi Product Dgri\GH15459-PA Comment Comment: PROVISIONAL REFSEQ: This record is based on preliminary annotation provided by FlyBase. This record is derived from an annotated genomic sequence (NW_001961672). COMPLETENESS: incomplete on both ends.
1
61
121
181
241
301
361
421
481
541
601
661
721
781
841
901
961
1021
1081
1141
1201
1261
1321
1381
1441
1501
1561
1621
1681
1741
1801
1861
1921
1981
2041
2101
2161
2221
2281
2341
2401
2461
2521
2581
2641
2701
2761
2821
2881
2941
3001
3061
3121
3181
3241
3301ATGAACGATG TGGCGGATGC GGCCTTCTCC AGTTTCTACG TTGGCAGCCA GCTACAGCAT
GCGGAGCTGT CGCTATCGAC GCCTATCCAT GCCCTGGAGC ACGATAGCAA TTTCACCGGT
CTCTTTGACG ATGATCCCGC CCTGCTCTCG CTTCCCCTGT CGACAATATC GGGAGCAGCA
GCTGTAGCAG CAGTCGCGAC CCATAAGGTT GCAACGGGCG TTGTAACGGA GACCGCCTGC
ATTCCATTTG TGCAGATCCA TACGACAGAC TTGCAACAGC AACTCGAACC GGGTCGCAGC
TATCGCAATG GATTCCGACG ACGCACAGCT GAAATCAAAT CGGAGGCGGA ACTCATTAAA
TCAGAGCAGG CGGATGCGGC GGCTAAGGAA CGCATCAATG CCACACCCAC ACCGCCCACA
GCCACAAAGA CAATCGCGAG CGAGGGTTGC TCGGATCTGC CGCTGCACAA GTGTCCCAGC
TGCCCGTTCC TCAGTCTCTG CCAGCTGAAG GCCCAAACGC ACATCAGCAG CTGCTTTGGC
GTCGATGCCC AGCGACGCCT GCAGTGTCCA GGTTGTGCGA ACGTTTTCTA CAGCATCGAT
GTGCTGCAGT TGCATCTGAG CGCTGATCAT CAGCTGGAGC CGCAGGAGAT AGCCAAGCTG
ACCGGCAAAT CCAGCGAAAG AGGAGCCAGA AAACCACAGC AGCAGCAGCA CCAATCGCTG
CCCAAAAGTC GCATCTTTAT CAAGAATGTG GATTGCTTGA GGGAGCCGCA TCGCGAGCAG
GATGCAATCA ATCCATTGTC CGACTTTCTG CCGCTGTTGC CCAACTCGCC AGATAGCAGC
ACTGGCAATA TACTAGACCT TCTCGATGAT GTTGACGAGG AGCAGCAACA GCAACTGCAA
ATCTTGCCAA TGAGCCAAAA GACAGCCGTG CAAAAGATAT CCATAAAGAG TGTCGATGTG
CTGCGAGAGC CGGCGCTGCT GCCCTTTGAT TTCCATCTGC CCAATGGCGG AGAGCAACTG
CAGCAGCAGC AACATTTGCT GGATGTACAT GTTGTGGACG TATCGGAGCC GGAGAAACCC
CGTCAGCCCA AGATCTACAT ACGCAATGTG GACATACTAA AAGAGCCCAT GTTGCTGCCG
GGCATGGGTT TCAACGAGGC ACCCACCACG ACGGCAATCG AAAGTTCCGT GGAGATGTTT
CCCGCCGAAA CGCTGCTAAC GCCTACGGGT CCGGTGGGTC CGCTGCCCGG CTTTGAGCCA
GCTCTGGCTC CGTTGGCCAA CATGTGCGGT GAGTCGTTCA ATTTTGATGC TGTGCTCAGT
GGTGCTGGCA CCACCAGCAG CAACAGTGTC AGCAGTAACA ATTTCAGTGC CTTGGATTTG
GATTTTGGTG TCGATTTCGA GCACAGTGTG CAGCTGGAGA CAACACCACC ACCACCACCA
GCACCATCAT CAGCAGTCAC AGCAGCAGCA GCTGGAGCAG CAGTATCGAC GGAAGCAACA
