This is a Validated Antibody Database (VAD) review about mouse Klrg1, based on 89 published articles (read how Labome selects the articles), using Klrg1 antibody in all methods. It is aimed to help Labome visitors find the most suited Klrg1 antibody. Please note the number of articles fluctuates since newly identified citations are added and citations for discontinued catalog numbers are removed regularly.
Klrg1 synonym: 2F1-Ag; MAFA; MAFA-L

Invitrogen
Syrian golden hamster monoclonal (2F1)
  • flow cytometry; mouse; loading ...; fig s2a
Invitrogen Klrg1 antibody (eBioscience, 2F1) was used in flow cytometry on mouse samples (fig s2a). elife (2020) ncbi
Syrian golden hamster monoclonal (2F1)
  • flow cytometry; mouse; fig s5a
Invitrogen Klrg1 antibody (eBioscience, 2F1) was used in flow cytometry on mouse samples (fig s5a). Nature (2019) ncbi
Syrian golden hamster monoclonal (2F1)
  • flow cytometry; mouse; 1:800; loading ...; fig 3a, s4d
Invitrogen Klrg1 antibody (Thermo Fisher, 2F1) was used in flow cytometry on mouse samples at 1:800 (fig 3a, s4d). Cell Rep (2019) ncbi
Syrian golden hamster monoclonal (2F1)
  • flow cytometry; mouse; loading ...; fig 2f
Invitrogen Klrg1 antibody (eBioscience, 2F1) was used in flow cytometry on mouse samples (fig 2f). Science (2019) ncbi
Syrian golden hamster monoclonal (2F1)
  • mass cytometry; mouse; loading ...; fig 3e
Invitrogen Klrg1 antibody (Thermo Fisher, 16-5893-82) was used in mass cytometry on mouse samples (fig 3e). Cell (2019) ncbi
Syrian golden hamster monoclonal (2F1)
  • flow cytometry; mouse; loading ...; fig e1b
Invitrogen Klrg1 antibody (eBioscience, 2F1) was used in flow cytometry on mouse samples (fig e1b). Nature (2019) ncbi
Syrian golden hamster monoclonal (2F1)
  • flow cytometry; mouse; loading ...; fig 3a
Invitrogen Klrg1 antibody (eBioscience, 2F1) was used in flow cytometry on mouse samples (fig 3a). Front Immunol (2018) ncbi
Syrian golden hamster monoclonal (2F1)
  • flow cytometry; mouse; loading ...; fig 4h
Invitrogen Klrg1 antibody (Thermo Fisher Scientific, 2F1) was used in flow cytometry on mouse samples (fig 4h). Eur J Immunol (2018) ncbi
Syrian golden hamster monoclonal (2F1)
  • flow cytometry; mouse; 1:100; loading ...; fig 2a
Invitrogen Klrg1 antibody (eBioscience, 2F1) was used in flow cytometry on mouse samples at 1:100 (fig 2a). Infect Immun (2018) ncbi
Syrian golden hamster monoclonal (2F1)
  • flow cytometry; mouse; loading ...; fig 1g
Invitrogen Klrg1 antibody (eBioscience, 2F1) was used in flow cytometry on mouse samples (fig 1g). Front Immunol (2018) ncbi
Syrian golden hamster monoclonal (2F1)
  • flow cytometry; mouse; loading ...; fig 4e
Invitrogen Klrg1 antibody (eBioscience, 2F1) was used in flow cytometry on mouse samples (fig 4e). J Clin Invest (2018) ncbi
Syrian golden hamster monoclonal (2F1)
  • flow cytometry; mouse; loading ...; fig 1b
Invitrogen Klrg1 antibody (eBioscience, 2F1) was used in flow cytometry on mouse samples (fig 1b). J Exp Med (2018) ncbi
Syrian golden hamster monoclonal (2F1)
  • flow cytometry; mouse; fig 1h
Invitrogen Klrg1 antibody (eBiosciences, 46-5893-80) was used in flow cytometry on mouse samples (fig 1h). Cell (2018) ncbi
Syrian golden hamster monoclonal (2F1)
  • flow cytometry; mouse; loading ...; fig 1d
Invitrogen Klrg1 antibody (eBioscience, 2F1) was used in flow cytometry on mouse samples (fig 1d). Science (2018) ncbi
Syrian golden hamster monoclonal (2F1)
  • flow cytometry; mouse; fig s6b
In order to investigate the effect of polymicrobial sepsis in skin immune response, Invitrogen Klrg1 antibody (eBioscience, 2F1) was used in flow cytometry on mouse samples (fig s6b). PLoS Pathog (2017) ncbi
Syrian golden hamster monoclonal (2F1)
  • immunohistochemistry; mouse; loading ...; fig s6a
Invitrogen Klrg1 antibody (eBioscience, 2F1) was used in immunohistochemistry on mouse samples (fig s6a). Nature (2017) ncbi
Syrian golden hamster monoclonal (2F1)
