FOX1 cDNA ORF clone, Chlamydomonas reinhardtii

The following FOX1 gene cDNA ORF clone sequences were retrieved from the NCBI Reference Sequence Database (RefSeq). These sequences represent the protein coding region of the FOX1 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.

***CloneID Accession No. Definition **Vector *Turnaround time Price (USD) Select
OCh03300 XM_001694533.1
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Chlamydomonas reinhardtii multicopper ferroxidase (FOX1), mRNA. pcDNA3.1-C-(k)DYK or customized vector 19-21 $559.30
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** You may select a custom vector to replace pcDNA3.1+/C-(K)DYK after clone is added to cart.

** GenScript guarantees 100% sequence accuracy of all synthetic DNA constructs we deliver, but we do not guarantee protein expression in your experimental system. Protein expression is influenced by many factors that may vary between experiments or laboratories. In addition, please pay attention to the signal peptide, propeptide and transit peptide in target ORF, which may affect the choice of vector (N/C terminal tag vector).

***One clone ID might be correlated to multiple accession numbers, which share the same CDS sequence.

  • Reference Sequences (Refseq)
    CloneID OCh03300
    Clone ID Related Accession (Same CDS sequence) XM_001694533.1
    Accession Version XM_001694533.1 Latest version! Documents for ORF clone product in default vector
    Sequence Information ORF Nucleotide Sequence (Length: 3429bp)
    Protein sequence
    SNP
    Vector pcDNA3.1-C-(k)DYK or customized vector User Manual
    Clone information Clone Map MSDS
    Tag on pcDNA3.1+/C-(K)DYK C terminal DYKDDDDK tags
    ORF Insert Method CloneEZ™ Seamless cloning technology
    Insert Structure linear
    Update Date 1503849600000
    Organism Chlamydomonas reinhardtii
    Product multicopper ferroxidase
    Comment Comment: PROVISIONAL REFSEQ: This record has not yet been subject to final NCBI review. This record is derived from an annotated genomic sequence (NW_001843666).