GTAGAGCCTC CATCACAGCA GTCACTTATA AGTGCGCAGC TGGCGGAGCT GGGTGCACTG
CCACAAGATG AGCTGGATAA CTATTTATCA AGGACGACAT CGTCGAAGCA AAAGATCTTC
ATCAAGAATG TGGATATATT GAAGGCGCCA CAGCGTGGCA CATTGCATCT GCGCACCGTC
GACGAACTGA ATCTGATGAA TCGCAACGAG GTCGAGCATC TGATTGTGCC CCATAGGGAG
CCGCTGCAGC TGGAGCAGCT GCCACTAAAT GACACAGCTG CTGCTGCGGC TGCTGCTGCT
GCTGTCGCAC TGGAATCGAC TCTCGTCGAT TTCGAGCAGG CGCCATCAGC GCCATTGAGC
TATGATGATA GCTATGACTT GGCCGAGAAT CTGGAAATCT GGCCCTGGAT GGAGGAGTCG
GTGCCAGCGG GCATAGACAC AGCCACAGAG ACGGAGCACG ATGTTACAGA ACAGCTGGAG
TTGCCACACA ATGCCGACGA TATTCTGATT AAGGATTTTC CGCAACTCTA TGCATCGCAG
ACGCCCACAG CGGATGCTGT GCCGCCTCTG GTGCCGGTCA CCGGCTCACC GGAACTGGTG
GGGAGCTCAG CTGTGCCTGC AGAGAATTTG TGCGGGCTAC CCGTACCGCC GCTGGTGCCC
CTCGCTGCAG AGGCGGCAGC TGCTGGTGCT GCTGCTGGCG GCGCCGATGA GAAGCCCGCT
CGCATTTATG TGGCCAACAA TTTGCTGCCC ACTGCTGTGG AGCCAGCGCC GCTGCCAGGT
GGCACCTCGG TGCGTGGTCG TCCATATGGT GCCAAGCAAG CAGGTCAAAC GGCCAAACGA
CGACCGGCAC AGAGCGCAGT GCAGTCGCTG GAGGGTGGCA AATGCACCGT GGAGGGTTGC
ATGTTCCGCT TCAAGTCACC GACCACCTTG GAGTACCATG GACGTTGTCA CAATGGCTCG
CTCGGCTCCA CACAGCCGAT GATCTGTCCC GAGTGCCGAT CTACACAGTT CAGCAATTGG
AATTGCCTGC ACACCCATCT GTGGCGCACC CATGAGATCG ACATGGAACT GTACTGCTGC
CAGCTGTGCA GCTTTAAGAC GCCAATTTAC TCCAGGCTGG TGAACACCCA TGCCAAGATC
CACTCCGAGG AGCGCAACTA CAAGTGCGAG CAATGCGGCA AGGGATTCAA GAACACCAAA
CAGCTAAAGA ACCATCGACG ATTGCATCGC ACCCAGGGCC TGGGCATGTC AGCCAAGCCA
AGCATCAGCG AGGAGCAGAT GGCGTTACCA ATTCTGCATC GCTGCGAGGA TTGCGGTACC
GCCTTCAAGC ATCGCAAAAC GCTGCGGGAG CATCTGTGCA AGCAGCGCAA CGAGCAGCCA
CAGTGCACCA CTTGTCAGCG CGTCTTTAGC TCGAAGAGCA GCCTCAAGTT GCACATGCGC
AGTCATCAGG AGAGCAAGCG ATTCAAGTGC GAAAAGTGCG ATCATGAAGC GAATGATCAC
AATGCCTTCC GGCGTCATCT GGCCACACAT CGGGAGGCCA AACGCTATGC GTGTCCACAC
TGCGATTTTA AGGCCATCCA AAGCACCGCC TATCGGATAC ACCTGCAGAA GATGCATCCG
GAGCAGGAGC TGTCCAGCAT TATATACAAA TGCAATGCGT GCACCTTTTC CAGCATCAAT
CGCGGCCTGC TGCTGGTTCA TCAGGCCAAA CACGACACGG CGCCAAGCGA GTCCTCAAAG
ATCAAAGTGA AAAGCAGCCT TCTGCTTGCA CCAAATGTTA AGGAGCCCAA ACCGGCTGAA
TTGGTGGCAC TTGCGGCGCC AGCTGGCGAT CTAATTGCCT AGThe stop codons will be deleted if pcDNA3.1+/C-(K)DYK vector is selected.
