Brilliant Violet 421™ anti-mouse I-A/I-E Antibody

Product Details

Verified Reactivity

Mouse

Antibody Type

Monoclonal

Host Species

Rat

Immunogen

Activated C57BL/6 mouse spleen cells

Formulation

µl size: Phosphate-buffered solution, pH 7.2, containing 0.09% sodium azide and BSA (origin USA).
µg size: Phosphate-buffered solution, pH 7.2, containing 0.09% sodium azide and BSA (origin USA).

Preparation

The antibody was purified by affinity chromatography and conjugated with Brilliant Violet 421™ under optimal conditions.

Concentration

µg sizes: 0.2 mg/mL
µL sizes: lot-specific (to obtain lot-specific concentration and expiration, please enter the lot number in our Certificate of Analysis online tool.)

Storage & Handling

The antibody solution should be stored undiluted between 2°C and 8°C, and protected from prolonged exposure to light. Do not freeze.

Application

FC - Quality tested
IHC-F - Verified

SB - Reported in the literature, not verified in house

Recommended Usage

Each lot of this antibody is quality control tested by immunofluorescent staining with flow cytometric analysis. For flow cytometric staining using the µl size, the suggested use of this reagent is 5 µl per million cells in 100 µl staining volume or 5 µl per 100 µl of whole blood. For flow cytometric staining using the µg size, the suggested use of this reagent is ≤ 0.25 µg per million cells in 100 µl volume. It is recommended that the reagent be titrated for optimal performance for each application.

Brilliant Violet 421™ excites at 405 nm and emits at 421 nm. The standard bandpass filter 450/50 nm is recommended for detection. Brilliant Violet 421™ is a trademark of Sirigen Group Ltd.

Learn more about Brilliant Violet™.

This product is subject to proprietary rights of Sirigen Inc. and is made and sold under license from Sirigen Inc. The purchase of this product conveys to the buyer a non-transferable right to use the purchased product for research purposes only. This product may not be resold or incorporated in any manner into another product for resale. Any use for therapeutics or diagnostics is strictly prohibited. This product is covered by U.S. Patent(s), pending patent applications and foreign equivalents.

Excitation Laser

Violet Laser (405 nm)

Application Notes

The M5/114.15.2 antibody reacts with a polymorphic determinant shared by the I-A^b, I-A^d, I-A^q, I-E^d, and I-E^k MHC class II alloantigens from mice carrying H-2^p,r,q,b,d,u haplotypes. Clone M5/114.15.2 however does not react wtih I-A^f, I-A^k, or I-A^s MHC class II alloantigens.¹

Additional reported applications (for the relevant formats) include: immunoprecipitation¹, immunohistochemistry of frozen sections^2,3,6, in vitro and in vivo blocking of antigen presentation or ligand binding^4-7, and spatial biology (IBEX)^17,18. The Ultra-LEAF™ purified antibody (Endotoxin < 0.01 EU/µg, Azide-Free, 0.2 µm filtered) is recommended for functional assays (Cat. Nos. 107655 & 107656).

Additional Product Notes

Iterative Bleaching Extended multi-pleXity (IBEX) is a fluorescent imaging technique capable of highly-multiplexed spatial analysis. The method relies on cyclical bleaching of panels of fluorescent antibodies in order to image and analyze many markers over multiple cycles of staining, imaging, and, bleaching. It is a community-developed open-access method developed by the Center for Advanced Tissue Imaging (CAT-I) in the National Institute of Allergy and Infectious Diseases (NIAID, NIH).

Application References

(PubMed link indicates BioLegend citation)

1. Bhattacharya A, et al. 1981. J. Immunol. 127:2488. (IP)
2. Viville S, et al. 1993. Cell 72:635. (IHC)
3. Nelson AJ, et al. 1993. J. Immunol. 151:2453. (IHC)
4. Shi Y, et al. 1998. J. Exp. Med. 187:367. (Block)
5. Yamashita I, et al. 1993. Int. Immunol. 5:1139.
6. Guo M, et al. 1995. Zygote 3:65. (IHC)
7. Kim A, et al. 2004. Exp. Mol. Med. 36:428. (Block)
8. Luckashenak NA, et al. 2006. J. Immunol. 177:5177.
9. Venanzi ES, et al. 2007. J. Immunol. 179:5693.
10. Christensen SR, et al. 2006. Immunity 25:417. PubMed
11. Matte-Martone C, et al. 2008. Blood 111:3884. PubMed
12. De Pascalis R, et al. 2008. Infect. Immun. 76:4311. PubMed
13. Kuns RD, et al. 2009. Blood 113:5999. PubMed
14. Sabatino JJ, et al. 2011. J. Exp. Med. 208:81. PubMed
15. Draber P, et al. 2011. Mol Cell Biol. 22:4550. PubMed
16. Fu H, et al. 2014. Nat Commun. 5:3436. PubMed
17. Radtke AJ, et al. 2020. Proc Natl Acad Sci U S A. 117:33455-65. (SB) PubMed
18. Radtke AJ, et al. 2022. Nat Protoc. 17:378-401. (SB) PubMed

