ORF » Species Summary » Homo sapiens » ADAM30 cDNA ORF clone

ADAM30 cDNA ORF clone, Homo sapiens(human)

  • Gene

  • Clones

  • gRNAs

The following ADAM30 gene cDNA ORF clone sequences were retrieved from the NCBI Reference Sequence Database (RefSeq). These sequences represent the protein coding region of the ADAM30 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
OHu12398 NM_021794.4
Latest version!		 Homo sapiens ADAM metallopeptidase domain 30 (ADAM30), mRNA. pcDNA3.1-C-(k)DYK or customized vector
in pcDNA3.1-C-(k)DYK 		$279.50-$391.30
$559.00
View Old Accession Versions >>
OHu12398 NM_021794.3 Homo sapiens ADAM metallopeptidase domain 30 (ADAM30), mRNA. pcDNA3.1-C-(k)DYK or customized vector TBD $265.30
$379.00
Hide Old Accession Versions >>

ORF Online Only Promotion

Next-day Shipping ORF Clones ( in default vector with tag)
1 Clone 30% OFF
2-4 Clone 40% OFF
5 or more Clone 50% OFF
All Other ORF Clones
30% OFF

*Business Day

** 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)
    ADAM30 ( NM_021794.4 ) cDNA ORF clone, Homo sapiens(human) -> NP_068566.2 Homo sapiens ADAM metallopeptidase domain 30 (ADAM30), mRNA.
    Price & Availability↑
    CloneID OHu12398
    Clone ID Related Accession (Same CDS sequence) NM_021794.3 , NM_021794.4
    Accession Version NM_021794.4 Latest version! Documents for ORF clone product in default vector
    Sequence Information ORF Nucleotide Sequence (Length: 2373bp)
    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 2019-10-20
    Organism Homo sapiens(human)
    Product disintegrin and metalloproteinase domain-containing protein 30 preproprotein
    Comment Comment: REVIEWED REFSEQ: This record has been curated by NCBI staff. The reference sequence was derived from AL359752.11 and BC028372.2. On May 17, 2019 this sequence version replaced NM_021794.3. Sequence Note: This RefSeq record was created from transcript and genomic sequence data to make the sequence consistent with the reference genome assembly. The genomic coordinates used for the transcript record were based on transcript alignments. ##Evidence-Data-START## Transcript is intronless :: BC028372.2, AK292483.1 [ECO:0000345] ##Evidence-Data-END## ##RefSeq-Attributes-START## MANE Ensembl match :: ENST00000369400.2/ ENSP00000358407.1 RefSeq Select criteria :: based on single protein-coding transcript ##RefSeq-Attributes-END## COMPLETENESS: complete on the 3' end. 