  • immunohistochemistry - frozen section; mouse; loading ...; fig 1c
  • flow cytometry; mouse; loading ...; fig 1a
Invitrogen Klrg1 antibody (eBioscience, 2F1) was used in immunohistochemistry - frozen section on mouse samples (fig 1c) and in flow cytometry on mouse samples (fig 1a). Immunology (2017) ncbi
Syrian golden hamster monoclonal (2F1)
  • flow cytometry; mouse; loading ...; fig 1c
Invitrogen Klrg1 antibody (eBioscience, 2F1) was used in flow cytometry on mouse samples (fig 1c). Immunology (2017) ncbi
Syrian golden hamster monoclonal (2F1)
  • flow cytometry; mouse; loading ...; fig 1,3
In order to elucidate the interaction between tumor-associated and -infiltrating lymphocytes in ovarian cancer, Invitrogen Klrg1 antibody (eBioscience, 11-5893-82) was used in flow cytometry on mouse samples (fig 1,3). Oncoimmunology (2017) ncbi
Syrian golden hamster monoclonal (2F1)
  • flow cytometry; mouse; fig 6c
In order to investigate the mechanisms by which eomesodermin regulates memory fitness in T cells, Invitrogen Klrg1 antibody (eBioscience, 2F1) was used in flow cytometry on mouse samples (fig 6c). Proc Natl Acad Sci U S A (2017) ncbi
Syrian golden hamster monoclonal (2F1)
  • flow cytometry; mouse; 1:100; loading ...; fig s1a
In order to find an alternative pathway of NK-cell development driven by IL-12, Invitrogen Klrg1 antibody (eBioscience, 2F1) was used in flow cytometry on mouse samples at 1:100 (fig s1a). Nat Commun (2016) ncbi
Syrian golden hamster monoclonal (2F1)
  • flow cytometry; mouse; loading ...; fig 6f
In order to investigate the contribution of TGF-beta to the eomesodermin-driven CD4 T cell program during viral infection, Invitrogen Klrg1 antibody (eBioscience, 2F1) was used in flow cytometry on mouse samples (fig 6f). J Clin Invest (2016) ncbi
Syrian golden hamster monoclonal (2F1)
  • flow cytometry; mouse; fig 7
Invitrogen Klrg1 antibody (eBioscience, 2F1) was used in flow cytometry on mouse samples (fig 7). PLoS ONE (2016) ncbi
Syrian golden hamster monoclonal (2F1)
  • flow cytometry; mouse; loading ...; fig 4d
In order to demonstrate that DNMT3a directs early CD8 positive T-cell effector and memory fate decisions, Invitrogen Klrg1 antibody (eBioscience, 2F1) was used in flow cytometry on mouse samples (fig 4d). Proc Natl Acad Sci U S A (2016) ncbi
Syrian golden hamster monoclonal (2F1)
  • flow cytometry; mouse; loading ...; fig 2
In order to determine the function of the SLAM family of proteins in natural killer cells, Invitrogen Klrg1 antibody (eBioscience, 2F1) was used in flow cytometry on mouse samples (fig 2). J Exp Med (2016) ncbi
Syrian golden hamster monoclonal (2F1)
  • flow cytometry; mouse; loading ...; fig 10c
Invitrogen Klrg1 antibody (eBiosciences, 2F1) was used in flow cytometry on mouse samples (fig 10c). J Exp Med (2016) ncbi
Syrian golden hamster monoclonal (2F1)
  • flow cytometry; mouse; loading ...; fig 2a
In order to investigate the mechanism for adoptively transferred effector T-cell survival and memory formation, Invitrogen Klrg1 antibody (eBioscience, 2F1) was used in flow cytometry on mouse samples (fig 2a). Cell Biosci (2016) ncbi
Syrian golden hamster monoclonal (2F1)
  • flow cytometry; mouse; loading ...; fig 4a
In order to discover cell-intrinsic division and differentiation differences in neonatal CD8+ T cells, Invitrogen Klrg1 antibody (eBiosciences, 46-5893-82) was used in flow cytometry on mouse samples (fig 4a). Immunol Cell Biol (2016) ncbi
Syrian golden hamster monoclonal (2F1)
  • flow cytometry; mouse; fig 2
In order to establish that autophagy is essential for maintenance of a balanced CD4 positive intestinal T cell response, Invitrogen Klrg1 antibody (eBioscience, 2F1) was used in flow cytometry on mouse samples (fig 2). elife (2016) ncbi
Syrian golden hamster monoclonal (2F1)
  • flow cytometry; mouse; fig 1
Invitrogen Klrg1 antibody (eBioscience, 2F1) was used in flow cytometry on mouse samples (fig 1). Mucosal Immunol (2016) ncbi