Product Citations

1. Sagnella SM, et al. 2020. Cancer Cell. 37(3):354-370. PubMed
2. Zhao Z, et al. 2021. Nat Commun. 12:4355. PubMed
3. Hutton C, et al. 2021. Cancer Cell. 39:1227. PubMed
4. Friess MC, et al. 2022. Cell Rep. 38:110334. PubMed
5. Iwamoto H et al. 2018. Cell metabolism. 28(1):104-117 . PubMed
6. Song Q, et al. 2022. Front Immunol. 13:920232. PubMed
7. Postat J et al. 2018. Immunity. 49(4):654-665 . PubMed
8. Sepe JJ, et al. 2022. JACC Basic Transl Sci. 7:915. PubMed
9. Schmidleithner L et al. 2019. Immunity. 50(5):1232-1248 . PubMed
10. Potluri HK, et al. 2022. J Immunother Cancer. 10:. PubMed
11. Mariani SA, et al. 2019. Immunity. 50:1439. PubMed
12. Ostendorf BN, et al. 2020. Nat Med. 26:1048. PubMed
13. Perner C, et al. 2020. Immunity. 53(5):1063-1077.e7. PubMed
14. Voisin M, et al. 2021. Commun Biol. 4:420. PubMed
15. Wang F, et al. 2021. Cell Mol Gastroenterol Hepatol. 13:257. PubMed
16. Salei N, et al. 2020. J Am Soc Nephrol. 31:257. PubMed
17. Mehta AK, et al. 2021. Nat Cancer. 2:66. PubMed
18. Reed J, et al. 2020. Bio Protoc. 10:e3607. PubMed
19. Ferreira R, et al. 2016. J Infect Dis. 213: 669 - 673. PubMed
20. Tavazoie MF, et al. 2018. Cell. 172:825. PubMed
21. Roberts LM, et al. 2021. iScience. 24:103025. PubMed
22. Li Y, et al. 2021. Sci Transl Med. 13:. PubMed
23. Panea C, et al. 2021. Commun Biol. 4:913. PubMed
24. Wang Y, et al. 2020. Cell Death Dis. 1.169444444. PubMed
25. Lim CX, et al. 2020. Cell Rep. 3793:30. PubMed
26. Luo J et al. 2018. Immunity. 49(1):107-119 . PubMed
27. Grauel AL, et al. 2020. Nat Commun. 4.84375. PubMed
28. Zhang Q, et al. 2021. Front Cell Dev Biol. 9:655552. PubMed
29. Nair S, et al. 2021. JCI Insight. 6:. PubMed
30. Taylor D, et al. 2022. Front Immunol. 13:936129. PubMed
31. Wang YT, et al. 2020. Nat Microbiol. 0.397222222. PubMed
32. Alam Z, et al. 2020. Cell Rep. 107825:31. PubMed
33. Nabet BY et al. 2017. Cell. 170(2):352-366 . PubMed
34. Benci JL et al. 2019. Cell. 178(4):933-948 . PubMed
35. Nenasheva T, et al. 2017. PLoS One. 12(6):e0178983. PubMed
36. Matsuda T, et al. 2022. iScience. 25:105324. PubMed
37. Dong X, et al. 2022. Front Immunol. 13:896472. PubMed
38. Takahashi F, et al. 2022. iScience. 25:104278. PubMed
39. Barbet G, et al. 2018. Immunity. 48:584. PubMed
40. Lai SM et al. 2018. Cell reports. 25(11):3099-3109 . PubMed
41. Zhang Q, et al. 2022. Commun Biol. 5:544. PubMed
42. Dotsey E, et al. 2017. Sci Rep. 7:42584. PubMed
43. Xiao Y, et al. 2021. Cell. 184:6037. PubMed
44. Kiss M, et al. 2020. Cancer Immunol Res. 9:309. PubMed
45. Yu H, et al. 2021. Cell Death Dis. 13:1. PubMed
46. Pantelidou C, et al. 2022. NPJ Breast Cancer. 8:102. PubMed
47. Xu L, et al. 2022. Nat Commun. 13:6881. PubMed
48. Kunishita Y, et al. 2020. Front Immunol. 11:98. PubMed
49. Gu AQ, et al. 2019. J Cell Mol Med. 23(8):5403. PubMed
50. Liang Z, et al. 2017. Autophagy. 14:505. PubMed
51. Hirota K et al. 2018. Immunity. 48(6):1220-1232 . PubMed
52. Sheng J, et al. 2021. eLife. 10:00. PubMed
53. Mellal K, et al. 2019. Sci Rep. 9:12903. PubMed
54. Mincham KT, et al. 2021. Front Immunol. 11:601494. PubMed
55. Luo ZW, et al. 2021. Int J Nanomedicine. 16:2949. PubMed
56. Spiljar M, et al. 2021. Cell Metab. 33:2231. PubMed
57. Liang Z, et al. 2022. iScience. 25:105233. PubMed
58. Lal JC, et al. 2021. Breast Cancer Res. 23:83. PubMed
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RRID