    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
    ATGAGGTCAG TGCAGATCTT CCTCTCCCAA TGCCGTTTGC TCCTTCTACT AGTTCCGACA 
    ATGCTCCTTA AGTCTCTTGG CGAAGATGTA ATTTTTCACC CTGAAGGGGA GTTTGACTCG 
    TATGAAGTCA CCATTCCTGA GAAGCTGAGC TTCCGGGGAG AGGTGCAGGG TGTGGTCAGT 
    CCCGTGTCCT ACCTACTGCA GTTAAAAGGC AAGAAGCACG TCCTCCATTT GTGGCCCAAG 
    AGACTTCTGT TGCCCCGACA TCTGCGCGTT TTCTCCTTCA CAGAACATGG GGAACTGCTG 
    GAGGATCATC CTTACATACC AAAGGACTGC AACTACATGG GCTCCGTGAA AGAGTCTCTG 
    GACTCTAAAG CTACTATAAG CACATGCATG GGGGGTCTCC GAGGTGTATT TAACATTGAT 
    GCCAAACATT ACCAAATTGA GCCCCTCAAG GCCTCTCCCA GTTTTGAACA TGTCGTCTAT 
    CTCCTGAAGA AAGAGCAGTT TGGGAATCAG GTTTGTGGCT TAAGTGATGA TGAAATAGAA 
    TGGCAGATGG CCCCTTATGA GAATAAGGCG AGGCTAAGGG ACTTTCCTGG ATCCTATAAA 
    CACCCAAAGT ACTTGGAATT GATCCTACTC TTTGATCAAA GTAGGTATAG GTTTGTGAAC 
    AACAATCTTT CTCAAGTCAT ACATGATGCC ATTCTTTTGA CTGGGATTAT GGACACCTAC 
    TTTCAAGATG TTCGTATGAG GATACACTTA AAGGCTCTTG AAGTATGGAC AGATTTTAAC 
    AAAATACGCG TTGGATATCC AGAGTTAGCT GAAGTTTTAG GCAGATTTGT AATATATAAA 
    AAAAGTGTAT TAAATGCTCG CCTGTCATCA GATTGGGCAC ATTTATATCT TCAAAGAAAA 
    TATAATGATG CTCTTGCATG GTCGTTTGGA AAAGTGTGTT CTCTAGAATA TGCTGGATCA 
    GTGAGTACTT TACTAGATAC AAATATCCTT GCCCCTGCTA CCTGGTCTGC TCATGAGCTG 
    GGTCATGCTG TAGGAATGTC ACATGATGAA CAATACTGCC AATGTAGGGG TAGGCTTAAT 
    TGCATCATGG GCTCAGGACG CACTGGGTTT AGCAATTGCA GTTATATCTC TTTTTTTAAA 
    CATATCTCTT CGGGAGCAAC ATGTCTAAAT AATATCCCAG GACTAGGTTA TGTGCTTAAG 
    AGATGTGGAA ACAAAATTGT GGAGGACAAT GAGGAATGTG ACTGTGGTTC CACAGAGGAG 
    TGTCAGAAAG ATCGGTGTTG CCAATCAAAT TGTAAGTTGC AACCAGGTGC CAACTGTAGC 
    ATTGGACTTT GCTGTCATGA TTGTCGGTTT CGTCCATCTG GATACGTGTG TAGGCAGGAA 
    GGAAATGAAT GTGACCTTGC AGAGTACTGC GACGGGAATT CAAGTTCCTG CCCAAATGAC 
    GTTTATAAGC AGGATGGAAC CCCTTGCAAG TATGAAGGCC GTTGTTTCAG GAAGGGGTGC 
    AGATCCAGAT ATATGCAGTG CCAAAGCATT TTTGGACCTG ATGCCATGGA GGCTCCTAGT 
    GAGTGCTATG ATGCAGTTAA CTTAATAGGT GATCAATTTG GTAACTGTGA GATTACAGGA 
    ATTCGAAATT TTAAAAAGTG TGAAAGTGCA AATTCAATAT GTGGCAGGCT ACAGTGTATA 
    AATGTTGAAA CCATCCCTGA TTTGCCAGAG CATACGACTA TAATTTCTAC TCATTTACAG 
    GCAGAAAATC TCATGTGCTG GGGCACAGGC TATCATCTAT CCATGAAACC CATGGGAATA 
    CCTGACCTAG GTATGATAAA TGATGGCACC TCCTGTGGAG AAGGCCGGGT ATGTTTTAAA 
    AAAAATTGCG TCAATAGCTC AGTCCTGCAG TTTGACTGTT TGCCTGAGAA ATGCAATACC 
    CGGGGTGTTT GCAACAACAG AAAAAACTGC CACTGCATGT ATGGGTGGGC ACCTCCATTC 
    TGTGAGGAAG TGGGGTATGG AGGAAGCATT GACAGTGGGC CTCCAGGACT GCTCAGAGGG 
    GCGATTCCCT CGTCAATTTG GGTTGTGTCC ATCATAATGT TTCGCCTTAT TTTATTAATC 
    CTTTCAGTGG TTTTTGTGTT TTTCCGGCAA GTGATAGGAA ACCACTTAAA ACCCAAACAG 
    GAAAAAATGC CACTATCCAA AGCAAAAACT GAACAGGAAG AATCTAAAAC AAAAACTGTA 
    CAGGAAGAAT CTAAAACAAA AACTGGACAG GAAGAATCTG AAGCAAAAAC TGGACAGGAA 
    GAATCTAAAG CAAAAACTGG ACAGGAAGAA TCTAAAGCAA ACATTGAAAG TAAACGACCC 
    AAAGCAAAGA GTGTCAAGAA ACAAAAAAAG TAA

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

    RefSeq NP_068566.2
    CDS180..2552
    Translation

    Target ORF information:

    RefSeq Version NM_021794.4
    Organism Homo sapiens(human)
    Definition Homo sapiens ADAM metallopeptidase domain 30 (ADAM30), mRNA.