Syrian golden hamster monoclonal (2F1)
  • flow cytometry; mouse; 1:200
In order to assess the role of NLRC5 to NK-T-cell crosstalk, Invitrogen Klrg1 antibody (eBioscience, 2F1) was used in flow cytometry on mouse samples at 1:200. Nat Commun (2016) ncbi
Syrian golden hamster monoclonal (2F1)
  • flow cytometry; mouse; fig 2
Invitrogen Klrg1 antibody (eBioscience, 2F1) was used in flow cytometry on mouse samples (fig 2). J Immunol (2016) ncbi
Syrian golden hamster monoclonal (2F1)
  • flow cytometry; mouse; fig 2
Invitrogen Klrg1 antibody (eBioscience, 2F1) was used in flow cytometry on mouse samples (fig 2). J Virol (2016) ncbi
Syrian golden hamster monoclonal (2F1)
  • flow cytometry; mouse
In order to study PI3Kdelta in CD8+ T cells during infection with Listeria monocytogenes, Invitrogen Klrg1 antibody (eBioscience, 2F1) was used in flow cytometry on mouse samples . J Immunol (2015) ncbi
Syrian golden hamster monoclonal (2F1)
  • flow cytometry; mouse; loading ...; fig s2
In order to test if anti-retroviral natural killer cell functions are inhibited by T regulatory cells during an acute Friend retrovirus infection, Invitrogen Klrg1 antibody (eBioscience, 2F1) was used in flow cytometry on mouse samples (fig s2). Retrovirology (2015) ncbi
Syrian golden hamster monoclonal (2F1)
  • flow cytometry; mouse; fig 3
Invitrogen Klrg1 antibody (eBioscience, 2F1) was used in flow cytometry on mouse samples (fig 3). Nat Immunol (2015) ncbi
Syrian golden hamster monoclonal (2F1)
  • flow cytometry; mouse; fig s4
Invitrogen Klrg1 antibody (eBioscience, 11-5893) was used in flow cytometry on mouse samples (fig s4). EMBO Mol Med (2015) ncbi
Syrian golden hamster monoclonal (2F1)
  • flow cytometry; mouse; fig s3
Invitrogen Klrg1 antibody (eBioscience, 2F1) was used in flow cytometry on mouse samples (fig s3). Nat Immunol (2015) ncbi
Syrian golden hamster monoclonal (2F1)
  • flow cytometry; mouse
Invitrogen Klrg1 antibody (eBioscience, 2F1) was used in flow cytometry on mouse samples . J Immunol (2015) ncbi
Syrian golden hamster monoclonal (2F1)
  • flow cytometry; mouse
Invitrogen Klrg1 antibody (eBioscience, 2F1) was used in flow cytometry on mouse samples . Proc Natl Acad Sci U S A (2014) ncbi
Syrian golden hamster monoclonal (2F1)
  • flow cytometry; mouse; fig s7
Invitrogen Klrg1 antibody (eBioscience, 2F1) was used in flow cytometry on mouse samples (fig s7). Nat Immunol (2014) ncbi
Syrian golden hamster monoclonal (2F1)
  • flow cytometry; mouse
Invitrogen Klrg1 antibody (eBioscience, 2F1) was used in flow cytometry on mouse samples . PLoS Pathog (2014) ncbi
Syrian golden hamster monoclonal (2F1)
  • flow cytometry; mouse; fig s5
Invitrogen Klrg1 antibody (eBioscience, 2F1) was used in flow cytometry on mouse samples (fig s5). Nature (2013) ncbi
Syrian golden hamster monoclonal (2F1)
  • flow cytometry; mouse
In order to elucidate how TGF-beta signaling regulates the self-reactivity of peripheral T cells, Invitrogen Klrg1 antibody (eBioscience, 2F1) was used in flow cytometry on mouse samples . Nat Immunol (2012) ncbi
Syrian golden hamster monoclonal (2F1)
  • flow cytometry; mouse
In order to determine the role for DOCK8 in peripheral CD8 T cell survival and function, Invitrogen Klrg1 antibody (eBioscience, 2F1) was used in flow cytometry on mouse samples . J Exp Med (2011) ncbi
Syrian golden hamster monoclonal (2F1)
  • flow cytometry; mouse; fig 1b
In order to study the effect of KLRG1 and E-cadherin interactions in different immune cells, Invitrogen Klrg1 antibody (eBioscience, 2F1) was used in flow cytometry on mouse samples (fig 1b). Blood (2009) ncbi
Syrian golden hamster monoclonal (2F1)
  • flow cytometry; mouse; fig 9
Invitrogen Klrg1 antibody (eBioscience, 2F1) was used in flow cytometry on mouse samples (fig 9). J Immunol (2007) ncbi
Syrian golden hamster monoclonal (2F1)
  • flow cytometry; mouse; fig 4A