RefSeq XP_001983643.1 CDS 1..3342 Translation 
Target ORF information:
RefSeq Version XM_001983607.1 Organism Drosophila grimshawi Definition Drosophila grimshawi GH15459 (Dgri\GH15459), mRNA. Target ORF information:
Epitope DYKDDDDK Bacterial selection AMPR Mammalian selection NeoR Vector pcDNA3.1+/C-(K)DYK 
XM_001983607.1
ORF Insert Sequence:
1
61
121
181
241
301
361
421
481
541
601
661
721
781
841
901
961
1021
1081
1141
1201
1261
1321
1381
1441
1501
1561
1621
1681
1741
1801
1861
1921
1981
2041
2101
2161
2221
2281
2341
2401
2461
2521
2581
2641
2701
2761
2821
2881
2941
3001
3061
3121
3181
3241
3301ATGAACGATG TGGCGGATGC GGCCTTCTCC AGTTTCTACG TTGGCAGCCA GCTACAGCAT
GCGGAGCTGT CGCTATCGAC GCCTATCCAT GCCCTGGAGC ACGATAGCAA TTTCACCGGT
CTCTTTGACG ATGATCCCGC CCTGCTCTCG CTTCCCCTGT CGACAATATC GGGAGCAGCA
GCTGTAGCAG CAGTCGCGAC CCATAAGGTT GCAACGGGCG TTGTAACGGA GACCGCCTGC
ATTCCATTTG TGCAGATCCA TACGACAGAC TTGCAACAGC AACTCGAACC GGGTCGCAGC
TATCGCAATG GATTCCGACG ACGCACAGCT GAAATCAAAT CGGAGGCGGA ACTCATTAAA
TCAGAGCAGG CGGATGCGGC GGCTAAGGAA CGCATCAATG CCACACCCAC ACCGCCCACA
GCCACAAAGA CAATCGCGAG CGAGGGTTGC TCGGATCTGC CGCTGCACAA GTGTCCCAGC
TGCCCGTTCC TCAGTCTCTG CCAGCTGAAG GCCCAAACGC ACATCAGCAG CTGCTTTGGC
GTCGATGCCC AGCGACGCCT GCAGTGTCCA GGTTGTGCGA ACGTTTTCTA CAGCATCGAT
GTGCTGCAGT TGCATCTGAG CGCTGATCAT CAGCTGGAGC CGCAGGAGAT AGCCAAGCTG
ACCGGCAAAT CCAGCGAAAG AGGAGCCAGA AAACCACAGC AGCAGCAGCA CCAATCGCTG
CCCAAAAGTC GCATCTTTAT CAAGAATGTG GATTGCTTGA GGGAGCCGCA TCGCGAGCAG
GATGCAATCA ATCCATTGTC CGACTTTCTG CCGCTGTTGC CCAACTCGCC AGATAGCAGC
ACTGGCAATA TACTAGACCT TCTCGATGAT GTTGACGAGG AGCAGCAACA GCAACTGCAA
ATCTTGCCAA TGAGCCAAAA GACAGCCGTG CAAAAGATAT CCATAAAGAG TGTCGATGTG
CTGCGAGAGC CGGCGCTGCT GCCCTTTGAT TTCCATCTGC CCAATGGCGG AGAGCAACTG
CAGCAGCAGC AACATTTGCT GGATGTACAT GTTGTGGACG TATCGGAGCC GGAGAAACCC
CGTCAGCCCA AGATCTACAT ACGCAATGTG GACATACTAA AAGAGCCCAT GTTGCTGCCG
GGCATGGGTT TCAACGAGGC ACCCACCACG ACGGCAATCG AAAGTTCCGT GGAGATGTTT
CCCGCCGAAA CGCTGCTAAC GCCTACGGGT CCGGTGGGTC CGCTGCCCGG CTTTGAGCCA
GCTCTGGCTC CGTTGGCCAA CATGTGCGGT GAGTCGTTCA ATTTTGATGC TGTGCTCAGT
GGTGCTGGCA CCACCAGCAG CAACAGTGTC AGCAGTAACA ATTTCAGTGC CTTGGATTTG
GATTTTGGTG TCGATTTCGA GCACAGTGTG CAGCTGGAGA CAACACCACC ACCACCACCA