    Target ORF information:

    Epitope DYKDDDDK
    Bacterial selection AMPR
    Mammalian selection NeoR
    Vector pcDNA3.1+/C-(K)DYK
    		 NM_021794.4

    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
    ATGAGGTCAG TGCAGATCTT CCTCTCCCAA TGCCGTTTGC TCCTTCTACT AGTTCCGACA 
    ATGCTCCTTA AGTCTCTTGG CGAAGATGTA ATTTTTCACC CTGAAGGGGA GTTTGACTCG 
    TATGAAGTCA CCATTCCTGA GAAGCTGAGC TTCCGGGGAG AGGTGCAGGG TGTGGTCAGT 
    CCCGTGTCCT ACCTACTGCA GTTAAAAGGC AAGAAGCACG TCCTCCATTT GTGGCCCAAG 
    AGACTTCTGT TGCCCCGACA TCTGCGCGTT TTCTCCTTCA CAGAACATGG GGAACTGCTG 
    GAGGATCATC CTTACATACC AAAGGACTGC AACTACATGG GCTCCGTGAA AGAGTCTCTG 
    GACTCTAAAG CTACTATAAG CACATGCATG GGGGGTCTCC GAGGTGTATT TAACATTGAT 
    GCCAAACATT ACCAAATTGA GCCCCTCAAG GCCTCTCCCA GTTTTGAACA TGTCGTCTAT 
    CTCCTGAAGA AAGAGCAGTT TGGGAATCAG GTTTGTGGCT TAAGTGATGA TGAAATAGAA 
    TGGCAGATGG CCCCTTATGA GAATAAGGCG AGGCTAAGGG ACTTTCCTGG ATCCTATAAA 
    CACCCAAAGT ACTTGGAATT GATCCTACTC TTTGATCAAA GTAGGTATAG GTTTGTGAAC 
    AACAATCTTT CTCAAGTCAT ACATGATGCC ATTCTTTTGA CTGGGATTAT GGACACCTAC 
    TTTCAAGATG TTCGTATGAG GATACACTTA AAGGCTCTTG AAGTATGGAC AGATTTTAAC 
    AAAATACGCG TTGGATATCC AGAGTTAGCT GAAGTTTTAG GCAGATTTGT AATATATAAA 
    AAAAGTGTAT TAAATGCTCG CCTGTCATCA GATTGGGCAC ATTTATATCT TCAAAGAAAA 
    TATAATGATG CTCTTGCATG GTCGTTTGGA AAAGTGTGTT CTCTAGAATA TGCTGGATCA 
    GTGAGTACTT TACTAGATAC AAATATCCTT GCCCCTGCTA CCTGGTCTGC TCATGAGCTG 
    GGTCATGCTG TAGGAATGTC ACATGATGAA CAATACTGCC AATGTAGGGG TAGGCTTAAT 
    TGCATCATGG GCTCAGGACG CACTGGGTTT AGCAATTGCA GTTATATCTC TTTTTTTAAA 
    CATATCTCTT CGGGAGCAAC ATGTCTAAAT AATATCCCAG GACTAGGTTA TGTGCTTAAG 
    AGATGTGGAA ACAAAATTGT GGAGGACAAT GAGGAATGTG ACTGTGGTTC CACAGAGGAG 
    TGTCAGAAAG ATCGGTGTTG CCAATCAAAT TGTAAGTTGC AACCAGGTGC CAACTGTAGC 
    ATTGGACTTT GCTGTCATGA TTGTCGGTTT CGTCCATCTG GATACGTGTG TAGGCAGGAA 
    GGAAATGAAT GTGACCTTGC AGAGTACTGC GACGGGAATT CAAGTTCCTG CCCAAATGAC 
    GTTTATAAGC AGGATGGAAC CCCTTGCAAG TATGAAGGCC GTTGTTTCAG GAAGGGGTGC 
    AGATCCAGAT ATATGCAGTG CCAAAGCATT TTTGGACCTG ATGCCATGGA GGCTCCTAGT 
    GAGTGCTATG ATGCAGTTAA CTTAATAGGT GATCAATTTG GTAACTGTGA GATTACAGGA 
    ATTCGAAATT TTAAAAAGTG TGAAAGTGCA AATTCAATAT GTGGCAGGCT ACAGTGTATA 
    AATGTTGAAA CCATCCCTGA TTTGCCAGAG CATACGACTA TAATTTCTAC TCATTTACAG 
    GCAGAAAATC TCATGTGCTG GGGCACAGGC TATCATCTAT CCATGAAACC CATGGGAATA 
    CCTGACCTAG GTATGATAAA TGATGGCACC TCCTGTGGAG AAGGCCGGGT ATGTTTTAAA 
    AAAAATTGCG TCAATAGCTC AGTCCTGCAG TTTGACTGTT TGCCTGAGAA ATGCAATACC 
    CGGGGTGTTT GCAACAACAG AAAAAACTGC CACTGCATGT ATGGGTGGGC ACCTCCATTC 
    TGTGAGGAAG TGGGGTATGG AGGAAGCATT GACAGTGGGC CTCCAGGACT GCTCAGAGGG 
    GCGATTCCCT CGTCAATTTG GGTTGTGTCC ATCATAATGT TTCGCCTTAT TTTATTAATC 
    CTTTCAGTGG TTTTTGTGTT TTTCCGGCAA GTGATAGGAA ACCACTTAAA ACCCAAACAG 
    GAAAAAATGC CACTATCCAA AGCAAAAACT GAACAGGAAG AATCTAAAAC AAAAACTGTA 
    CAGGAAGAAT CTAAAACAAA AACTGGACAG GAAGAATCTG AAGCAAAAAC TGGACAGGAA 
    GAATCTAAAG CAAAAACTGG ACAGGAAGAA TCTAAAGCAA ACATTGAAAG TAAACGACCC 
    AAAGCAAAGA GTGTCAAGAA ACAAAAAAAG TAA