In order to discuss the development and functions of effector and memory Foxp3+ T cells, Invitrogen Klrg1 antibody (eBioscience, 2F1) was used in flow cytometry on mouse samples (fig 4A). J Immunol (2007) ncbi
BioLegend
Syrian golden hamster monoclonal (2F1/KLRG1)
  • flow cytometry; mouse; 1:100; loading ...; fig 4e
BioLegend Klrg1 antibody (Biolegend, 138411) was used in flow cytometry on mouse samples at 1:100 (fig 4e). Nat Commun (2021) ncbi
Syrian golden hamster monoclonal (2F1/KLRG1)
  • flow cytometry; mouse; 1:200; loading ...; fig s8g
BioLegend Klrg1 antibody (BioLegend, 138417) was used in flow cytometry on mouse samples at 1:200 (fig s8g). Nature (2021) ncbi
Syrian golden hamster monoclonal (2F1/KLRG1)
  • flow cytometry; mouse; loading ...; fig s2a
BioLegend Klrg1 antibody (BioLegend, 138429) was used in flow cytometry on mouse samples (fig s2a). Cell (2020) ncbi
Syrian golden hamster monoclonal (2F1/KLRG1)
  • flow cytometry; mouse; 1:100; loading ...; fig 6a, 6s1a
BioLegend Klrg1 antibody (Biolegend, 138417) was used in flow cytometry on mouse samples at 1:100 (fig 6a, 6s1a). elife (2020) ncbi
Syrian golden hamster monoclonal (2F1/KLRG1)
  • flow cytometry; mouse; loading ...; fig 1a
BioLegend Klrg1 antibody (Biolegend, 2F1/KLRG1) was used in flow cytometry on mouse samples (fig 1a). BMC Immunol (2019) ncbi
Syrian golden hamster monoclonal (2F1/KLRG1)
  • flow cytometry; mouse; loading ...; fig s2d
BioLegend Klrg1 antibody (Biolegend, 138410) was used in flow cytometry on mouse samples (fig s2d). Cell Rep (2019) ncbi
Syrian golden hamster monoclonal (2F1/KLRG1)
  • flow cytometry; human; loading ...; fig 1b
BioLegend Klrg1 antibody (Biolegend, 138419) was used in flow cytometry on human samples (fig 1b). Cell Mol Gastroenterol Hepatol (2020) ncbi
Syrian golden hamster monoclonal (2F1/KLRG1)
  • flow cytometry; mouse; fig 3e
BioLegend Klrg1 antibody (BioLegend, 138416) was used in flow cytometry on mouse samples (fig 3e). Immunity (2019) ncbi
Syrian golden hamster monoclonal (2F1/KLRG1)
  • flow cytometry; mouse; loading ...; fig 1c
BioLegend Klrg1 antibody (BioLegend, 138412) was used in flow cytometry on mouse samples (fig 1c). Cell (2019) ncbi
Syrian golden hamster monoclonal (2F1/KLRG1)
  • flow cytometry; mouse; loading ...; fig 3e
BioLegend Klrg1 antibody (BioLegend, 138416) was used in flow cytometry on mouse samples (fig 3e). Immunity (2018) ncbi
Syrian golden hamster monoclonal (2F1/KLRG1)
  • flow cytometry; mouse; loading ...; fig 3
BioLegend Klrg1 antibody (Biolegend, 138412) was used in flow cytometry on mouse samples (fig 3). Sci Rep (2017) ncbi
Syrian golden hamster monoclonal (2F1/KLRG1)
  • flow cytometry; mouse; loading ...; fig s1a
BioLegend Klrg1 antibody (BioLegend, 2F1/KLRG1) was used in flow cytometry on mouse samples (fig s1a). Nature (2017) ncbi
Syrian golden hamster monoclonal (2F1/KLRG1)
  • flow cytometry; mouse; loading ...; fig s7e
In order to find microenvironmental regulators of metastatic colonization, BioLegend Klrg1 antibody (Biolegend, 2F1/KLRG1) was used in flow cytometry on mouse samples (fig s7e). Nature (2017) ncbi
Syrian golden hamster monoclonal (2F1/KLRG1)
  • flow cytometry; mouse; fig 5b
BioLegend Klrg1 antibody (BioLegend, 2F1/KLRG1) was used in flow cytometry on mouse samples (fig 5b). Nat Commun (2016) ncbi
Syrian golden hamster monoclonal (2F1/KLRG1)
  • flow cytometry; mouse; loading ...; fig 1a
BioLegend Klrg1 antibody (BioLegend, 2F1/KLRG1) was used in flow cytometry on mouse samples (fig 1a). J Immunol (2017) ncbi
Syrian golden hamster monoclonal (2F1/KLRG1)
  • flow cytometry; mouse; 1:100; fig s1a
In order to suggest that air-pollution-induced atopic dermatitis occurs through activation of AhR, BioLegend Klrg1 antibody (BioLegend, 2F1/KLRG1) was used in flow cytometry on mouse samples at 1:100 (fig s1a). Nat Immunol (2017) ncbi
Syrian golden hamster monoclonal (2F1/KLRG1)
  • flow cytometry; human; loading ...; fig 1b