    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
    3301
    3361
    3421
    ATGGACAGCA AGGAAGCGGC GGAGCCGGCC TCGGTCCACG TCAACGTGGA CGTGGAGGCC 
    CAGAAGGCCC AGGCGCAGGC GGAGGCCGCA GCCAAGGGCG GCGCGTGCGC AACAAGCGGC
    ATGAGCAAAG GGAAGATCAT CGTCACTTCC TTGGTGATTT TTCTGGGGGT AGCGGTGGGC
    GTGGGTCTGG GCGTTGGCCT GGGCGTGGGT CTGAAGAAGG ACGACGGCTC GTCGGCCTAC
    ACCTCCCTGG ACCTGGGCAC GGGGTCGGGC GGCGGCAACA CCTACTTCGT CGCGGCGGAC
    AAGATTCAAT GGAACTACGC GCCCTCGGGC CGCAACAAGT GCTTCCCGCC CGACCTGGCT
    GCCAAGTACT TGGCCATGCA GCCCGGCATC ACGCGTGTGG GCGGCACCTT CGCCAAGGCC
    ATCTACCGCG CCTACACAGA CAGCAGCTTC AACACCCTCG CCACCACGCC CGCTGAATGG
    CAGCACCTGG GCAACGTGGG CCCCGTCATG TACGGCGCCG TGGGTCAGGT CATTCGCGTG
    GTGTTCAAGA ACAACCTGGA CTTCCCCGTC AACATGGCTC CCAGCGGCGG CCTGATCGCC
    TGGGACGGCA ACGGCCGCCG CTCCGCCCGC ATCGACCCCG TGAAGCCCGG GCAGACAGTC
    ACCTACCTGT GGCAGATCCC CGAGGACGCT GGCCCGGTGG CCAACGCCAC TGTGACCAGC
    CGCCTGTGGC TGTACCGCAG TAGCGTGGAC CCGCAGAAGC ACGACAACGC AGGACTGGTG
    GGCCCCATCA TCGTCACCTC CGCCGCCAAC GCCGACGCCA ACGGCCGCGC CCGCGACGTG
    GACCGCGACG TGGTGGCCAT CTTCCAGATT GTGCAGGAGC GCGCCAGCCC GCTGCTGTTC
    CAGGAGGACA CCAGCCTCAG CGCCGGCACC TCCTACACCA AGATGGCCAT CAACGGCTAC
    ACCTGGTGCA ACATGCCCGA CGGTGCCATC ACCATCAAGA CCGGCGAGCG GGTGCGGTGG
    CACGTGGCCT CCATTGGCTC GTCGGAGTCG CTGCACAACT TCCACTGGCA CGGACACGTG
    GTGGAGCTCA ACGGGCACCA TGTGGACCAG TTCACCGCCA TCCCCACCGC CACCTACTCG
    GTCAACATGG TGCCGGACGA GCCCGGCACC TGGATGTTCC ACTGCCACGT TAACTTCCAC
    ATGGACGGCG GCATGGTCGC CCTCTACACC GTCACCGGCG ACCCCGCGCC CCTGCCCACC
    GGCGGCGTGG AGCGGGTGTA CTACGTGCGC GCGCAGGAGG TTGAGTGGAG CTACAGCGGC
    CCCAACAACA CCCAGGCCTG CGCCGTGCCC GAGCTGCAGT TCTCCAGCGA GCCCGGCAGT
    GAGGAGGTGA ACGGCAATGT GTTCCTGGAG GGTCCCTCCA CCGACCCCGT GCGCCTGGGA
    CACATCTACA CCAAGACGCT GCTGATCGAG TACACGGACG CGAGCTTCAC CACCGTCAAG
    CCGCGGCCGG CGGACGAGCA GTACCTGGGG CTGCTGGGGC CGGTCATGCG GGCCAACGTG
    GGGGACACCA TCAAGGTGGT GCTGAAGAAC GACGCCAAGA TCGACGTGAG CCTGCACCCT
    CACGGCGTGC GCTACAGCAA GGCCAACGAG GGCACGCTGT ACGAGGACGG CACCAGCGGC
    GCCGACAAGG CTGACGACGT GGTGGCGCCC GGCACCACCT ACACCTACGT CTGGAACGTT
    CCTGACCGCG CCGGCCCCGG CCCGTGCGAC CCCAGCTCCA TGCTGTGGAT GTACCACTCC
    CACATCGACG AGACCGCGGA GACCTACGCC GGTGTGGCGG GAGGCATCAT CGTCACCGCC
    AAGGACATGG CCCGCAGCAC TGCCGACCTG ACGCCCAAGG ACGTGGACCG CGAAATTGTC
    ATCTTCTTTA CCGTGGTGGA TGAGATCAAG TCCTCCAACT TCATGGAGAA CCTGGCCAAC
    AAGCTGGGCG ACGGCGGCGC GCTGGCGGCC CAGCTGGCGG CCAACGCCAC CGAGATGACT
    GCGCTGGTGA CCGACCCCGT CTTCATGGAG CACATGCTCA AGCACGGCAT CAACGGCCAC
    ATGTACTGCC ACATGCCCCG CCTCACCTTC GAGCAGGGCG ACAAGGTCCG GCTGCACGTG
    ATGGTGCTGG GCACGCTGGA GGACATGCAC ACGCCCAACA TGGGCGGCCC GCGGTTCGAC
    TACAACGGCA TGCACACCGA CTCCATCCAG ATCAGCCCGG GCGGCATGGT CAGCGCCGAC
    GTGCAGATGA CCTCGCCGGG CGACTACGAG CTGCAGTGCC GTGTGGCGGA CCACGTGATG
    GCGGGCATGC GCGCCAAGTA CACCGTCACC GCCAACGCCA GCCGCATGGT GGTCAACCCC
    TCGGGCGTCA CCCGCACCTA CTACATCCAG GCAGAGGCCG TCAACTGGGA CTACGCGCCC
    GCAGGCTACC AGAAGTGCAC CGACACGGAC TTCTCCTACC AGTCCTCCGT GTACCTGCGC
    CGCACCTCCT ACACCATCGG CTCGCGCTAC CGCAAGGCCG TCTACCGCGC CTACACCGAC
    GCCACCTTCT CCACCCGCGT GCCCACGCCC GCCTACTACG GCACCATGGG CCCCATGATC
    ATTGCCGAGG TGGGCGACCG CATTGTGGTC CACTTCAAGA ACGCCGTGAC CGACCTGGAG
    GAGTACCCGC TCAACATCAG CCCCGGCGGC GGCCTGCTGG TGGAGGGCGC GGCCGACGAG
    AACTGCGCCG AGGTGGCGGC GGGCGAGACC TGCGTGTACC GCTGGATCGT GCCTGACAGC
    TCCGGCCCGG GCACCGCCGA CTTCAACACG GCCGTGTACG GCTACACCAG CAGCGTGGAC
    GTGGCCACGG CGCCCAGCGC GGGCCTGGCG GGCGCGCTGG TGGTGGCGGG GCGCGGGCAG
    CTGGTGGCGG GGCCGGACGG CAGCCTGCTG CCCCGCGGCG TGGACCTCAT GGTGCCGCTG
    TACTGGCAGG TGGTTGACGA GAACTCCAGC CCCTTCCTCG ACCTCAACGT GGAGGCGGCG
    CAGCTCAATG TCACCAAGTT CGAGAACGAC GCCGTACTGA GCGCCGACTT CGATGAGGGC
    AACCGCATGC ACTCCATCAA CGGCTACGTC TACTGCAACC AGCCGCTGGT GACCATCGCC
    AAGGGCAAGA AGCTGCGCTG GGTGCTTGTG GCGTACGGCA CGGAGGGCGA CTTCCACAGC
    CCGCAGTTCA CGGGGCAGAG CTTGGAGGCC GACAAGTCGG GCTACTCCAC CCTGGCCTCG
    CTGATGCCCT CCATCGCGCG CGTGGCCGAC ATGACCGCCG CCGACGTGGG CACGTGGCTG
    CTGTACTGCG ACGTGCACGA CCACTACATG GCAGGCATGA TGTCGCAGTT CGCCGTCACG
    GCCGCGTAA

