| Gene Symbol | EF-TU |
| Entrez Gene ID | 8241211 |
| Full Name | elongation factor tu gtp-binding domain protein 2 |
| Gene Type | protein-coding |
| Organism | Micromonas commoda |
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EF-TU cDNA ORF clone, Micromonas commoda
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Gene
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Clones
gRNAs
The following EF-TU gene cDNA ORF clone sequences were retrieved from the NCBI Reference Sequence Database (RefSeq). These sequences represent the protein coding region of the EF-TU 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 OMg00685 Clone ID Related Accession (Same CDS sequence) XM_002499484.1 Accession Version XM_002499484.1 Latest version! Documents for ORF clone product in default vector Sequence Information ORF Nucleotide Sequence (Length: 2961bp)
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 1498060800000 Organism Micromonas commoda Product elongation factor tu gtp-binding domain protein 2 Comment Comment: PROVISIONAL REFSEQ: This record has not yet been subject to final NCBI review. This record is derived from an annotated genomic sequence (NC_013039). 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
2941ATGGACTCGC ACTACGACGA GTTCGGCAAC TACATCGGAC CCGAGCTGAG CGACGATAGC
GACAGCGACG GTGGGGCGGA TGCCAACGAC CAGCAGGTGA GATCCCGGGA TGTCGACAAC
GGCACCGCGG GCATGGACGT CGACGGCGAC GACGCCGAGG AGAACTTCGA AACCGCGATC
GTCCTCGCCG AGGACAAGAA GTACTACCCA ACCGCGGAGG AGGTGTACGG CCCCGGGACT
GAGACGCTGA TCATGGACGA GGACGCGCAG CCGCTCGAGG AGCCCATCAT CGCGCCGGTG
AAAAAGAAGC AGATCGAGGC GGATCGGGGT AAGAACGCGC TCGAGTTGAA GGTGAGCGAG
GAGTACCTGC GGGGCCTCAT GGGCAACGCC AACCTCGTGC GGAACGTAGC CGTCGCCGGG
CACCTGCACC ACGGCAAGAC GACGGTGTTC GACATGCTGG TGGAGCAGAC GCACCACGTG
GACGACGCGA TCGTGCACGC GGACGATAGG GCGCTGCGAT ACACGGACAC CAGGTTGGAC
GAGCAGGACC GGGAGGTTAG CATCAAGGCG GTGCCCATGT CGCTGGTGAT GCCAAACGGC
GCGGGCAAGC ACCTGCTCTT CAACATGATG GACACCCCGG GCCACGTCAA CTTCAGCGAC
GAGGTCACCG CGAGCTACCG TTTGAGCGAC GGCGTTATGC TCGTGGTGGA CGCGGTGGAG
GGCGTGATGT GCGGCACGGA GCGGCTCATC AAGCACGCCG CGAAGGAGCG TCTGCCAATC
TGCGTATTTG TCAACAAGGT GGACAGGCTC ATCCTCGAGC TCAAGCTTCC CCCCGCGGAC
GCGTACCACA AGATCAGGCA CACGCTCGAG GAGATCAATG CCATCATCGA GGCCACCTAC
GGGGGCGACG AGAACGCGCC GTTCGCGGAT CCAGTCAAGG GGAGCGTGTG CTTTGGATCC