BioLegend Klrg1 antibody (BioLegend, 2F1/KLRG1) was used in flow cytometry on human samples (fig 1b). Nat Immunol (2016) ncbi
Syrian golden hamster monoclonal (2F1/KLRG1)
  • flow cytometry; mouse; fig s13
In order to study the response of intestinal tuft cells to parasites, BioLegend Klrg1 antibody (Biolegend, 2F1/KLRG1) was used in flow cytometry on mouse samples (fig s13). Science (2016) ncbi
Syrian golden hamster monoclonal (2F1/KLRG1)
  • flow cytometry; mouse; fig 5
BioLegend Klrg1 antibody (Biolegend, 2F1) was used in flow cytometry on mouse samples (fig 5). Sci Rep (2016) ncbi
Syrian golden hamster monoclonal (2F1/KLRG1)
  • flow cytometry; mouse; fig 2a
BioLegend Klrg1 antibody (Biolegend, 2F1/KLRG1) was used in flow cytometry on mouse samples (fig 2a). J Immunol (2015) ncbi
Syrian golden hamster monoclonal (2F1/KLRG1)
  • flow cytometry; mouse; fig 3c
In order to assess a CD 4 T-cell population during tuberculosis that has memory-like properties maintained by Bcl6 and ICOS-dependent pathways, BioLegend Klrg1 antibody (BioLegend, 2F1) was used in flow cytometry on mouse samples (fig 3c). J Exp Med (2015) ncbi
Syrian golden hamster monoclonal (2F1/KLRG1)
  • flow cytometry; mouse
BioLegend Klrg1 antibody (BioLegend, 2F1/KLRG1) was used in flow cytometry on mouse samples . J Immunol (2015) ncbi
Santa Cruz Biotechnology
Syrian golden hamster monoclonal (2F1)
  • flow cytometry; mouse; fig s7b
Santa Cruz Biotechnology Klrg1 antibody (Santa Cruz, 2F1) was used in flow cytometry on mouse samples (fig s7b). Proc Natl Acad Sci U S A (2015) ncbi
SouthernBiotech
monoclonal (2F1)
  • flow cytometry; mouse; loading ...; fig 4e
SouthernBiotech Klrg1 antibody (Southern Biotech, 2F1) was used in flow cytometry on mouse samples (fig 4e). Nature (2019) ncbi
monoclonal (2F1)
  • flow cytometry; mouse; loading ...; fig 6d
SouthernBiotech Klrg1 antibody (Southern Biotech, 2F1) was used in flow cytometry on mouse samples (fig 6d). J Immunol (2019) ncbi
Tonbo Biosciences
monoclonal (2F1)
  • flow cytometry; mouse; loading ...; fig 3h
Tonbo Biosciences Klrg1 antibody (Tonbo Biosciences, 50-5893) was used in flow cytometry on mouse samples (fig 3h). Cell Rep (2018) ncbi
BD Biosciences
hamsters monoclonal (2F1)
  • flow cytometry; mouse; loading ...
BD Biosciences Klrg1 antibody (BD Biosciences, 561621) was used in flow cytometry on mouse samples . Front Immunol (2021) ncbi
hamsters monoclonal (2F1)
  • flow cytometry; mouse
BD Biosciences Klrg1 antibody (BD Biosciences, 562190) was used in flow cytometry on mouse samples . Cancer Cell (2021) ncbi
hamsters monoclonal (2F1)
  • flow cytometry; mouse; 1:200; loading ...
BD Biosciences Klrg1 antibody (BD Horizon, 2F1) was used in flow cytometry on mouse samples at 1:200. Nat Commun (2021) ncbi
hamsters monoclonal (2F1)
  • flow cytometry; mouse; loading ...; fig 8a
BD Biosciences Klrg1 antibody (BD Biosciences, 2F1) was used in flow cytometry on mouse samples (fig 8a). Front Immunol (2020) ncbi
hamsters monoclonal (2F1)
  • flow cytometry; mouse; loading ...; fig 2b
BD Biosciences Klrg1 antibody (BD Biosciences, 561619) was used in flow cytometry on mouse samples (fig 2b). Immunity (2019) ncbi
monoclonal (2F1)
  • flow cytometry; mouse; 1:200; loading ...; fig s1f
BD Biosciences Klrg1 antibody (BD Biosciences, 740156) was used in flow cytometry on mouse samples at 1:200 (fig s1f). Nat Commun (2018) ncbi
hamsters monoclonal (2F1)
  • flow cytometry; mouse; fig 3c
BD Biosciences Klrg1 antibody (BD Biosciences, 2F1) was used in flow cytometry on mouse samples (fig 3c). Oncotarget (2018) ncbi
hamsters monoclonal (2F1)
  • flow cytometry; mouse; loading ...; fig 5d
BD Biosciences Klrg1 antibody (BD Biosciences, 2F1/KLRG1) was used in flow cytometry on mouse samples (fig 5d). Infect Immun (2018) ncbi
hamsters monoclonal (2F1)
  • flow cytometry; mouse; fig 2b
BD Biosciences Klrg1 antibody (BD, 2F1) was used in flow cytometry on mouse samples (fig 2b). J Exp Med (2017) ncbi
