Human SASH1/CAPOK/dJ323M4.1 ORF/cDNA clone-Adenovirus particle (NM_015278.5)

Cat. No.: vGMAD000895

Pre-made Human SASH1/CAPOK/dJ323M4.1 Adenovirus for SASH1 overexpression in-vitro and in-vivo. The SASH1 adenoviral vector excels as a vehicle for transient gene transfection in both stable cell lines and primary cells, including DC cells, macrophages, cardiomyocytes, hepatocytes, and neurons. The purified SASH1-encoding adenovirus also stands out as a quintessential tool for in vivo studies and vaccine research initiatives.

At GM Vector Core (GMVC), we provide bespoke adenovirus development and manufacture various grades of adenoviruses utilizing cutting-edge techniques. Dive deeper into our offerings.

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Product information

Catalog No. Product Name Adenovirus Grade Adenovirus quantity
vGMAD000895 Human SASH1 Adenovirus particle Research Grade-In vitro 1E+10PFU (1E+10pfu/ml×1ml)
5E+10PFU (1E+10pfu/ml×5ml)
1E+11PFU (1E+10pfu/ml×10ml)
Research Grade-In vivo 1E+11PFU (1E+11pfu/ml×1ml)
GMP-like Grade inquiry
GMP Grade inquiry


Product Description

Catalog ID vGMAD000895
Gene Name SASH1
Accession Number NM_015278.5
Gene ID 23328
Species Human
Product Type Adenovirus particle (overexpression)
Insert Length 3744 bp
Gene Alias CAPOK,dJ323M4.1,DUH1,SH3D6A
Fluorescent Reporter EGFP
Mammalian Cell Selection Null
Fusion Tag HA (C-Terminal)
Promoter EF1
Resistance Kanamycin
ORF Nucleotide Sequence ATGGAGGACGCGGGAGCAGCTGGCCCGGGGCCGGAGCCTGAGCCCGAGCCCGAGCCGGAGCCCGAGCCCGCGCCGGAGCCGGAACCGGAGCCCAAGCCGGGTGCTGGCACATCCGAGGCGTTCTCCCGACTCTGGACCGACGTGATGGGTATCCTGGACGGTTCACTGGGAAACATCGATGACCTGGCGCAGCAGTATGCAGATTATTACAACACCTGTTTCTCCGACGTGTGCGAGAGGATGGAGGAGCTGCGGAAACGGCGGGTTTCCCAGGACCTGGAAGTGGAGAAACCCGATGCTAGCCCCACGTCACTTCAGCTGCGGTCCCAGATCGAAGAGTCGCTTGGCTTCTGTAGCGCCGTGTCAACCCCAGAAGTGGAAAGAAAGAACCCTCTTCATAAATCAAACTCAGAAGACAGCTCTGTAGGAAAAGGAGACTGGAAGAAGAAAAATAAGTATTTCTGGCAGAACTTCCGAAAGAACCAGAAAGGAATAATGAGACAGACTTCAAAAGGAGAAGACGTTGGTTATGTTGCCAGTGAAATAACGATGAGCGATGAGGAGCGGATTCAGCTAATGATGATGGTCAAAGAAAAGATGATCACAATTGAGGAAGCACTTGCTAGGCTCAAGGAATACGAGGCCCAGCACCGGCAGTCGGCTGCCCTGGACCCTGCTGACTGGCCAGATGGTTCTTACCCAACGTTTGATGGCTCATCAAACTGCAATTCAAGAGAACAATCGGATGATGAGACTGAGGAGTCGGTGAAGTTTAAGAGGTTACACAAGCTGGTAAACTCCACTCGCAGAGTCAGAAAGAAACTAATTAGGGTGGAAGAAATGAAAAAACCCAGCACTGAAGGTGGGGAGGAGCACGTGTTTGAGAATTCGCCGGTCCTGGATGAACGGTCCGCCCTCTACTCTGGCGTGCACAAGAAGCCCCTTTTCTTTGATGGCTCTCCTGAGAAACCTCCCGAAGATGACTCAGACTCTCTCACCACGTCTCCATCCTCCAGCAGCCTGGACACCTGGGGGGCTGGCCGGAAGTTGGTCAAAACCTTCAGCAAAGGAGAGAGCCGGGGCCTGATTAAGCCCCCCAAGAAGATGGGGACATTCTTCTCCTACCCAGAAGAAGAAAAGGCCCAGAAAGTGTCCCGCTCCCTCACCGAGGGGGAGATGAAGAAGGGTCTCGGGTCCCTAAGCCACGGGAGAACCTGCAGTTTTGGAGGATTTGACTTGACGAATCGCTCTCTGCACGTTGGCAGTAATAATTCTGACCCAATGGGTAAAGAAGGAGACTTTGTGTACAAAGAAGTCATCAAATCACCTACTGCCTCTCGCATCTCTCTTGGGAAAAAGGTGAAATCAGTGAAAGAGACGATGAGAAAGAGAATGTCTAAAAAATACAGCAGCTCTGTCTCTGAGCAGGACTCGGGCCTTGATGGAATGCCTGGCTCCCCTCCGCCTTCACAGCCCGACCCCGAACACTTGGACAAGCCCAAGCTCAAGGCCGGGGGTTCTGTAGAAAGTCTTCGCAGTTCTCTCAGTGGGCAGAGCTCCATGAGCGGTCAAACAGTGAGCACCACTGATTCCTCAACCAGCAACCGGGAAAGCGTCAAGTCGGAAGATGGGGATGACGAAGAGCCGCCTTACCGAGGCCCGTTCTGCGGGCGTGCCAGGGTGCACACCGACTTCACCCCCAGTCCCTATGACACAGACTCACTCAAGCTCAAGAAAGGAGATATCATCGATATAATCAGCAAGCCACCCATGGGGACCTGGATGGGCCTGCTGAACAACAAAGTCGGCACGTTCAAGTTCATCTACGTGGACGTGCTCAGTGAAGACGAGGAGAAACCCAAACGCCCCACCAGGAGGCGTCGGAAAGGACGACCACCCCAGCCCAAGTCTGTGGAGGATCTCCTGGATCGGATTAACCTAAAAGAGCACATGCCCACTTTCCTGTTCAATGGATATGAAGATTTGGACACCTTTAAGCTGCTGGAGGAGGAAGACTTGGATGAGTTAAATATCAGGGACCCGGAACACAGAGCTGTTCTCTTGACAGCAGTGGAGCTGTTACAAGAGTATGACAGTAACAGCGACCAGTCAGGATCCCAGGAGAAGCTGCTCGTTGACAGCCAGGGCCTGAGTGGATGCTCACCCCGAGACTCAGGATGCTACGAAAGCAGTGAGAACCTGGAAAACGGCAAGACTCGGAAAGCTAGCCTCCTATCTGCCAAGTCATCCACCGAGCCCAGCTTGAAGTCTTTTAGCAGAAACCAGTTGGGCAATTACCCAACATTGCCTTTAATGAAATCAGGGGATGCACTGAAGCAGGGACAGGAGGAGGGCAGGCTGGGTGGTGGCCTTGCCCCAGACACGTCCAAGAGCTGTGACCCACCTGGTGTGACTGGTTTGAATAAAAACCGAAGAAGCCTCCCAGTTTCCATCTGCCGGAGCTGTGAGACCCTGGAGGGCCCCCAGACTGTGGACACTTGGCCCCGATCCCATTCCCTGGATGACCTTCAAGTGGAGCCTGGTGCTGAGCAAGACGTGCCTACCGAGGTGACAGAACCGCCCCCTCAGATTGTACCTGAAGTGCCACAGAAGACGACCGCCTCTTCCACGAAGGCCCAGCCCCTGGAGCAAGACTCTGCTGTCGACAATGCATTGCTACTGACCCAAAGCAAGAGATTTTCTGAACCTCAGAAATTGACAACTAAGAAACTGGAGGGCTCAATCGCAGCCTCTGGTCGCGGCCTGTCACCCCCTCAGTGTTTGCCCAGAAACTATGATGCTCAGCCTCCTGGAGCTAAACACGGTTTAGCAAGGACGCCTCTGGAGGGCCACAGAAAAGGACACGAGTTTGAAGGAACACACCATCCCCTGGGCACCAAAGAAGGGGTAGATGCTGAGCAGAGAATGCAGCCCAAAATTCCATCACAGCCTCCACCTGTTCCTGCCAAAAAGAGCAGAGAACGCCTTGCTAACGGACTCCACCCTGTTCCCATGGGCCCCAGTGGGGCCCTCCCCAGTCCCGATGCGCCATGCCTGCCAGTGAAAAGGGGCAGCCCCGCCAGCCCCACCAGCCCTAGCGACTGTCCCCCAGCACTGGCTCCCAGGCCTCTCTCAGGGCAGGCGCCTGGCAGCCCACCAAGCACAAGGCCGCCCCCCTGGCTCTCAGAGCTCCCCGAGAACACAAGCCTCCAGGAGCACGGTGTGAAGCTGGGCCCGGCTTTGACCAGGAAGGTCTCCTGTGCCCGGGGAGTGGATCTAGAAACGCTCACTGAAAACAAGCTGCACGCTGAAGGCATCGATCTCACGGAGGAGCCGTATTCTGATAAGCATGGCCGCTGTGGGATTCCTGAAGCCCTGGTGCAGAGATACGCAGAGGACTTGGATCAGCCCGAGCGGGACGTCGCCGCCAACATGGACCAGATCCGGGTGAAGCAGCTTCGGAAGCAGCACCGCATGGCGATTCCAAGTGGTGGACTCACGGAAATCTGCCGAAAGCCCGTCTCTCCTGGGTGCATTTCGTCTGTGTCAGATTGGCTCATTTCCATCGGTCTGCCCATGTACGCCGGCACCCTCTCCACCGCGGGCTTCAGCACACTGAGCCAAGTGCCTTCTCTGTCTCACACTTGCCTTCAGGAGGCCGGCATCACAGAGGAGAGACACATAAGAAAGCTCCTATCTGCAGCCAGACTCTTCAAACTGCCGCCAGGCCCTGAGGCCATGTAG
ORF Protein Sequence MEDAGAAGPGPEPEPEPEPEPEPAPEPEPEPKPGAGTSEAFSRLWTDVMGILDGSLGNIDDLAQQYADYYNTCFSDVCERMEELRKRRVSQDLEVEKPDASPTSLQLRSQIEESLGFCSAVSTPEVERKNPLHKSNSEDSSVGKGDWKKKNKYFWQNFRKNQKGIMRQTSKGEDVGYVASEITMSDEERIQLMMMVKEKMITIEEALARLKEYEAQHRQSAALDPADWPDGSYPTFDGSSNCNSREQSDDETEESVKFKRLHKLVNSTRRVRKKLIRVEEMKKPSTEGGEEHVFENSPVLDERSALYSGVHKKPLFFDGSPEKPPEDDSDSLTTSPSSSSLDTWGAGRKLVKTFSKGESRGLIKPPKKMGTFFSYPEEEKAQKVSRSLTEGEMKKGLGSLSHGRTCSFGGFDLTNRSLHVGSNNSDPMGKEGDFVYKEVIKSPTASRISLGKKVKSVKETMRKRMSKKYSSSVSEQDSGLDGMPGSPPPSQPDPEHLDKPKLKAGGSVESLRSSLSGQSSMSGQTVSTTDSSTSNRESVKSEDGDDEEPPYRGPFCGRARVHTDFTPSPYDTDSLKLKKGDIIDIISKPPMGTWMGLLNNKVGTFKFIYVDVLSEDEEKPKRPTRRRRKGRPPQPKSVEDLLDRINLKEHMPTFLFNGYEDLDTFKLLEEEDLDELNIRDPEHRAVLLTAVELLQEYDSNSDQSGSQEKLLVDSQGLSGCSPRDSGCYESSENLENGKTRKASLLSAKSSTEPSLKSFSRNQLGNYPTLPLMKSGDALKQGQEEGRLGGGLAPDTSKSCDPPGVTGLNKNRRSLPVSICRSCETLEGPQTVDTWPRSHSLDDLQVEPGAEQDVPTEVTEPPPQIVPEVPQKTTASSTKAQPLEQDSAVDNALLLTQSKRFSEPQKLTTKKLEGSIAASGRGLSPPQCLPRNYDAQPPGAKHGLARTPLEGHRKGHEFEGTHHPLGTKEGVDAEQRMQPKIPSQPPPVPAKKSRERLANGLHPVPMGPSGALPSPDAPCLPVKRGSPASPTSPSDCPPALAPRPLSGQAPGSPPSTRPPPWLSELPENTSLQEHGVKLGPALTRKVSCARGVDLETLTENKLHAEGIDLTEEPYSDKHGRCGIPEALVQRYAEDLDQPERDVAANMDQIRVKQLRKQHRMAIPSGGLTEICRKPVSPGCISSVSDWLISIGLPMYAGTLSTAGFSTLSQVPSLSHTCLQEAGITEERHIRKLLSAARLFKLPPGPEAM

Reference




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    Associated products


    Category Cat No. Products Name
    ORF Viral Vector pGMAD000895 Human SASH1 Adenovirus plasmid




    About GMVC

    GDU

    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.