GCAAAGTACG GCTGGTCCTT CACCCTCAAC TCATTCGCGA GGCTCTACGC GGATATTCGC
GGCGTAGACA TGGATACCCA GGCGTTCGCG CGCAGGCTCT GGGGCGACAT GTACTTCAAC
GAGGAGACGC GCACGTTCAG ACGCAAGCCC CCACCGGGCG GCGGCGACCG CTCCTTCGTG
CAGTTTATCC TCGAGCCGCT GTATAAGATT TACTCGCAAG CCGTGGGCGA GCACCAGGCG
TCCTTCGCCC GCGTCCTCGC CGAGCTCGGC GTGACGCTCA AACCCAAGGA GTACAGGATG
AACACCAAGC CCCTCATCAA ACTCGCGTGC ACCAAGATCT TCGGCGACGC GTCCGGTCTG
GTCGACATGC TCTGCGCGCA CGTGCCCACC GCGAGGGGCG GAGCGCCAGC CAAGGTTGAA
AACGCGTACG CGGGCCCCCT CGCCGGCGCC GACGGCCAAA GCTGCGTGAA CACCATGCGC
GCGTGCGACC CGAACGGCCC GTTGCAGGTG ATGGTCGCGA AGCTCTACCC GAAGGACGAT
TGCTCATCCT TCGACGCGCT CGCGAGGGTC ATGAGCGGCA CGCTGAAGAA GGGTCAGAAC
GTGCGGGTGT TGGGCGAGGC GTACTCGCCG GATGACGAGG AGGACTGCGC GGTGAAGCAG
GTGACGAACC TGTGGGTGTA CCAGGCGAGG TACCGCATCC CCGTGGAGGA GGTCGCCGCG
GGCGCCTGGG TTCTCGTCGA GGGCATCGAC GGGAGCATCA GCAAGACGGC GACGCTCGTG
GCGGAGTACG GGGAGGAGGA TGCGTACGTG TTCAGGCCTC TCGCGTTTGA TAACCAGTCG
GTGGTGAAGA TCGCGACGGA GCCGCTGAAC CCCAGCGACC TGCCGAAGAT GGTCGAGGGT
CTGCGTAAGA TCAACAAGTC CTACCCGCTC GCGGTGACGA AGGTTGAGGA GAGCGGCGAG
CACACCATCA TGGGCACGGG TGAGATTTTC CTGGACTCCA TCATGAAGGA CCTTCGCGAG
CTGTACTCGG AGGTTGAGGT CAAGGTTGCC GACCCGGTCG TCACCTTCTG CGAGACCGTG
GTCGAGACGT CCAGCCTGAA GTGCTTCGCA GAGACCCCGA ACAAGAAAAA CAAGATCACC
ATGATCGCCG AGCCGCTGGA TAAAGGATTG GCGGCGGACA TCGAGAACGG GACGGTGTCA
CTCAAGTGGC CAAAAAAGAA GCTCGGGGAT TTCTTCCAGA ACAAGTACGA TTGGGATATC
CTCGCCGCGC GGAGCGTGTG GGCGTTCGGC CCGGACGAGA AGGGTGCCAA CGCGCTGCTC
GATGACACCC TGCCCGGTGA GATCGACAAA TCCCTGCTCA ACGCGGTCAA GGAGAGCATC
GTGCAGGGTT TCCAGTGGGG CACGAGGGAA GGACCGTTGT GCGACGAGCC CATCCGCAAC
GTTAAGTTTA AGATCCTGGA CGCGATCGTC GCGGATCAGC CGCTGCACAG GGGCGGCGGG
CAGGTGATCC CCACTGCGCG CAGGGTGGCG TATTCATCGT TCCTGATGGC GTCGCCGAGG
CTGATGGAGC CCGTGTTCGC TTGCGAGATT CAGACCCCCG CGGATTGCAT GAGTGCAATT
TACACGGTGC TCTCCAAGCG CCGCGGGCAC GTCATCGCCG ACAACCCCAA GCCCGGCACT
CCGGTGTACA CGGTCAAGGC GCTCATCCCC GCGATCGAAT CGTTCGGCTT CGAAACAGAT
CTTCGCTATC ACACGCAGGG CCAGGCGTTC GGGCAGAGCT ACTTCGATCA TTGGGCGGTT
GTGCCCGGCG ACCCGCTGGA CCGCGGCATC GTCCTGAGGC CGCTGGAGCC GAGCCCGGTG
CAGGCGCTCG CGAGGGAGTT CATGGTGAAG ACGAGGCGAC GGAAGGGGAT GAGCGAGGAC
GTGAGCGTGC AGAAGTTCTT CGACGACACG CTCCTCGCGG AGCTGGCCAA GGCGGACGCG
GGCATCGAGG GGATCATGTG AThe stop codons will be deleted if pcDNA3.1+/C-(K)DYK vector is selected.