    The stop codons will be deleted if pcDNA3.1+/C-(K)DYK vector is selected.

    RefSeq XP_001694585.1
    CDS271..3699
    Translation

    Target ORF information:

    RefSeq Version XM_001694533.1
    Organism Chlamydomonas reinhardtii
    Definition Chlamydomonas reinhardtii multicopper ferroxidase (FOX1), mRNA.

    Target ORF information:

    Epitope DYKDDDDK
    Bacterial selection AMPR
    Mammalian selection NeoR
    Vector pcDNA3.1+/C-(K)DYK
    XM_001694533.1

    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
    3301
    3361
    3421
    ATGGACAGCA AGGAAGCGGC GGAGCCGGCC TCGGTCCACG TCAACGTGGA CGTGGAGGCC 
    CAGAAGGCCC AGGCGCAGGC GGAGGCCGCA GCCAAGGGCG GCGCGTGCGC AACAAGCGGC
    ATGAGCAAAG GGAAGATCAT CGTCACTTCC TTGGTGATTT TTCTGGGGGT AGCGGTGGGC
    GTGGGTCTGG GCGTTGGCCT GGGCGTGGGT CTGAAGAAGG ACGACGGCTC GTCGGCCTAC
    ACCTCCCTGG ACCTGGGCAC GGGGTCGGGC GGCGGCAACA CCTACTTCGT CGCGGCGGAC
    AAGATTCAAT GGAACTACGC GCCCTCGGGC CGCAACAAGT GCTTCCCGCC CGACCTGGCT
    GCCAAGTACT TGGCCATGCA GCCCGGCATC ACGCGTGTGG GCGGCACCTT CGCCAAGGCC
    ATCTACCGCG CCTACACAGA CAGCAGCTTC AACACCCTCG CCACCACGCC CGCTGAATGG
    CAGCACCTGG GCAACGTGGG CCCCGTCATG TACGGCGCCG TGGGTCAGGT CATTCGCGTG
    GTGTTCAAGA ACAACCTGGA CTTCCCCGTC AACATGGCTC CCAGCGGCGG CCTGATCGCC
    TGGGACGGCA ACGGCCGCCG CTCCGCCCGC ATCGACCCCG TGAAGCCCGG GCAGACAGTC
    ACCTACCTGT GGCAGATCCC CGAGGACGCT GGCCCGGTGG CCAACGCCAC TGTGACCAGC
    CGCCTGTGGC TGTACCGCAG TAGCGTGGAC CCGCAGAAGC ACGACAACGC AGGACTGGTG
    GGCCCCATCA TCGTCACCTC CGCCGCCAAC GCCGACGCCA ACGGCCGCGC CCGCGACGTG
    GACCGCGACG TGGTGGCCAT CTTCCAGATT GTGCAGGAGC GCGCCAGCCC GCTGCTGTTC
    CAGGAGGACA CCAGCCTCAG CGCCGGCACC TCCTACACCA AGATGGCCAT CAACGGCTAC
    ACCTGGTGCA ACATGCCCGA CGGTGCCATC ACCATCAAGA CCGGCGAGCG GGTGCGGTGG
    CACGTGGCCT CCATTGGCTC GTCGGAGTCG CTGCACAACT TCCACTGGCA CGGACACGTG
    GTGGAGCTCA ACGGGCACCA TGTGGACCAG TTCACCGCCA TCCCCACCGC CACCTACTCG
    GTCAACATGG TGCCGGACGA GCCCGGCACC TGGATGTTCC ACTGCCACGT TAACTTCCAC
    ATGGACGGCG GCATGGTCGC CCTCTACACC GTCACCGGCG ACCCCGCGCC CCTGCCCACC
    GGCGGCGTGG AGCGGGTGTA CTACGTGCGC GCGCAGGAGG TTGAGTGGAG CTACAGCGGC
    CCCAACAACA CCCAGGCCTG CGCCGTGCCC GAGCTGCAGT TCTCCAGCGA GCCCGGCAGT
    GAGGAGGTGA ACGGCAATGT GTTCCTGGAG GGTCCCTCCA CCGACCCCGT GCGCCTGGGA
    CACATCTACA CCAAGACGCT GCTGATCGAG TACACGGACG CGAGCTTCAC CACCGTCAAG