hamsters monoclonal (2F1)
  • flow cytometry; mouse; loading ...; fig s2d
In order to investigate how aging affects transcriptional dynamics in naive and CD4 positive T cells, BD Biosciences Klrg1 antibody (BD Biosciences, 2F1) was used in flow cytometry on mouse samples (fig s2d). Science (2017) ncbi
hamsters monoclonal (2F1)
  • flow cytometry; mouse
In order to investigate how organ-specific Btnl genes shape local T cell compartments, BD Biosciences Klrg1 antibody (BD, 562897) was used in flow cytometry on mouse samples . Cell (2016) ncbi
hamsters monoclonal (2F1)
  • flow cytometry; mouse; loading ...; fig 2a
In order to explore the role of exhausted CD8 positive CXCR5 positive T cells in mice chronically infected with lymphocytic choriomeningitis virus, BD Biosciences Klrg1 antibody (BD, 2F1) was used in flow cytometry on mouse samples (fig 2a). Nature (2016) ncbi
hamsters monoclonal (2F1)
  • flow cytometry; mouse; fig 3
In order to study the functions of WASp knock out natural killer cells, BD Biosciences Klrg1 antibody (BD Biosciences, 2F1) was used in flow cytometry on mouse samples (fig 3). Sci Rep (2016) ncbi
hamsters monoclonal (2F1)
  • flow cytometry; mouse; loading ...; fig 3a
In order to assess the capacity of dried microneedle array vaccination on effector/memory CD8 positive T cell subsets, BD Biosciences Klrg1 antibody (BD Biosciences, 2F1) was used in flow cytometry on mouse samples (fig 3a). Vaccine (2015) ncbi
hamsters monoclonal (2F1)
  • flow cytometry; rat; fig s3
BD Biosciences Klrg1 antibody (BD Biosciences, 2F1) was used in flow cytometry on rat samples (fig s3). Eur J Immunol (2015) ncbi
hamsters monoclonal (2F1)
  • flow cytometry; mouse
BD Biosciences Klrg1 antibody (BD Biosciences, 2F1) was used in flow cytometry on mouse samples . J Immunol (2014) ncbi
Articles Reviewed
  1. Deng F, Hu J, Yang X, Sun Q, Lin Z, Zhao B, et al. Gut Microbial Metabolite Pravastatin Attenuates Intestinal Ischemia/Reperfusion Injury Through Promoting IL-13 Release From Type II Innate Lymphoid Cells via IL-33/ST2 Signaling. Front Immunol. 2021;12:704836 pubmed publisher
  2. Petley E, Koay H, Henderson M, Sek K, Todd K, Keam S, et al. MAIT cells regulate NK cell-mediated tumor immunity. Nat Commun. 2021;12:4746 pubmed publisher
  3. Hutton C, Heider F, Blanco Gómez A, Banyard A, Kononov A, Zhang X, et al. Single-cell analysis defines a pancreatic fibroblast lineage that supports anti-tumor immunity. Cancer Cell. 2021;: pubmed publisher
  4. Amoozgar Z, Kloepper J, Ren J, Tay R, Kazer S, Kiner E, et al. Targeting Treg cells with GITR activation alleviates resistance to immunotherapy in murine glioblastomas. Nat Commun. 2021;12:2582 pubmed publisher
  5. Bielecki P, Riesenfeld S, Hütter J, Torlai Triglia E, Kowalczyk M, Ricardo Gonzalez R, et al. Skin-resident innate lymphoid cells converge on a pathogenic effector state. Nature. 2021;592:128-132 pubmed publisher
  6. Grand M, Waqasi M, Demarta Gatsi C, Wei Y, Peronet R, Commere P, et al. Hepatic Inflammation Confers Protective Immunity Against Liver Stages of Malaria Parasite. Front Immunol. 2020;11:585502 pubmed publisher
  7. Pasciuto E, Burton O, Roca C, Lagou V, Rajan W, Theys T, et al. Microglia Require CD4 T Cells to Complete the Fetal-to-Adult Transition. Cell. 2020;182:625-640.e24 pubmed publisher
  8. Vacca F, Chauch C, Jamwal A, Hinchy E, Heieis G, Webster H, et al. A helminth-derived suppressor of ST2 blocks allergic responses. elife. 2020;9: pubmed publisher
  9. Tizian C, Lahmann A, Hölsken O, Cosovanu C, Kofoed Branzk M, Heinrich F, et al. c-Maf restrains T-bet-driven programming of CCR6-negative group 3 innate lymphoid cells. elife. 2020;9: pubmed publisher
  10. Wei J, Long L, Zheng W, Dhungana Y, Lim S, Guy C, et al. Targeting REGNASE-1 programs long-lived effector T cells for cancer therapy. Nature. 2019;576:471-476 pubmed publisher
