Mouse Plxnb2/Debt/plexin-B2 ORF/cDNA clone-Mammalian (Non-Viral Vector) plasmid (NM_001159521.2)

Name: Mouse Plxnb2 Mammalian (Non-Viral Vector) plasmid
Brand: GeneMedi
SKU: pGMPC001565
Price: 2762.76 USD
Availability: InStock
Rating: 5 (12 reviews)

Cat. No.: pGMPC001565
Size: 10 µg
Concentration: generally 0.5ug/ul, usually not less than 0.3ug/ul
Leading Time: 3-7 working days

Pre-made Mouse Plxnb2/Debt/plexin-B2 Non-Viral expression plasmid (overexpression vector) for mouse Plxnb2 overexpression in unique cell transient transfection and stable cell line development.

Datasheet

MSDS

Purchase

Select a Price Option:

Quantity:

Shipping fee: Limited-time free

For payment issues, contact us.

Product Description

Catalog ID	pGMPC001565
Gene Name	Plxnb2
Accession Number	NM_001159521.2
Gene ID	140570
Species	Mouse
Product Type	Mammalian (Non-Viral Vector) plasmid (overexpression)
Insert Length	5529 bp
Gene Alias	Debt,plexin-B2
Fluorescent Reporter	ZsGreen
Mammalian Cell Selection	Puromyocin
Fusion Tag	Null
Promoter	CMV
Resistance	Amplicin
ORF Nucleotide Sequence	ATGGCTCTGCCACTCTGGGCCCTGACCTTTCTAGGTCTCACGGGCCTAGGGTTGAGCCTGCGGTCCCGAAAGCCGGAGAGTTTCCGCAGTGAGACAGAGCTGAACCACCTGGCTGTGGATGAGGTCACAGGTGTGGTGTATGTCGGGGCAGTGAACGCGCTCTACCAGCTGAGTGCCGACCTGCACGTCCAGCAGCACGTGGTCACAGGCCCCTTCATGGATAACAAGAAGTGCACACCACCCATTGAGGCCAGCCAGTGCCACGAAGCGGTGCTCACTGACAACTTCAACCAGCTGCTGCTGCTCGACCCACCGGGGAAACGCCTGGTGGAGTGCGGCAGCCTCTTCAAGGGCATCTGTGCCCTGCGCGCCATGAGCAACATCTCGGTGCGCCTCTTCTACGAGGATGGCAGCGGCGAGAAGTCCTTCGTGGCCAGCAATGACGAGAGAGTGGCCACCGTGGGGCTGGTGACCTCCACGCGCCCCGACGGCGAGCGCGTGCTGTTTGTGGGCAAAGGCAATGGGCCGCACGACAATGGTATCATCGTGAGCACCCGCCTGCTGGACAGGGCTGAGGGCCGGGAGGCCTTTGAGGCCTACTCTGACCACACCACCTTCAAGGCCGGCTACCTGTCCACGAATACTCAGCAGTTTGTCGCAGCCTTTGAGGATGATTTCTATGTCTTCTTCGTCTTTAACCATCAAGACAAGCATCCTGCTAAGAACCGCACGCTGCTGGCGCGCATGTGCAAAGACGACCCCTCCTACTATTCCTATGTAGAGATGGACCTGCAGTGTCAGGATCCCAGTGACCCCCAAGACTCTGCCTTTGGCACCTGCCTAGCCGCTTCTGTAGCCACATCGGGTGCTGGCAGAGCACTTTATGCTGTCTTCAGCAGAGATGGCCGGAGCACTGGGGGACCTGGCGCGGGCCTCTGTGTGTTCCCGCTAGATAAAGTCCGTGAGAAGATAGAAGCCAACCGTAACGCCTGCTACACAGGTGCCCGAGAGGCAGGCCGCACTATCTTCTACAAGCCCTTCCACGGAGAAATCCAGTGTGGCGGCCATCTGATAGGTGCCAGCGAGAGCTTCCCATGCGGCTCGGAGCATCTGCCCTATCCACTGGGCAGTCGTGATGGACTCGTCGCCACAGCCGTGCTGCACCGCGGGGGCCTGAATCTGACAGCAGTGACAGTAACTGCCGAGAATGACCACACTGTTGCGTTCCTGGGCACCTCAGATGGCCGGATCCTTAAGGTGTACCTTGCTCCAGACGGCACTTCTGCAGAGTATGGTTCTATCCCAGTAGACATCAATAAGAAAATCAAGCAGGACCTGGCACTGTCTGGAAACCTGTCCAGTCTGTATGCTATGACCCAGGACAAGGTGTTCCGGCTCCCAGTACAAGAATGCCTGAGCTATGTAACCTGCGCTCAGTGTCGTGACTCCCAAGATCCCTACTGTGGCTGGTGTGTCATCGAGGGACGATGCACCAGGAAGTCCGAGTGCTCACGGGCCGAGGAAACCGGACACTGGCTGTGGAGCCGGGAGAAGTCCTGTGTGGCCATCACTGATGCCTTTCCACAGAACATGAGCCGGCGGGCCCAAGGAGAGGTACGCCTGTCTGTCAGCCCCCTGCCCACCCTGACTGAGGACGATGAGTTACTGTGCCTCTTTGGTGACTCACCACCCCACCCTGCCCGGGTAGAGGACGATACCGTCATCTGTAATTCCCCAAGCAGCATCCCTAGTACACCGCCAGGCCAAGACCATGTTGACGTGAGCATCCAGCTCCTCTTAAAAAGCGGCAGTGTCTTCCTCACCTCCCACCAGTATCCCTTCTATGACTGCCGTGAGGCCATGAGCCTGGTGGAGAACCTGCCGTGCATCTCTTGTGCTAGCAACCGCTGGACTTGCCAATGGGACCTGCAGTACTACGAGTGTCGGGAGGCTTCGCCCAACCCAGAGGAGGGAATCATACGTGCCCACATGGAGGACAACTGCCCCCAGTTCCTGGCCCCTGACCCTTTGGTCATCCCCATGAACCATGAGACAGAGGTGACCTTCCAGGGCAAGAACTTGGAGACTGTGAAGGTTTCTTCCCTGTATGTGGGCAGTGAGCTGCTGAATTTTGAAGAGACTGTGACCATGCATGAATCAGACACCTTCTCTTTTAGGACCCCAAAGCTATCCCATGATGGTAATGAGACACTGCCTCTTCACCTGTATGTTAAGTCCTTTGGCAAGAACATTGACAGCAAGCTACAAGTGACTCTCTACAACTGCTCCTTTGGCCGCAGTGACTGTAGCCTGTGTCTGGCTGCCGATCCTGCCTACAGGTGTGTGTGGTGCCGTGGGCAGAACCGGTGCGTGTACGAAGCTCTGTGCAGCAATGTCACTTCTGAGTGCCCACCACCAGTTATCACTAGGATCCAGCCTGAGACGGGCCCGCTGGGTGGGGGCATCCTGGTCACTATCCATGGGTCCAATCTGGGTGTCAAAGCAGATGACGTCAAGAAGATAACTGTGGCTGGCCAGAACTGTGCCTTTGAACCAAGAGGGTACTCCGTATCCACCCGGATTGTGTGTGCAATTGAGGCTTCGGAGATGCCCTTCACAGGAGGCATTGAGGTGGATGTTAATGGAAAACTCGGCCATTCACCGCCACACGTCCAGTTCACTTATCAACAACCCCAGCCTCTCAGTGTGGAGCCACGACAGGGGCCACAGGCAGGTGGCACCACATTGACCATCAATGGCACTCACCTGGACACAGGCTCCAAGGAGGATGTGCGGGTGACACTCAATGACGTCCCTTGTGAAGTGACAAAGTTTGGAGCACAGCTACAGTGTGTCACAGGTCAACAGTTGGCTCCAGGCCAGGTGACACTAGAAATCTACTATGGGGGCTCCAGAGTGCCCAGCCCCGGCATCTCTTTCACCTACTGCGAGAACCCCATGATACGAGCCTTTGAGCCATTGAGAAGCTTTGTCAGTGGTGGCCGGAGCATCAACGTTACTGGCCAGGGCTTCAGCCTCATCCAGAAGTTTGCCATGGTTGTCATCGCTGAGCCCTTGCGGTCCTGGAGGCGGCGGCGGCGGGAGGCTGGAGCCCTGGAGCGTGTGACGGTCGAGGGCATGGAGTACGTGTTCTACAACGACACCAAGGTCGTCTTCTTGTCTCCTGCTGTCCCCGAAGAGCCCGAGGCTTACAACCTCACCGTGCTGATACGGATGGACGGTCACTGTGCCCCGCTCAGGACCGAAGCCGGAGTCTTTGAGTATGTGGCAGACCCCACCTTTGAGAACTTCACGGGTGGCGTCAAAAAGCAGGTCAACAAGCTCATCCACGCCCGGGGAACCAATCTGAACAAAGCCATGACTCTGGAGGAGGCAGAGGCATTTGTGGGTGCTGAGCGTTGCATTATGAAGACGCTGACCGAGACGGACCTGTACTGCGAGCCCCCAGAGGTGCAGCCTCCACCCAAGCGGCGGCAGAAGCGAGACACGGCACACAACCTACCTGAGTTCATTGTGAAGTTTGGCTCCCGAGAGTGGGTGCTAGGCCGAGTGGAGTACGACACGCGTGCGAGTGACGTGCCGCTCAGTCTCATCCTGCCTCTGGTCATGGTACCCATGGTGTTTATCATCGTGGTCTCCATCTACTGCTACTGGAGGAAGAGCCAGCAGGCCGAGCGCGAGTACGAGAAGATCAAATCCCAGCTCGAGGGCTTGGAGGAGAGCGTGCGTGACCGCTGCAAGAAGGAATTCACAGACCTGATGATCGAGATGGAGGACCAGACGAATGACGTGCATGAGGCAGGCATCCCCACGCTGGACTACAAGACCTACACCGACCGCGTATTCTTCCTGCCATCCAAGGATGGTGACAAGGATGTGATGATCACCGGCAAGCTAGACATCCCTGAGTCACGGCGGCCCATTGTGGAGCAAGCCCTCTACCAGTTCTCCAACCTGCTTAATAGCAAGTCCTTCCTCATCAATTTCATCCACACCCTGGAGAATCAGCGTGAGTTCTCAGCTCGGGCCAAGGTCTACTTTGCATCACTGCTGACTGTGGCCCTGCACGGGAAGCTGGAGTACTACACGGACATCATGCGCACGCTCTTCCTGGAGCTCATGGAGCAGTATGTGGTGGCCAAGAACCCCAAGCTAATGCTGCGCAGGTCTGAGACAGTGGTGGAGAGGATGCTGTCCAACTGGATGTCCATCTGTCTGTACCAGTACCTCAAGGATAGTGCAGGGGAGCCTCTCTACAAGCTCTTCAAGGCCATCAAACACCAGGTGGAAAAGGGGCCCGTGGATGCTGTGCAGAAGAAGGCCAAGTACACCCTCAATGACACAGGCCTGCTCGGGGACGATGTTGAGTATGCGCCTCTGACCGTGAGCGTGATTGTTCAGGATGAAGGGATCGATGCCATCCCGGTTAAGGTCCTCAACTGTGACACCATCTCTCAGGTCAAAGAGAAGATCATCGACCAAGTGTACCGTACTCAGCCCTGCTCCTGCTGGCCCAAGCCAGACAGTGTGGTGCTTGAATGGCGTCCTGGGTCCACGGCCCAGATTCTGTCTGACTTGGACCTTACCTCCCAGCGGGAGGGCCGGTGGAAGCGCATCAACACCCTGATGCACTACAACGTCCGGGATGGAGCCACCCTCATCCTGTCTAAGGTGGGAGTCTCCCAGCAGCCAGAAGACAGCCAACAGGACTTGCCAGGGGAGCGCCATGCCCTTCTGGAAGAGGAAAACCGCGTGTGGCACTTGGTGCGGCCAACAGATGAGGTAGATGAAGGCAAGTCCAAGCGCGGCAGCATGAAGGAGAAAGAGCGGACTAAGGCCATCACAGAGATCTACCTGACGCGGCTACTCTCCGTCAAGGGCACACTGCAGCAGTTTGTGGACAACTTCTTCCAAAGCGTGCTGGCGCCTGGGCATGCGGTGCCACCCGCCGTCAAGTACTTCTTCGATTTCTTGGACGAGCAGGCAGAGAAGCATGACATCCGAGATGAGGATACCATCCATATCTGGAAAACCAACAGTTTACCACTTCGGTTCTGGGTGAACATCCTGAAGAACCCTCATTTCATCTTTGATGTCCACGTCCACGAAGTGGTGGACGCCTCCCTGTCAGTCATCGCACAGACCTTCATGGACGCCTGTACTCGCACGGAGCACAAGCTGAGCCGAGACTCTCCCAGCAACAAGCTGTTGTATGCTAAGGAGATCTCTACCTACAAGAAGATGGTGGAGGACTACTACAAGGGCATCAGACAGATGGTGCAGGTCAGCGACCAGGACATGAATACGCACTTGGCAGAGATTTCCCGGGCTCACACAGACTCCCTGAACACACTCGTGGCCCTACACCAGCTCTACCAATACACACAGAAGTACTATGATGAGATCATCAATGCTCTGGAGGAGGACCCTGCAGCCCAAAAGATGCAACTGGCCTTCCGCCTACAGCAGATTGCTGCTGCGCTTGAGAATAAGGTTACAGACCTCTGA
ORF Protein Sequence	MALPLWALTFLGLTGLGLSLRSRKPESFRSETELNHLAVDEVTGVVYVGAVNALYQLSADLHVQQHVVTGPFMDNKKCTPPIEASQCHEAVLTDNFNQLLLLDPPGKRLVECGSLFKGICALRAMSNISVRLFYEDGSGEKSFVASNDERVATVGLVTSTRPDGERVLFVGKGNGPHDNGIIVSTRLLDRAEGREAFEAYSDHTTFKAGYLSTNTQQFVAAFEDDFYVFFVFNHQDKHPAKNRTLLARMCKDDPSYYSYVEMDLQCQDPSDPQDSAFGTCLAASVATSGAGRALYAVFSRDGRSTGGPGAGLCVFPLDKVREKIEANRNACYTGAREAGRTIFYKPFHGEIQCGGHLIGASESFPCGSEHLPYPLGSRDGLVATAVLHRGGLNLTAVTVTAENDHTVAFLGTSDGRILKVYLAPDGTSAEYGSIPVDINKKIKQDLALSGNLSSLYAMTQDKVFRLPVQECLSYVTCAQCRDSQDPYCGWCVIEGRCTRKSECSRAEETGHWLWSREKSCVAITDAFPQNMSRRAQGEVRLSVSPLPTLTEDDELLCLFGDSPPHPARVEDDTVICNSPSSIPSTPPGQDHVDVSIQLLLKSGSVFLTSHQYPFYDCREAMSLVENLPCISCASNRWTCQWDLQYYECREASPNPEEGIIRAHMEDNCPQFLAPDPLVIPMNHETEVTFQGKNLETVKVSSLYVGSELLNFEETVTMHESDTFSFRTPKLSHDGNETLPLHLYVKSFGKNIDSKLQVTLYNCSFGRSDCSLCLAADPAYRCVWCRGQNRCVYEALCSNVTSECPPPVITRIQPETGPLGGGILVTIHGSNLGVKADDVKKITVAGQNCAFEPRGYSVSTRIVCAIEASEMPFTGGIEVDVNGKLGHSPPHVQFTYQQPQPLSVEPRQGPQAGGTTLTINGTHLDTGSKEDVRVTLNDVPCEVTKFGAQLQCVTGQQLAPGQVTLEIYYGGSRVPSPGISFTYCENPMIRAFEPLRSFVSGGRSINVTGQGFSLIQKFAMVVIAEPLRSWRRRRREAGALERVTVEGMEYVFYNDTKVVFLSPAVPEEPEAYNLTVLIRMDGHCAPLRTEAGVFEYVADPTFENFTGGVKKQVNKLIHARGTNLNKAMTLEEAEAFVGAERCIMKTLTETDLYCEPPEVQPPPKRRQKRDTAHNLPEFIVKFGSREWVLGRVEYDTRASDVPLSLILPLVMVPMVFIIVVSIYCYWRKSQQAEREYEKIKSQLEGLEESVRDRCKKEFTDLMIEMEDQTNDVHEAGIPTLDYKTYTDRVFFLPSKDGDKDVMITGKLDIPESRRPIVEQALYQFSNLLNSKSFLINFIHTLENQREFSARAKVYFASLLTVALHGKLEYYTDIMRTLFLELMEQYVVAKNPKLMLRRSETVVERMLSNWMSICLYQYLKDSAGEPLYKLFKAIKHQVEKGPVDAVQKKAKYTLNDTGLLGDDVEYAPLTVSVIVQDEGIDAIPVKVLNCDTISQVKEKIIDQVYRTQPCSCWPKPDSVVLEWRPGSTAQILSDLDLTSQREGRWKRINTLMHYNVRDGATLILSKVGVSQQPEDSQQDLPGERHALLEEENRVWHLVRPTDEVDEGKSKRGSMKEKERTKAITEIYLTRLLSVKGTLQQFVDNFFQSVLAPGHAVPPAVKYFFDFLDEQAEKHDIRDEDTIHIWKTNSLPLRFWVNILKNPHFIFDVHVHEVVDASLSVIAQTFMDACTRTEHKLSRDSPSNKLLYAKEISTYKKMVEDYYKGIRQMVQVSDQDMNTHLAEISRAHTDSLNTLVALHQLYQYTQKYYDEIINALEEDPAAQKMQLAFRLQQIAAALENKVTDL

Reference

Data / case study

Click to get more Data / Case study about the product.

About GMVC

GMVC (GM Vector Core) is GeneMedi’s unique platform for QbD Viral vectors Processes development and manufacturing. In GMVC, our core expertise lies in the tailored production of viral vectors, including adeno-associated virus (AAV), lentivirus, and adenovirus. Our state-of-the-art facilities are equipped for scalable manufacturing, ensuring high-quality viral vector production to meet both research and therapeutic needs. Our expert team specializes in process development, leveraging innovative technology and extensive industry knowledge to provide clients with tailored solutions that exceed expectations. GMVC will be the ideal partner for scientists and healthcare professionals seeking reliable and efficient viral vector production services.

GVector System - Mouse Plxnb2 Mammalian (Non-Viral Vector) plasmid pGMPC001565

TECHNICAL RESOURCE

Supports

Protocol Library Download

Mouse Plxnb2/Debt/plexin-B2 ORF/cDNA clone-Mammalian (Non-Viral Vector) plasmid (NM_001159521.2)

Product Description

Reference

Data / case study

About GMVC

About GeneMedi