RefSeq XP_002499530.1 CDS 1..2961 Translation 
Target ORF information:
RefSeq Version XM_002499484.1 Organism Micromonas commoda Definition Micromonas commoda elongation factor tu gtp-binding domain protein 2 (EF-TU), partial mRNA. Target ORF information:
Epitope DYKDDDDK Bacterial selection AMPR Mammalian selection NeoR Vector pcDNA3.1+/C-(K)DYK 
XM_002499484.1
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
2941ATGGACTCGC ACTACGACGA GTTCGGCAAC TACATCGGAC CCGAGCTGAG CGACGATAGC
GACAGCGACG GTGGGGCGGA TGCCAACGAC CAGCAGGTGA GATCCCGGGA TGTCGACAAC
GGCACCGCGG GCATGGACGT CGACGGCGAC GACGCCGAGG AGAACTTCGA AACCGCGATC
GTCCTCGCCG AGGACAAGAA GTACTACCCA ACCGCGGAGG AGGTGTACGG CCCCGGGACT
GAGACGCTGA TCATGGACGA GGACGCGCAG CCGCTCGAGG AGCCCATCAT CGCGCCGGTG
AAAAAGAAGC AGATCGAGGC GGATCGGGGT AAGAACGCGC TCGAGTTGAA GGTGAGCGAG
GAGTACCTGC GGGGCCTCAT GGGCAACGCC AACCTCGTGC GGAACGTAGC CGTCGCCGGG
CACCTGCACC ACGGCAAGAC GACGGTGTTC GACATGCTGG TGGAGCAGAC GCACCACGTG
GACGACGCGA TCGTGCACGC GGACGATAGG GCGCTGCGAT ACACGGACAC CAGGTTGGAC
GAGCAGGACC GGGAGGTTAG CATCAAGGCG GTGCCCATGT CGCTGGTGAT GCCAAACGGC
GCGGGCAAGC ACCTGCTCTT CAACATGATG GACACCCCGG GCCACGTCAA CTTCAGCGAC
GAGGTCACCG CGAGCTACCG TTTGAGCGAC GGCGTTATGC TCGTGGTGGA CGCGGTGGAG
GGCGTGATGT GCGGCACGGA GCGGCTCATC AAGCACGCCG CGAAGGAGCG TCTGCCAATC
TGCGTATTTG TCAACAAGGT GGACAGGCTC ATCCTCGAGC TCAAGCTTCC CCCCGCGGAC
GCGTACCACA AGATCAGGCA CACGCTCGAG GAGATCAATG CCATCATCGA GGCCACCTAC
GGGGGCGACG AGAACGCGCC GTTCGCGGAT CCAGTCAAGG GGAGCGTGTG CTTTGGATCC
GCAAAGTACG GCTGGTCCTT CACCCTCAAC TCATTCGCGA GGCTCTACGC GGATATTCGC
GGCGTAGACA TGGATACCCA GGCGTTCGCG CGCAGGCTCT GGGGCGACAT GTACTTCAAC
GAGGAGACGC GCACGTTCAG ACGCAAGCCC CCACCGGGCG GCGGCGACCG CTCCTTCGTG
CAGTTTATCC TCGAGCCGCT GTATAAGATT TACTCGCAAG CCGTGGGCGA GCACCAGGCG
TCCTTCGCCC GCGTCCTCGC CGAGCTCGGC GTGACGCTCA AACCCAAGGA GTACAGGATG
AACACCAAGC CCCTCATCAA ACTCGCGTGC ACCAAGATCT TCGGCGACGC GTCCGGTCTG
GTCGACATGC TCTGCGCGCA CGTGCCCACC GCGAGGGGCG GAGCGCCAGC CAAGGTTGAA
AACGCGTACG CGGGCCCCCT CGCCGGCGCC GACGGCCAAA GCTGCGTGAA CACCATGCGC
GCGTGCGACC CGAACGGCCC GTTGCAGGTG ATGGTCGCGA AGCTCTACCC GAAGGACGAT
TGCTCATCCT TCGACGCGCT CGCGAGGGTC ATGAGCGGCA CGCTGAAGAA GGGTCAGAAC
GTGCGGGTGT TGGGCGAGGC GTACTCGCCG GATGACGAGG AGGACTGCGC GGTGAAGCAG
GTGACGAACC TGTGGGTGTA CCAGGCGAGG TACCGCATCC CCGTGGAGGA GGTCGCCGCG