  11. Mantani P, Dunér P, Ljungcrantz I, Nilsson J, Bjorkbacka H, Fredrikson G. ILC2 transfers to apolipoprotein E deficient mice reduce the lipid content of atherosclerotic lesions. BMC Immunol. 2019;20:47 pubmed publisher
  12. Li A, Herbst R, Canner D, Schenkel J, Smith O, Kim J, et al. IL-33 Signaling Alters Regulatory T Cell Diversity in Support of Tumor Development. Cell Rep. 2019;29:2998-3008.e8 pubmed publisher
  13. Wang L, Shen E, Luo L, Rabe H, Wang Q, Yin J, et al. Control of Germinal Center Localization and Lineage Stability of Follicular Regulatory T Cells by the Blimp1 Transcription Factor. Cell Rep. 2019;29:1848-1861.e6 pubmed publisher
  14. Leone R, Zhao L, Englert J, Sun I, Oh M, Sun I, et al. Glutamine blockade induces divergent metabolic programs to overcome tumor immune evasion. Science. 2019;366:1013-1021 pubmed publisher
  15. Chen Z, Ji Z, Ngiow S, Manne S, Cai Z, Huang A, et al. TCF-1-Centered Transcriptional Network Drives an Effector versus Exhausted CD8 T Cell-Fate Decision. Immunity. 2019;51:840-855.e5 pubmed publisher
  16. Di Blasi D, Boldanova T, Mori L, Terracciano L, Heim M, De Libero G. Unique T-Cell Populations Define Immune-Inflamed Hepatocellular Carcinoma. Cell Mol Gastroenterol Hepatol. 2020;9:195-218 pubmed publisher
  17. Khan O, Giles J, McDonald S, Manne S, Ngiow S, Patel K, et al. TOX transcriptionally and epigenetically programs CD8+ T cell exhaustion. Nature. 2019;: pubmed publisher
  18. Wu J, Ma S, Sandhoff R, Ming Y, Hotz Wagenblatt A, Timmerman V, et al. Loss of Neurological Disease HSAN-I-Associated Gene SPTLC2 Impairs CD8+ T Cell Responses to Infection by Inhibiting T Cell Metabolic Fitness. Immunity. 2019;50:1218-1231.e5 pubmed publisher
  19. Kobayashi T, Voisin B, Kim D, Kennedy E, Jo J, Shih H, et al. Homeostatic Control of Sebaceous Glands by Innate Lymphoid Cells Regulates Commensal Bacteria Equilibrium. Cell. 2019;176:982-997.e16 pubmed publisher
  20. McLaren J, Clement M, Marsden M, Miners K, Llewellyn Lacey S, Grant E, et al. IL-33 Augments Virus-Specific Memory T Cell Inflation and Potentiates the Efficacy of an Attenuated Cytomegalovirus-Based Vaccine. J Immunol. 2019;202:943-955 pubmed publisher
  21. Wang J, Sanmamed M, Datar I, Su T, Ji L, Sun J, et al. Fibrinogen-like Protein 1 Is a Major Immune Inhibitory Ligand of LAG-3. Cell. 2019;176:334-347.e12 pubmed publisher
  22. Karmaus P, Chen X, Lim S, Herrada A, Nguyen T, Xu B, et al. Metabolic heterogeneity underlies reciprocal fates of TH17 cell stemness and plasticity. Nature. 2019;565:101-105 pubmed publisher
  23. Muscate F, Stetter N, Schramm C, Schulze zur Wiesch J, Bosurgi L, Jacobs T. HVEM and CD160: Regulators of Immunopathology During Malaria Blood-Stage. Front Immunol. 2018;9:2611 pubmed publisher
  24. Wang F, Meng M, Mo B, Yang Y, Ji Y, Huang P, et al. Crosstalks between mTORC1 and mTORC2 variagate cytokine signaling to control NK maturation and effector function. Nat Commun. 2018;9:4874 pubmed publisher
  25. Geary C, Krishna C, Lau C, Adams N, Gearty S, Pritykin Y, et al. Non-redundant ISGF3 Components Promote NK Cell Survival in an Auto-regulatory Manner during Viral Infection. Cell Rep. 2018;24:1949-1957.e6 pubmed publisher
  26. Amôr N, de Oliveira C, Gasparoto T, Vilas Boas V, Perri G, Kaneno R, et al. ST2/IL-33 signaling promotes malignant development of experimental squamous cell carcinoma by decreasing NK cells cytotoxicity and modulating the intratumoral cell infiltrate. Oncotarget. 2018;9:30894-30904 pubmed publisher
  27. Baens M, Stirparo R, Lampi Y, Verbeke D, Vandepoel R, Cools J, et al. Malt1 self-cleavage is critical for regulatory T cell homeostasis and anti-tumor immunity in mice. Eur J Immunol. 2018;48:1728-1738 pubmed publisher
  28. Nadjsombati M, McGinty J, Lyons Cohen M, Jaffe J, DiPeso L, Schneider C, et al. Detection of Succinate by Intestinal Tuft Cells Triggers a Type 2 Innate Immune Circuit. Immunity. 2018;49:33-41.e7 pubmed publisher