GCACCATCAT CAGCAGTCAC AGCAGCAGCA GCTGGAGCAG CAGTATCGAC GGAAGCAACA
GTAGAGCCTC CATCACAGCA GTCACTTATA AGTGCGCAGC TGGCGGAGCT GGGTGCACTG
CCACAAGATG AGCTGGATAA CTATTTATCA AGGACGACAT CGTCGAAGCA AAAGATCTTC
ATCAAGAATG TGGATATATT GAAGGCGCCA CAGCGTGGCA CATTGCATCT GCGCACCGTC
GACGAACTGA ATCTGATGAA TCGCAACGAG GTCGAGCATC TGATTGTGCC CCATAGGGAG
CCGCTGCAGC TGGAGCAGCT GCCACTAAAT GACACAGCTG CTGCTGCGGC TGCTGCTGCT
GCTGTCGCAC TGGAATCGAC TCTCGTCGAT TTCGAGCAGG CGCCATCAGC GCCATTGAGC
TATGATGATA GCTATGACTT GGCCGAGAAT CTGGAAATCT GGCCCTGGAT GGAGGAGTCG
GTGCCAGCGG GCATAGACAC AGCCACAGAG ACGGAGCACG ATGTTACAGA ACAGCTGGAG
TTGCCACACA ATGCCGACGA TATTCTGATT AAGGATTTTC CGCAACTCTA TGCATCGCAG
ACGCCCACAG CGGATGCTGT GCCGCCTCTG GTGCCGGTCA CCGGCTCACC GGAACTGGTG
GGGAGCTCAG CTGTGCCTGC AGAGAATTTG TGCGGGCTAC CCGTACCGCC GCTGGTGCCC
CTCGCTGCAG AGGCGGCAGC TGCTGGTGCT GCTGCTGGCG GCGCCGATGA GAAGCCCGCT
CGCATTTATG TGGCCAACAA TTTGCTGCCC ACTGCTGTGG AGCCAGCGCC GCTGCCAGGT
GGCACCTCGG TGCGTGGTCG TCCATATGGT GCCAAGCAAG CAGGTCAAAC GGCCAAACGA
CGACCGGCAC AGAGCGCAGT GCAGTCGCTG GAGGGTGGCA AATGCACCGT GGAGGGTTGC
ATGTTCCGCT TCAAGTCACC GACCACCTTG GAGTACCATG GACGTTGTCA CAATGGCTCG
CTCGGCTCCA CACAGCCGAT GATCTGTCCC GAGTGCCGAT CTACACAGTT CAGCAATTGG
AATTGCCTGC ACACCCATCT GTGGCGCACC CATGAGATCG ACATGGAACT GTACTGCTGC
CAGCTGTGCA GCTTTAAGAC GCCAATTTAC TCCAGGCTGG TGAACACCCA TGCCAAGATC
CACTCCGAGG AGCGCAACTA CAAGTGCGAG CAATGCGGCA AGGGATTCAA GAACACCAAA
CAGCTAAAGA ACCATCGACG ATTGCATCGC ACCCAGGGCC TGGGCATGTC AGCCAAGCCA
AGCATCAGCG AGGAGCAGAT GGCGTTACCA ATTCTGCATC GCTGCGAGGA TTGCGGTACC
GCCTTCAAGC ATCGCAAAAC GCTGCGGGAG CATCTGTGCA AGCAGCGCAA CGAGCAGCCA
CAGTGCACCA CTTGTCAGCG CGTCTTTAGC TCGAAGAGCA GCCTCAAGTT GCACATGCGC
AGTCATCAGG AGAGCAAGCG ATTCAAGTGC GAAAAGTGCG ATCATGAAGC GAATGATCAC
AATGCCTTCC GGCGTCATCT GGCCACACAT CGGGAGGCCA AACGCTATGC GTGTCCACAC
TGCGATTTTA AGGCCATCCA AAGCACCGCC TATCGGATAC ACCTGCAGAA GATGCATCCG
GAGCAGGAGC TGTCCAGCAT TATATACAAA TGCAATGCGT GCACCTTTTC CAGCATCAAT
CGCGGCCTGC TGCTGGTTCA TCAGGCCAAA CACGACACGG CGCCAAGCGA GTCCTCAAAG
ATCAAAGTGA AAAGCAGCCT TCTGCTTGCA CCAAATGTTA AGGAGCCCAA ACCGGCTGAA
TTGGTGGCAC TTGCGGCGCC AGCTGGCGAT CTAATTGCCT AGThe stop codons will be deleted if pcDNA3.1+/C-(K)DYK vector is selected.
