AdmiRa-hsa-let-7a-2-3p-Off Virus

Cat. No.

mh5003

Unit

1.0 ml

Price

$245.00

Lead Time

Around 11 weeks

Custom Option

Cat. No.	mh5003
Name	AdmiRa-hsa-let-7a-2-3p-Off Virus
Unit	1.0 ml
Description	This miRNA inhibitor adenovirus is part of abm’s Adenoviral Expression System and can be used directly to transiently inhibit your miRNA of interest in a wide range of host cells. This adenovirus can be used to amplify more adenovirus by transducing HEK293 cells. For enhanced transduction efficiency, the use of ViralPlus (G698) at 1:100 is recommended at the time of transduction.
miRNA Name	hsa-let-7a-2-3p
Accession Number	MIMAT0010195
Species	Human (H. sapiens)
Vector Map	pAdeno-miR-Off (click blue link to view)
miRNA ID	MIMAT0010195
System	Adenovirus
Storage Condition	High titer adenoviruses are shipped with dry ice and low titer adenoviruses are shipped with ice packs. For long term storage, it is recommended to store the viruses at -80°C in small aliquots to avoid repeated freeze-thaw cycles.

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Supporting Protocol

Other

	Is it ready for use?
	Yes, it is ready to use. Just load suggested volume (5ul) to the well.

	What is the smallest size agarose gel can separate?
	That is around 300bp for 1% agarose and 100bp for 2.5% agarose. With anything smaller than the dye, there may be separation but it will be difficult to tell when the fragment will run off the gel.

What is the difference between Retro-, Lenti-, and Adeno- viruses?

Retrovirus: Classic, can integrate into the genome but with low transduction efficiency. They are useful for gene transfer and protein expression in cells that have low transfection efficiency with other transfection reagents. Lentivirus: Can integrate into the genome with relatively high transduction efficiency and they are very useful for cells that have low transfection efficiency with other transfection reagents. No special competent cells required, as they are stable plasmids. Lentiviruses are a powerful tool for stable gene transfer to both dividing and non-dividing cells in vitro and in vivo. Adenovirus: Only work transiently (about 7 days) but have almost 100% transduction efficiency. Adenoviruses can infect a broad range of cell types with the highest efficiency and infection is not dependent on active host cell division. A second key feature is that high virus titers and high-level gene expression can be obtained in most mammalian cells.

What are the correct concentration units for each recombinant viral particle?

For lentiviruses and retroviruses, they are measured in CFU/ml (colony-forming units per millilitre). Transduction with lentiviruses and retroviruses can cause the formation of colonies, which can be quantified for concentration. For AAV the titer is measured as genome copies per mL (GC/mL). Adenoviruses are measured as PFU/ml (plaque-forming units per millilitre). Transduction with adenoviruses will kill packaging cells, forming plaques in the process for quantification. The concentration for all three types of viruses can also be classified as IU/ml (Infectious Units/ml). Ultimately, the units refers to the viral particles and different units reflect the different assays involved.

	What do I use to check if my cells were successfully immortalized by the SV40 agent?
	We have an SV40 T antibody that can be used for the western blot analysis. The catalog number is G202. Otherwise, a qPCR primer can be designed on the SV40 gene for qPCR analysis. The sequence can be found in the link below: http://www.abmgood.com/pLenti%20SV40-Vector-Location-Map.html

	What are the primers to use for SV40 identification?
	SV40 Forward Primer Sequence 5’ ACTGAGGGGCCTGAAATGA SV40 Reverse Primer Sequence 5’ GACTCAGGGCATGAAACAGG These are qPCR primers and the band size is 61 bp.

What advantages / disadvantages exist between the Lenti-SV40, -SV40T, and SV40T+t vectors?

There are simply differences in the content of all vectors due to customer demand for variety. Lenti-SV40 will contain the whole SV40 gene, -SV40T, the large T Antigen only, and -SV40T&t the large and small T antigens only. It is up to the end user to decide which vectors will best suit their project, however we have successfully used Lenti-SV40 (whole gene) in a wide range of immortalization projects.

	Are the Opti-DNA markers compatible with radiolabelling?
	Our lab has not tested the Opti-DNA markers for this particular application, but we believe it shouldn't be a problem. The Opti-DNA markers should be compatible for radio-labelling.

	What is the accession number for the SV40?
	The SV40 covers the entire genome and the accession number is J02400.1. You can use this information to design primers for conventional PCR as well.

	Is it possible to use frozen blood sample with this kit?
	Frozen blood samples have not yet been tested with this kit, however this should not be a problem.

	What is the TE buffer used for?
	The TE buffer is optional and is included because some prefer to use TE for elution. TE buffer can be used instead of elution buffer if needed.

	How long after transduction can the infection efficiency be observed?
	You can observe transduction efficiency from 48 hours up to 5 days after infection.

	What are the primers to use for SV40T and SV40T tsA58 detection?
	PCR primers: SV40T Forward Primer Sequence 5’ AGCCTGTAGAACCAAACATT 3' SV40T Reverse Primer Sequence 5’ CTGCTGACTCTCAACATTCT 3' The two primers should amplify the region between 3677-4468bp, giving a 792bp fragment.

	What is the sequence of the SV40 large T antigen?
	This information can be accessed on this page by clicking on "pLenti-SV40-T" under vector map. The Large T antigen is at position 5079-5927.

	For G221 and LV620, what does the 'V12' in RasV12 mean?
	The V12 means that amino acid # 12 is mutated from a Valine to a Glycine. Other than that, the sequence matches the coding region of HRAS perfectly (NM_005343).

	Where is the SV40T tsA58 gene sequence?
	The SV40T tsA58 gene is located between 3138-5264bp, with the Alanine-to-Valine mutation at amino acid 438.

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Panchapakesan SSS, Ferguson ML, Hayden EJ, Chen X, Hoskins AA, Unrau PJ. et al. "Ribonucleoprotein purification and characterization using RNA Mango." RNA. 2017 Oct;23(10):1592-1599. DOI: 10.1261/rna.062166.117.
Trachman RJ 3rd, Demeshkina NA, Lau MWL, Panchapakesan SSS, Jeng SCY, Unrau PJ, Ferré-D'Amaré AR. et al. "Structural basis for high-affinity fluorophore binding and activation by RNA Mango." Nat Chem Biol. 2017 Jul;13(7):807-813. DOI: 10.1038/nchembio.2392.
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