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

    ADAM30 ( NM_021794.3 ) cDNA ORF clone, Homo sapiens(human) -> NP_068566.2 Homo sapiens ADAM metallopeptidase domain 30 (ADAM30), mRNA.
    Price & Availability↑
    CloneID OHu12398
    Clone ID Related Accession (Same CDS sequence) NM_021794.3 , NM_021794.4
    Accession Version NM_021794.3 Documents for ORF clone product in default vector
    Sequence Information ORF Nucleotide Sequence (Length: 2373bp)
    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 2019-02-22
    Organism Homo sapiens(human)
    Product disintegrin and metalloproteinase domain-containing protein 30 preproprotein
    Comment Comment: REVIEWED REFSEQ: This record has been curated by NCBI staff. The reference sequence was derived from AL359752.11 and BC028372.2. On Feb 24, 2011 this sequence version replaced NM_021794.2. Sequence Note: This RefSeq record was created from transcript and genomic sequence data to make the sequence consistent with the reference genome assembly. The genomic coordinates used for the transcript record were based on transcript alignments. ##Evidence-Data-START## Transcript is intronless :: BC028372.2 [ECO:0000345] ##Evidence-Data-END## COMPLETENESS: complete on the 3' end. 

    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
    ATGAGGTCAG TGCAGATCTT CCTCTCCCAA TGCCGTTTGC TCCTTCTACT AGTTCCGACA 
    ATGCTCCTTA AGTCTCTTGG CGAAGATGTA ATTTTTCACC CTGAAGGGGA GTTTGACTCG 
    TATGAAGTCA CCATTCCTGA GAAGCTGAGC TTCCGGGGAG AGGTGCAGGG TGTGGTCAGT 
    CCCGTGTCCT ACCTACTGCA GTTAAAAGGC AAGAAGCACG TCCTCCATTT GTGGCCCAAG 
    AGACTTCTGT TGCCCCGACA TCTGCGCGTT TTCTCCTTCA CAGAACATGG GGAACTGCTG 
    GAGGATCATC CTTACATACC AAAGGACTGC AACTACATGG GCTCCGTGAA AGAGTCTCTG 
    GACTCTAAAG CTACTATAAG CACATGCATG GGGGGTCTCC GAGGTGTATT TAACATTGAT 
    GCCAAACATT ACCAAATTGA GCCCCTCAAG GCCTCTCCCA GTTTTGAACA TGTCGTCTAT 
    CTCCTGAAGA AAGAGCAGTT TGGGAATCAG GTTTGTGGCT TAAGTGATGA TGAAATAGAA 
    TGGCAGATGG CCCCTTATGA GAATAAGGCG AGGCTAAGGG ACTTTCCTGG ATCCTATAAA 
    CACCCAAAGT ACTTGGAATT GATCCTACTC TTTGATCAAA GTAGGTATAG GTTTGTGAAC 