    CCGCGGCCGG CGGACGAGCA GTACCTGGGG CTGCTGGGGC CGGTCATGCG GGCCAACGTG
    GGGGACACCA TCAAGGTGGT GCTGAAGAAC GACGCCAAGA TCGACGTGAG CCTGCACCCT
    CACGGCGTGC GCTACAGCAA GGCCAACGAG GGCACGCTGT ACGAGGACGG CACCAGCGGC
    GCCGACAAGG CTGACGACGT GGTGGCGCCC GGCACCACCT ACACCTACGT CTGGAACGTT
    CCTGACCGCG CCGGCCCCGG CCCGTGCGAC CCCAGCTCCA TGCTGTGGAT GTACCACTCC
    CACATCGACG AGACCGCGGA GACCTACGCC GGTGTGGCGG GAGGCATCAT CGTCACCGCC
    AAGGACATGG CCCGCAGCAC TGCCGACCTG ACGCCCAAGG ACGTGGACCG CGAAATTGTC
    ATCTTCTTTA CCGTGGTGGA TGAGATCAAG TCCTCCAACT TCATGGAGAA CCTGGCCAAC
    AAGCTGGGCG ACGGCGGCGC GCTGGCGGCC CAGCTGGCGG CCAACGCCAC CGAGATGACT
    GCGCTGGTGA CCGACCCCGT CTTCATGGAG CACATGCTCA AGCACGGCAT CAACGGCCAC
    ATGTACTGCC ACATGCCCCG CCTCACCTTC GAGCAGGGCG ACAAGGTCCG GCTGCACGTG
    ATGGTGCTGG GCACGCTGGA GGACATGCAC ACGCCCAACA TGGGCGGCCC GCGGTTCGAC
    TACAACGGCA TGCACACCGA CTCCATCCAG ATCAGCCCGG GCGGCATGGT CAGCGCCGAC
    GTGCAGATGA CCTCGCCGGG CGACTACGAG CTGCAGTGCC GTGTGGCGGA CCACGTGATG
    GCGGGCATGC GCGCCAAGTA CACCGTCACC GCCAACGCCA GCCGCATGGT GGTCAACCCC
    TCGGGCGTCA CCCGCACCTA CTACATCCAG GCAGAGGCCG TCAACTGGGA CTACGCGCCC
    GCAGGCTACC AGAAGTGCAC CGACACGGAC TTCTCCTACC AGTCCTCCGT GTACCTGCGC
    CGCACCTCCT ACACCATCGG CTCGCGCTAC CGCAAGGCCG TCTACCGCGC CTACACCGAC
    GCCACCTTCT CCACCCGCGT GCCCACGCCC GCCTACTACG GCACCATGGG CCCCATGATC
    ATTGCCGAGG TGGGCGACCG CATTGTGGTC CACTTCAAGA ACGCCGTGAC CGACCTGGAG
    GAGTACCCGC TCAACATCAG CCCCGGCGGC GGCCTGCTGG TGGAGGGCGC GGCCGACGAG
    AACTGCGCCG AGGTGGCGGC GGGCGAGACC TGCGTGTACC GCTGGATCGT GCCTGACAGC
    TCCGGCCCGG GCACCGCCGA CTTCAACACG GCCGTGTACG GCTACACCAG CAGCGTGGAC
    GTGGCCACGG CGCCCAGCGC GGGCCTGGCG GGCGCGCTGG TGGTGGCGGG GCGCGGGCAG
    CTGGTGGCGG GGCCGGACGG CAGCCTGCTG CCCCGCGGCG TGGACCTCAT GGTGCCGCTG
    TACTGGCAGG TGGTTGACGA GAACTCCAGC CCCTTCCTCG ACCTCAACGT GGAGGCGGCG
    CAGCTCAATG TCACCAAGTT CGAGAACGAC GCCGTACTGA GCGCCGACTT CGATGAGGGC
    AACCGCATGC ACTCCATCAA CGGCTACGTC TACTGCAACC AGCCGCTGGT GACCATCGCC
    AAGGGCAAGA AGCTGCGCTG GGTGCTTGTG GCGTACGGCA CGGAGGGCGA CTTCCACAGC
    CCGCAGTTCA CGGGGCAGAG CTTGGAGGCC GACAAGTCGG GCTACTCCAC CCTGGCCTCG
    CTGATGCCCT CCATCGCGCG CGTGGCCGAC ATGACCGCCG CCGACGTGGG CACGTGGCTG
    CTGTACTGCG ACGTGCACGA CCACTACATG GCAGGCATGA TGTCGCAGTT CGCCGTCACG
    GCCGCGTAA