AB_10900075 (BioLegend Cat. No. 107631)
AB_2650896 (BioLegend Cat. No. 107632)

Antigen Details

Structure

MHC class II

Distribution

B cell and activated T cells, APCs of the H-2^b,d,q,r bearing mice

Function

Antigen presentation

Ligand/Receptor

CD3/TCR, CD4

Cell Type

Antigen-presenting cells, B cells, Dendritic cells, T cells, Tregs

Biology Area

Immunology, Innate Immunity

Molecular Family

MHC Antigens

Antigen References

1. Watts C. 1997. Ann. Rev. Immunol. 15:821.
2. Pamer E, et al. 1998. Ann. Rev. Immunol. 16:323.

Gene ID

14961 View all products for this Gene ID 14969 View all products for this Gene ID

UniProt

View information about I-A/I-E on UniProt.org

Documentation

• Technical Data Sheet (pdf)
• Certificate of Analysis
• Safety Data Sheet

Reviews

Related Protocols

• Cell Surface Flow Cytometry Staining Protocol

Related Pages & Pathways

Related FAQs

What is the F/P ratio range of our BV421™ format antibody reagents?

It is lot-specific. On average it ranges between 2-4.

If an antibody clone has been previously successfully used in IBEX in one fluorescent format, will other antibody formats work as well?

It’s likely that other fluorophore conjugates to the same antibody clone will also be compatible with IBEX using the same sample fixation procedure. Ultimately a directly conjugated antibody’s utility in fluorescent imaging and IBEX may be specific to the sample and microscope being used in the experiment. Some antibody clone conjugates may perform better than others due to performance differences in non-specific binding, fluorophore brightness, and other biochemical properties unique to that conjugate.

Will antibodies my lab is already using for fluorescent or chromogenic IHC work in IBEX?

Fundamentally, IBEX as a technique that works much in the same way as single antibody panels or single marker IF/IHC. If you’re already successfully using an antibody clone on a sample of interest, it is likely that clone will have utility in IBEX. It is expected some optimization and testing of different antibody fluorophore conjugates will be required to find a suitable format; however, legacy microscopy techniques like chromogenic IHC on fixed or frozen tissue is an excellent place to start looking for useful antibodies.

Are other fluorophores compatible with IBEX?

Over 18 fluorescent formats have been screened for use in IBEX, however, it is likely that other fluorophores are able to be rapidly bleached in IBEX. If a fluorophore format is already suitable for your imaging platform it can be tested for compatibility in IBEX.

The same antibody works in one tissue type but not another. What is happening?

Differences in tissue properties may impact both the ability of an antibody to bind its target specifically and impact the ability of a specific fluorophore conjugate to overcome the background fluorescent signal in a given tissue. Secondary stains, as well as testing multiple fluorescent conjugates of the same clone, may help to troubleshoot challenging targets or tissues. Using a reference control tissue may also give confidence in the specificity of your staining.

How can I be sure the staining I’m seeing in my tissue is real?

In general, best practices for validating an antibody in traditional chromogenic or fluorescent IHC are applicable to IBEX. Please reference the Nature Methods review on antibody based multiplexed imaging for resources on validating antibodies for IBEX.

Other Formats

Certificate of Analysis