GGCGCCTGGG TTCTCGTCGA GGGCATCGAC GGGAGCATCA GCAAGACGGC GACGCTCGTG
GCGGAGTACG GGGAGGAGGA TGCGTACGTG TTCAGGCCTC TCGCGTTTGA TAACCAGTCG
GTGGTGAAGA TCGCGACGGA GCCGCTGAAC CCCAGCGACC TGCCGAAGAT GGTCGAGGGT
CTGCGTAAGA TCAACAAGTC CTACCCGCTC GCGGTGACGA AGGTTGAGGA GAGCGGCGAG
CACACCATCA TGGGCACGGG TGAGATTTTC CTGGACTCCA TCATGAAGGA CCTTCGCGAG
CTGTACTCGG AGGTTGAGGT CAAGGTTGCC GACCCGGTCG TCACCTTCTG CGAGACCGTG
GTCGAGACGT CCAGCCTGAA GTGCTTCGCA GAGACCCCGA ACAAGAAAAA CAAGATCACC
ATGATCGCCG AGCCGCTGGA TAAAGGATTG GCGGCGGACA TCGAGAACGG GACGGTGTCA
CTCAAGTGGC CAAAAAAGAA GCTCGGGGAT TTCTTCCAGA ACAAGTACGA TTGGGATATC
CTCGCCGCGC GGAGCGTGTG GGCGTTCGGC CCGGACGAGA AGGGTGCCAA CGCGCTGCTC
GATGACACCC TGCCCGGTGA GATCGACAAA TCCCTGCTCA ACGCGGTCAA GGAGAGCATC
GTGCAGGGTT TCCAGTGGGG CACGAGGGAA GGACCGTTGT GCGACGAGCC CATCCGCAAC
GTTAAGTTTA AGATCCTGGA CGCGATCGTC GCGGATCAGC CGCTGCACAG GGGCGGCGGG
CAGGTGATCC CCACTGCGCG CAGGGTGGCG TATTCATCGT TCCTGATGGC GTCGCCGAGG
CTGATGGAGC CCGTGTTCGC TTGCGAGATT CAGACCCCCG CGGATTGCAT GAGTGCAATT
TACACGGTGC TCTCCAAGCG CCGCGGGCAC GTCATCGCCG ACAACCCCAA GCCCGGCACT
CCGGTGTACA CGGTCAAGGC GCTCATCCCC GCGATCGAAT CGTTCGGCTT CGAAACAGAT
CTTCGCTATC ACACGCAGGG CCAGGCGTTC GGGCAGAGCT ACTTCGATCA TTGGGCGGTT
GTGCCCGGCG ACCCGCTGGA CCGCGGCATC GTCCTGAGGC CGCTGGAGCC GAGCCCGGTG
CAGGCGCTCG CGAGGGAGTT CATGGTGAAG ACGAGGCGAC GGAAGGGGAT GAGCGAGGAC
GTGAGCGTGC AGAAGTTCTT CGACGACACG CTCCTCGCGG AGCTGGCCAA GGCGGACGCG
GGCATCGAGG GGATCATGTG AThe stop codons will be deleted if pcDNA3.1+/C-(K)DYK vector is selected.
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PubMed
Green evolution and dynamic adaptations revealed by genomes of the marine picoeukaryotes Micromonas.
Science (New York, N.Y.)324(5924)268-72(2009 Apr)
Worden AZ,Lee JH,Mock T,Rouzé P,Simmons MP,Aerts AL,Allen AE,Cuvelier ML,Derelle E,Everett MV,Foulon E,Grimwood J,Gundlach H,Henrissat B,Napoli C,McDonald SM,Parker MS,Rombauts S,Salamov A,Von Dassow P,Badger JH,Coutinho PM,Demir E,Dubchak I,Gentemann C,Eikrem W,Gready JE,John U,Lanier W,Lindquist EA,Lucas S,Mayer KF,Moreau H,Not F,Otillar R,Panaud O,Pangilinan J,Paulsen I,Piegu B,Poliakov A,Robbens S,Schmutz J,Toulza E,Wyss T,Zelensky A,Zhou K,Armbrust EV,Bhattacharya D,Goodenough UW,Van de Peer Y,Grigoriev IV
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