    The stop codons will be deleted if pcDNA3.1+/C-(K)DYK vector is selected.

  • PubMed

    The Chlamydomonas genome reveals the evolution of key animal and plant functions.
    Science (New York, N.Y.)318(5848)245-50(2007 Oct)
    Merchant SS,Prochnik SE,Vallon O,Harris EH,Karpowicz SJ,Witman GB,Terry A,Salamov A,Fritz-Laylin LK,Maréchal-Drouard L,Marshall WF,Qu LH,Nelson DR,Sanderfoot AA,Spalding MH,Kapitonov VV,Ren Q,Ferris P,Lindquist E,Shapiro H,Lucas SM,Grimwood J,Schmutz J,Cardol P,Cerutti H,Chanfreau G,Chen CL,Cognat V,Croft MT,Dent R,Dutcher S,Fernández E,Fukuzawa H,González-Ballester D,González-Halphen D,Hallmann A,Hanikenne M,Hippler M,Inwood W,Jabbari K,Kalanon M,Kuras R,Lefebvre PA,Lemaire SD,Lobanov AV,Lohr M,Manuell A,Meier I,Mets L,Mittag M,Mittelmeier T,Moroney JV,Moseley J,Napoli C,Nedelcu AM,Niyogi K,Novoselov SV,Paulsen IT,Pazour G,Purton S,Ral JP,Riaño-Pachón DM,Riekhof W,Rymarquis L,Schroda M,Stern D,Umen J,Willows R,Wilson N,Zimmer SL,Allmer J,Balk J,Bisova K,Chen CJ,Elias M,Gendler K,Hauser C,Lamb MR,Ledford H,Long JC,Minagawa J,Page MD,Pan J,Pootakham W,Roje S,Rose A,Stahlberg E,Terauchi AM,Yang P,Ball S,Bowler C,Dieckmann CL,Gladyshev VN,Green P,Jorgensen R,Mayfield S,Mueller-Roeber B,Rajamani S,Sayre RT,Brokstein P,Dubchak I,Goodstein D,Hornick L,Huang YW,Jhaveri J,Luo Y,Martínez D,Ngau WC,Otillar B,Poliakov A,Porter A,Szajkowski L,Werner G,Zhou K,Grigoriev IV,Rokhsar DS,Grossman AR