    AACAATCTTT CTCAAGTCAT ACATGATGCC ATTCTTTTGA CTGGGATTAT GGACACCTAC 
    TTTCAAGATG TTCGTATGAG GATACACTTA AAGGCTCTTG AAGTATGGAC AGATTTTAAC 
    AAAATACGCG TTGGATATCC AGAGTTAGCT GAAGTTTTAG GCAGATTTGT AATATATAAA 
    AAAAGTGTAT TAAATGCTCG CCTGTCATCA GATTGGGCAC ATTTATATCT TCAAAGAAAA 
    TATAATGATG CTCTTGCATG GTCGTTTGGA AAAGTGTGTT CTCTAGAATA TGCTGGATCA 
    GTGAGTACTT TACTAGATAC AAATATCCTT GCCCCTGCTA CCTGGTCTGC TCATGAGCTG 
    GGTCATGCTG TAGGAATGTC ACATGATGAA CAATACTGCC AATGTAGGGG TAGGCTTAAT 
    TGCATCATGG GCTCAGGACG CACTGGGTTT AGCAATTGCA GTTATATCTC TTTTTTTAAA 
    CATATCTCTT CGGGAGCAAC ATGTCTAAAT AATATCCCAG GACTAGGTTA TGTGCTTAAG 
    AGATGTGGAA ACAAAATTGT GGAGGACAAT GAGGAATGTG ACTGTGGTTC CACAGAGGAG 
    TGTCAGAAAG ATCGGTGTTG CCAATCAAAT TGTAAGTTGC AACCAGGTGC CAACTGTAGC 
    ATTGGACTTT GCTGTCATGA TTGTCGGTTT CGTCCATCTG GATACGTGTG TAGGCAGGAA 
    GGAAATGAAT GTGACCTTGC AGAGTACTGC GACGGGAATT CAAGTTCCTG CCCAAATGAC 
    GTTTATAAGC AGGATGGAAC CCCTTGCAAG TATGAAGGCC GTTGTTTCAG GAAGGGGTGC 
    AGATCCAGAT ATATGCAGTG CCAAAGCATT TTTGGACCTG ATGCCATGGA GGCTCCTAGT 
    GAGTGCTATG ATGCAGTTAA CTTAATAGGT GATCAATTTG GTAACTGTGA GATTACAGGA 
    ATTCGAAATT TTAAAAAGTG TGAAAGTGCA AATTCAATAT GTGGCAGGCT ACAGTGTATA 
    AATGTTGAAA CCATCCCTGA TTTGCCAGAG CATACGACTA TAATTTCTAC TCATTTACAG 
    GCAGAAAATC TCATGTGCTG GGGCACAGGC TATCATCTAT CCATGAAACC CATGGGAATA 
    CCTGACCTAG GTATGATAAA TGATGGCACC TCCTGTGGAG AAGGCCGGGT ATGTTTTAAA 
    AAAAATTGCG TCAATAGCTC AGTCCTGCAG TTTGACTGTT TGCCTGAGAA ATGCAATACC 
    CGGGGTGTTT GCAACAACAG AAAAAACTGC CACTGCATGT ATGGGTGGGC ACCTCCATTC 
    TGTGAGGAAG TGGGGTATGG AGGAAGCATT GACAGTGGGC CTCCAGGACT GCTCAGAGGG 
    GCGATTCCCT CGTCAATTTG GGTTGTGTCC ATCATAATGT TTCGCCTTAT TTTATTAATC 
    CTTTCAGTGG TTTTTGTGTT TTTCCGGCAA GTGATAGGAA ACCACTTAAA ACCCAAACAG 
    GAAAAAATGC CACTATCCAA AGCAAAAACT GAACAGGAAG AATCTAAAAC AAAAACTGTA 
    CAGGAAGAAT CTAAAACAAA AACTGGACAG GAAGAATCTG AAGCAAAAAC TGGACAGGAA 
    GAATCTAAAG CAAAAACTGG ACAGGAAGAA TCTAAAGCAA ACATTGAAAG TAAACGACCC 
    AAAGCAAAGA GTGTCAAGAA ACAAAAAAAG TAA