-
PubMed
Assembly reconciliation.
Bioinformatics (Oxford, England)24(1)42-5(2008 Jan)
Zimin AV,Smith DR,Sutton G,Yorke JA
Evolution of genes and genomes on the Drosophila phylogeny.
Nature450(7167)203-18(2007 Nov)
,Clark AG,Eisen MB,Smith DR,Bergman CM,Oliver B,Markow TA,Kaufman TC,Kellis M,Gelbart W,Iyer VN,Pollard DA,Sackton TB,Larracuente AM,Singh ND,Abad JP,Abt DN,Adryan B,Aguade M,Akashi H,Anderson WW,Aquadro CF,Ardell DH,Arguello R,Artieri CG,Barbash DA,Barker D,Barsanti P,Batterham P,Batzoglou S,Begun D,Bhutkar A,Blanco E,Bosak SA,Bradley RK,Brand AD,Brent MR,Brooks AN,Brown RH,Butlin RK,Caggese C,Calvi BR,Bernardo de Carvalho A,Caspi A,Castrezana S,Celniker SE,Chang JL,Chapple C,Chatterji S,Chinwalla A,Civetta A,Clifton SW,Comeron JM,Costello JC,Coyne JA,Daub J,David RG,Delcher AL,Delehaunty K,Do CB,Ebling H,Edwards K,Eickbush T,Evans JD,Filipski A,Findeiss S,Freyhult E,Fulton L,Fulton R,Garcia AC,Gardiner A,Garfield DA,Garvin BE,Gibson G,Gilbert D,Gnerre S,Godfrey J,Good R,Gotea V,Gravely B,Greenberg AJ,Griffiths-Jones S,Gross S,Guigo R,Gustafson EA,Haerty W,Hahn MW,Halligan DL,Halpern AL,Halter GM,Han MV,Heger A,Hillier L,Hinrichs AS,Holmes I,Hoskins RA,Hubisz MJ,Hultmark D,Huntley MA,Jaffe DB,Jagadeeshan S,Jeck WR,Johnson J,Jones CD,Jordan WC,Karpen GH,Kataoka E,Keightley PD,Kheradpour P,Kirkness EF,Koerich LB,Kristiansen K,Kudrna D,Kulathinal RJ,Kumar S,Kwok R,Lander E,Langley CH,Lapoint R,Lazzaro BP,Lee SJ,Levesque L,Li R,Lin CF,Lin MF,Lindblad-Toh K,Llopart A,Long M,Low L,Lozovsky E,Lu J,Luo M,Machado CA,Makalowski W,Marzo M,Matsuda M,Matzkin L,McAllister B,McBride CS,McKernan B,McKernan K,Mendez-Lago M,Minx P,Mollenhauer MU,Montooth K,Mount SM,Mu X,Myers E,Negre B,Newfeld S,Nielsen R,Noor MA,O'Grady P,Pachter L,Papaceit M,Parisi MJ,Parisi M,Parts L,Pedersen JS,Pesole G,Phillippy AM,Ponting CP,Pop M,Porcelli D,Powell JR,Prohaska S,Pruitt K,Puig M,Quesneville H,Ram KR,Rand D,Rasmussen MD,Reed LK,Reenan R,Reily A,Remington KA,Rieger TT,Ritchie MG,Robin C,Rogers YH,Rohde C,Rozas J,Rubenfield MJ,Ruiz A,Russo S,Salzberg SL,Sanchez-Gracia A,Saranga DJ,Sato H,Schaeffer SW,Schatz MC,Schlenke T,Schwartz R,Segarra C,Singh