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EHU091461

Sigma-Aldrich

MISSION® esiRNA

targeting human XRCC4

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About This Item

UNSPSC Code:
41105324
NACRES:
NA.51

description

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product line

MISSION®

form

lyophilized powder

esiRNA cDNA target sequence

TCAGACTTGGTTCCTTCAACCTAGAGAAAGTTGAAAACCCAGCTGAAGTCATTAGAGAACTTATTTGTTATTGCTTGGACACCATTGCAGAAAATCAAGCCAAAAATGAGCACCTGCAGAAAGAAAATGAAAGGCTTCTGAGAGATTGGAATGATGTTCAAGGACGATTTGAAAAATGTGTGAGTGCTAAGGAAGCTTTGGAGACTGATCTTTATAAGCGGTTTATTCTGGTGTTGAATGAGAAGAAAACAAAAATCAGAAGTTTGCATAATAAATTATTAAATGCAGCTCAAGAACGAGAAAAGGACATCAAACAAGAAGGGGAAACTGCAATCTGTTCTGAAATGACTGCTGACCGAGATCCAGTCTATGATGAGAGTACTGATGAGGAAAGTGAAAACCAAACTGATCTCTCTGGGTTGGCTT

Ensembl | human accession no.

NCBI accession no.

shipped in

ambient

storage temp.

−20°C

Gene Information

General description

MISSION esiRNA are endoribonuclease prepared siRNA. They are a heterogeneous mixture of siRNA that all target the same mRNA sequence. These multiple silencing triggers lead to highly-specific and effective gene silencing.

For additional details as well as to view all available esiRNA options, please visit SigmaAldrich.com/esiRNA.

Legal Information

MISSION is a registered trademark of Merck KGaA, Darmstadt, Germany

Storage Class Code

10 - Combustible liquids

Flash Point(F)

Not applicable

Flash Point(C)

Not applicable


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Wen Li et al.
Nature cell biology, 21(10), 1273-1285 (2019-09-25)
Chromosome translocation is a major cause of the onset and progression of diverse types of cancers. However, the mechanisms underlying this process remain poorly understood. Here, we identified a non-homologous end-joining protein, IFFO1, which structurally forms a heterotetramer with XRCC4.
Idit Hazan et al.
Cell reports, 29(3), 560-572 (2019-10-17)
DNA double-strand breaks (DSBs) are deleterious and tumorigenic but could also be essential for DNA-based processes. Yet the landscape of physiological DSBs and their role and repair are still elusive. Here, we mapped DSBs at high resolution in cancer and
Masahiro Terasawa et al.
PLoS genetics, 10(8), e1004563-e1004563 (2014-08-29)
DNA double-strand breaks (DSBs) can be repaired by one of two major pathways-non-homologous end-joining (NHEJ) and homologous recombination (HR)-depending on whether cells are in G1 or S/G2 phase, respectively. However, the mechanisms of DSB repair during M phase remain largely

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