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

    RefSeq NP_068566.2
    CDS189..2561
    Translation

    Target ORF information:

    RefSeq Version NM_021794.3
    Organism Homo sapiens(human)
    Definition Homo sapiens ADAM metallopeptidase domain 30 (ADAM30), mRNA.

    Target ORF information:

    Epitope DYKDDDDK
    Bacterial selection AMPR
    Mammalian selection NeoR
    Vector pcDNA3.1+/C-(K)DYK
    		 NM_021794.3

    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
    ATGAGGTCAG TGCAGATCTT CCTCTCCCAA TGCCGTTTGC TCCTTCTACT AGTTCCGACA 
    ATGCTCCTTA AGTCTCTTGG CGAAGATGTA ATTTTTCACC CTGAAGGGGA GTTTGACTCG 
    TATGAAGTCA CCATTCCTGA GAAGCTGAGC TTCCGGGGAG AGGTGCAGGG TGTGGTCAGT 
    CCCGTGTCCT ACCTACTGCA GTTAAAAGGC AAGAAGCACG TCCTCCATTT GTGGCCCAAG 
    AGACTTCTGT TGCCCCGACA TCTGCGCGTT TTCTCCTTCA CAGAACATGG GGAACTGCTG 
    GAGGATCATC CTTACATACC AAAGGACTGC AACTACATGG GCTCCGTGAA AGAGTCTCTG 
    GACTCTAAAG CTACTATAAG CACATGCATG GGGGGTCTCC GAGGTGTATT TAACATTGAT 
    GCCAAACATT ACCAAATTGA GCCCCTCAAG GCCTCTCCCA GTTTTGAACA TGTCGTCTAT 
    CTCCTGAAGA AAGAGCAGTT TGGGAATCAG GTTTGTGGCT TAAGTGATGA TGAAATAGAA 
    TGGCAGATGG CCCCTTATGA GAATAAGGCG AGGCTAAGGG ACTTTCCTGG ATCCTATAAA 
    CACCCAAAGT ACTTGGAATT GATCCTACTC TTTGATCAAA GTAGGTATAG GTTTGTGAAC 
    AACAATCTTT CTCAAGTCAT ACATGATGCC ATTCTTTTGA CTGGGATTAT GGACACCTAC 
    TTTCAAGATG TTCGTATGAG GATACACTTA AAGGCTCTTG AAGTATGGAC AGATTTTAAC 
    AAAATACGCG TTGGATATCC AGAGTTAGCT GAAGTTTTAG GCAGATTTGT AATATATAAA 
    AAAAGTGTAT TAAATGCTCG CCTGTCATCA GATTGGGCAC ATTTATATCT TCAAAGAAAA 
    TATAATGATG CTCTTGCATG GTCGTTTGGA AAAGTGTGTT CTCTAGAATA TGCTGGATCA 