RS,Sirot L,Sirota M,Sisneros NB,Smith CD,Smith TF,Spieth J,Stage DE,Stark A,Stephan W,Strausberg RL,Strempel S,Sturgill D,Sutton G,Sutton GG,Tao W,Teichmann S,Tobari YN,Tomimura Y,Tsolas JM,Valente VL,Venter E,Venter JC,Vicario S,Vieira FG,Vilella AJ,Villasante A,Walenz B,Wang J,Wasserman M,Watts T,Wilson D,Wilson RK,Wing RA,Wolfner MF,Wong A,Wong GK,Wu CI,Wu G,Yamamoto D,Yang HP,Yang SP,Yorke JA,Yoshida K,Zdobnov E,Zhang P,Zhang Y,Zimin AV,Baldwin J,Abdouelleil A,Abdulkadir J,Abebe A,Abera B,Abreu J,Acer SC,Aftuck L,Alexander A,An P,Anderson E,Anderson S,Arachi H,Azer M,Bachantsang P,Barry A,Bayul T,Berlin A,Bessette D,Bloom T,Blye J,Boguslavskiy L,Bonnet C,Boukhgalter B,Bourzgui I,Brown A,Cahill P,Channer S,Cheshatsang Y,Chuda L,Citroen M,Collymore A,Cooke P,Costello M,D'Aco K,Daza R,De Haan G,DeGray S,DeMaso C,Dhargay N,Dooley K,Dooley E,Doricent M,Dorje P,Dorjee K,Dupes A,Elong R,Falk J,Farina A,Faro S,Ferguson D,Fisher S,Foley CD,Franke A,Friedrich D,Gadbois L,Gearin G,Gearin CR,Giannoukos G,Goode T,Graham J,Grandbois E,Grewal S,Gyaltsen K,Hafez N,Hagos B,Hall J,Henson C,Hollinger A,Honan T,Huard MD,Hughes L,Hurhula B,Husby ME,Kamat A,Kanga B,Kashin S,Khazanovich D,Kisner P,Lance K,Lara M,Lee W,Lennon N,Letendre F,LeVine R,Lipovsky A,Liu X,Liu J,Liu S,Lokyitsang T,Lokyitsang Y,Lubonja R,Lui A,MacDonald P,Magnisalis V,Maru K,Matthews C,McCusker W,McDonough S,Mehta T,Meldrim J,Meneus L,Mihai O,Mihalev A,Mihova T,Mittelman R,Mlenga V,Montmayeur A,Mulrain L,Navidi A,Naylor J,Negash T,Nguyen T,Nguyen N,Nicol R,Norbu C,Norbu N,Novod N,O'Neill B,Osman S,Markiewicz E,Oyono OL,Patti C,Phunkhang P,Pierre F,Priest M,Raghuraman S,Rege F,Reyes R,Rise C,Rogov P,Ross K,Ryan E,Settipalli S,Shea T,Sherpa N,Shi L,Shih D,Sparrow T,Spaulding J,Stalker J,Stange-Thomann N,Stavropoulos S,Stone C,Strader C,Tesfaye S,Thomson T,Thoulutsang Y,Thoulutsang D,Topham K,Topping I,Tsamla T,Vassiliev H,Vo A,Wangchuk T,Wangdi T,Weiand M,Wilkinson J,Wilson A,Yadav S,Young G,Yu Q,Zembek L,Zhong D,Zimmer A,Zwirko Z,Jaffe DB,Alvarez P,Brockman W,Butler J,Chin C,Gnerre S,Grabherr M,Kleber M,Mauceli E,MacCallum I
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