    GTGAGTACTT TACTAGATAC AAATATCCTT GCCCCTGCTA CCTGGTCTGC TCATGAGCTG 
    GGTCATGCTG TAGGAATGTC ACATGATGAA CAATACTGCC AATGTAGGGG TAGGCTTAAT 
    TGCATCATGG GCTCAGGACG CACTGGGTTT AGCAATTGCA GTTATATCTC TTTTTTTAAA 
    CATATCTCTT CGGGAGCAAC ATGTCTAAAT AATATCCCAG GACTAGGTTA TGTGCTTAAG 
    AGATGTGGAA ACAAAATTGT GGAGGACAAT GAGGAATGTG ACTGTGGTTC CACAGAGGAG 
    TGTCAGAAAG ATCGGTGTTG CCAATCAAAT TGTAAGTTGC AACCAGGTGC CAACTGTAGC 
    ATTGGACTTT GCTGTCATGA TTGTCGGTTT CGTCCATCTG GATACGTGTG TAGGCAGGAA 
    GGAAATGAAT GTGACCTTGC AGAGTACTGC GACGGGAATT CAAGTTCCTG CCCAAATGAC 
    GTTTATAAGC AGGATGGAAC CCCTTGCAAG TATGAAGGCC GTTGTTTCAG GAAGGGGTGC 
    AGATCCAGAT ATATGCAGTG CCAAAGCATT TTTGGACCTG ATGCCATGGA GGCTCCTAGT 
    GAGTGCTATG ATGCAGTTAA CTTAATAGGT GATCAATTTG GTAACTGTGA GATTACAGGA 
    ATTCGAAATT TTAAAAAGTG TGAAAGTGCA AATTCAATAT GTGGCAGGCT ACAGTGTATA 
    AATGTTGAAA CCATCCCTGA TTTGCCAGAG CATACGACTA TAATTTCTAC TCATTTACAG 
    GCAGAAAATC TCATGTGCTG GGGCACAGGC TATCATCTAT CCATGAAACC CATGGGAATA 
    CCTGACCTAG GTATGATAAA TGATGGCACC TCCTGTGGAG AAGGCCGGGT ATGTTTTAAA 
    AAAAATTGCG TCAATAGCTC AGTCCTGCAG TTTGACTGTT TGCCTGAGAA ATGCAATACC 
    CGGGGTGTTT GCAACAACAG AAAAAACTGC CACTGCATGT ATGGGTGGGC ACCTCCATTC 
    TGTGAGGAAG TGGGGTATGG AGGAAGCATT GACAGTGGGC CTCCAGGACT GCTCAGAGGG 
    GCGATTCCCT CGTCAATTTG GGTTGTGTCC ATCATAATGT TTCGCCTTAT TTTATTAATC 
    CTTTCAGTGG TTTTTGTGTT TTTCCGGCAA GTGATAGGAA ACCACTTAAA ACCCAAACAG 
    GAAAAAATGC CACTATCCAA AGCAAAAACT GAACAGGAAG AATCTAAAAC AAAAACTGTA 
    CAGGAAGAAT CTAAAACAAA AACTGGACAG GAAGAATCTG AAGCAAAAAC TGGACAGGAA 
    GAATCTAAAG CAAAAACTGG ACAGGAAGAA TCTAAAGCAA ACATTGAAAG TAAACGACCC 
    AAAGCAAAGA GTGTCAAGAA ACAAAAAAAG TAA

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

  • PubMed

    ADAM30 Downregulates APP-Linked Defects Through Cathepsin D Activation in Alzheimer's Disease.
    EBioMedicine9278-292(2016 Jul)
    Letronne F,Laumet G,Ayral AM,Chapuis J,Demiautte F,Laga M,Vandenberghe ME,Malmanche N,Leroux F,Eysert F,Sottejeau Y,Chami L,Flaig A,Bauer C,Dourlen P,Lesaffre M,Delay C,Huot L,Dumont J,Werkmeister E,Lafont F,Mendes T,Hansmannel F,Dermaut B,Deprez B,H?rard AS,Dhenain M,Souedet N,Pasquier F,Tulasne D,Berr C,Hauw JJ,Lemoine Y,Amouyel P,Mann D,D?prez R,Checler F,Hot D,Delzescaux T,Gevaert K,Lambert JC


    Host-microbe interactions have shaped the genetic architecture of inflammatory bowel disease.
    Nature491(7422)119-24(2012 Nov)
    Jostins L,Ripke S,Weersma RK,Duerr RH,McGovern DP,Hui KY,Lee JC,Schumm LP,Sharma Y,Anderson CA,Essers J,Mitrovic M,Ning K,Cleynen I,Theatre E,Spain SL,Raychaudhuri S,Goyette P,Wei Z,Abraham C,Achkar JP,Ahmad T,Amininejad L,Ananthakrishnan AN,Andersen V,Andrews JM,Baidoo L,Balschun T,Bampton PA,Bitton A,Boucher G,Brand S,B?ning C,Cohain A,Cichon S,D'Amato M,De Jong D,Devaney KL,Dubinsky M,Edwards C,Ellinghaus D,Ferguson LR,Franchimont D,Fransen K,Gearry R,Georges M,Gieger C,Glas J,Haritunians T,Hart A,Hawkey C,Hedl M,Hu X,Karlsen TH,Kupcinskas L,Kugathasan S,Latiano A,Laukens D,Lawrance IC,Lees CW,Louis E,Mahy G,Mansfield J,Morgan AR,Mowat C,Newman W,Palmieri O,Ponsioen CY,Potocnik U,Prescott NJ,Regueiro M,Rotter JI,Russell RK,Sanderson JD,Sans M,Satsangi J,Schreiber S,Simms LA,Sventoraityte J,Targan SR,Taylor KD,Tremelling M,Verspaget HW,De Vos M,Wijmenga C,Wilson DC,Winkelmann J,Xavier RJ,Zeissig S,Zhang B,Zhang CK,Zhao H,,Silverberg MS,Annese V,Hakonarson H,Brant SR,Radford-Smith G,Mathew CG,Rioux JD,Schadt EE,Daly MJ,Franke A,Parkes M,Vermeire S,Barrett JC,Cho JH


    PPARG, KCNJ11, CDKAL1, CDKN2A-CDKN2B, IDE-KIF11-HHEX, IGF2BP2 and SLC30A8 are associated with type 2 diabetes in a Chinese population.
    PloS one4(10)e7643(2009 Oct)
    Hu C,Zhang R,Wang C,Wang J,Ma X,Lu J,Qin W,Hou X,Wang C,Bao Y,Xiang K,Jia W


    Assessing the combined impact of 18 common genetic variants of modest effect sizes on type 2 diabetes risk.
    Diabetes57(11)3129-35(2008 Nov)
    Lango H,,Palmer CN,Morris AD,Zeggini E,Hattersley AT,McCarthy MI,Frayling TM,Weedon MN


    Meta-analysis of genome-wide association data and large-scale replication identifies additional susceptibility loci for type 2 diabetes.
    Nature genetics40(5)638-45(2008 May)
    Zeggini E,Scott LJ,Saxena R,Voight BF,Marchini JL,Hu T,de Bakker PI,Abecasis GR,Almgren P,Andersen G,Ardlie K,Bostr?m KB,Bergman RN,Bonnycastle LL,Borch-Johnsen K,Burtt NP,Chen H,Chines PS,Daly MJ,Deodhar P,Ding CJ,Doney AS,Duren WL,Elliott KS,Erdos MR,Frayling TM,Freathy RM,Gianniny L,Grallert H,Grarup N,Groves CJ,Guiducci C,Hansen T,Herder C,Hitman GA,Hughes TE,Isomaa B,Jackson AU,J?rgensen T,Kong A,Kubalanza K,Kuruvilla FG,Kuusisto J,Langenberg C,Lango H,Lauritzen T,Li Y,Lindgren CM,Lyssenko V,Marvelle AF,Meisinger C,Midthjell K,Mohlke KL,Morken MA,Morris AD,Narisu N,Nilsson P,Owen KR,Palmer CN,Payne F,Perry JR,Pettersen E,Platou C,Prokopenko I,Qi L,Qin L,Rayner NW,Rees M,Roix JJ,Sandbaek A,Shields B,Sj?gren M,Steinthorsdottir V,Stringham HM,Swift AJ,Thorleifsson G,Thorsteinsdottir U,Timpson NJ,Tuomi T,Tuomilehto J,Walker M,Watanabe RM,Weedon MN,Willer CJ,,Illig T,Hveem K,Hu FB,Laakso M,Stefansson K,Pedersen O,Wareham NJ,Barroso I,Hattersley AT,Collins FS,Groop L,McCarthy MI,Boehnke M,Altshuler D


見積依頼

Eメール

japanmarket@genscript.com

電話

03-6811-6572

FAX

03-6811-6573
050-3174-7589(受注専用)

オンラインフォーム

オンライン注文