  29. Splitt S, Souza S, Valentine K, Castellanos B, Curd A, Hoyer K, et al. PD-L1, TIM-3, and CTLA-4 Blockade Fails To Promote Resistance to Secondary Infection with Virulent Strains of Toxoplasma gondii. Infect Immun. 2018;86: pubmed publisher
  30. Abel A, Tiwari A, Gerbec Z, Siebert J, Yang C, Schloemer N, et al. IQ Domain-Containing GTPase-Activating Protein 1 Regulates Cytoskeletal Reorganization and Facilitates NKG2D-Mediated Mechanistic Target of Rapamycin Complex 1 Activation and Cytokine Gene Translation in Natural Killer Cells. Front Immunol. 2018;9:1168 pubmed publisher
  31. Noguchi N, Nakamura R, Hatano S, Yamada H, Sun X, Ohara N, et al. Interleukin-21 Induces Short-Lived Effector CD8+ T Cells but Does Not Inhibit Their Exhaustion after Mycobacterium bovis BCG Infection in Mice. Infect Immun. 2018;86: pubmed publisher
  32. Khan A, Carpenter B, Santos e Sousa P, Pospori C, Khorshed R, Griffin J, et al. Redirection to the bone marrow improves T cell persistence and antitumor functions. J Clin Invest. 2018;128:2010-2024 pubmed publisher
  33. Omilusik K, Nadjsombati M, Shaw L, Yu B, Milner J, Goldrath A. Sustained Id2 regulation of E proteins is required for terminal differentiation of effector CD8+ T cells. J Exp Med. 2018;215:773-783 pubmed publisher
  34. Linehan J, Harrison O, Han S, Byrd A, Vujkovic Cvijin I, Villarino A, et al. Non-classical Immunity Controls Microbiota Impact on Skin Immunity and Tissue Repair. Cell. 2018;172:784-796.e18 pubmed publisher
  35. Huang Y, Mao K, Chen X, Sun M, Kawabe T, Li W, et al. S1P-dependent interorgan trafficking of group 2 innate lymphoid cells supports host defense. Science. 2018;359:114-119 pubmed publisher
  36. Glasner A, Isaacson B, Viukov S, Neuman T, Friedman N, Mandelboim M, et al. Increased NK cell immunity in a transgenic mouse model of NKp46 overexpression. Sci Rep. 2017;7:13090 pubmed publisher
  37. Danahy D, Anthony S, Jensen I, Hartwig S, Shan Q, Xue H, et al. Polymicrobial sepsis impairs bystander recruitment of effector cells to infected skin despite optimal sensing and alarming function of skin resident memory CD8 T cells. PLoS Pathog. 2017;13:e1006569 pubmed publisher
  38. Wallrapp A, Riesenfeld S, Burkett P, Abdulnour R, Nyman J, Dionne D, et al. The neuropeptide NMU amplifies ILC2-driven allergic lung inflammation. Nature. 2017;549:351-356 pubmed publisher
  39. Laffont S, Blanquart E, Savignac M, Cenac C, Laverny G, Metzger D, et al. Androgen signaling negatively controls group 2 innate lymphoid cells. J Exp Med. 2017;214:1581-1592 pubmed publisher
  40. Meinicke H, Bremser A, Brack M, Schrenk K, Pircher H, Izcue A. KLRG1 impairs regulatory T-cell competitive fitness in the gut. Immunology. 2017;152:65-73 pubmed publisher
  41. Meinicke H, Bremser A, Brack M, Akeus P, Pearson C, Bullers S, et al. Tumour-associated changes in intestinal epithelial cells cause local accumulation of KLRG1+ GATA3+ regulatory T cells in mice. Immunology. 2017;152:74-88 pubmed publisher
  42. Martinez Jimenez C, Eling N, Chen H, Vallejos C, Kolodziejczyk A, Connor F, et al. Aging increases cell-to-cell transcriptional variability upon immune stimulation. Science. 2017;355:1433-1436 pubmed publisher
  43. Huang R, Francois A, McGray A, Miliotto A, Odunsi K. Compensatory upregulation of PD-1, LAG-3, and CTLA-4 limits the efficacy of single-agent checkpoint blockade in metastatic ovarian cancer. Oncoimmunology. 2017;6:e1249561 pubmed publisher
  44. Knudson K, Pritzl C, Saxena V, Altman A, Daniels M, Teixeiro E. NFκB-Pim-1-Eomesodermin axis is critical for maintaining CD8 T-cell memory quality. Proc Natl Acad Sci U S A. 2017;114:E1659-E1667 pubmed publisher
  45. van der Weyden L, Arends M, Campbell A, Bald T, Wardle Jones H, Griggs N, et al. Genome-wide in vivo screen identifies novel host regulators of metastatic colonization. Nature. 2017;541:233-236 pubmed publisher
  46. Ohs I, Van Den Broek M, Nussbaum K, MUNZ C, Arnold S, Quezada S, et al. Interleukin-12 bypasses common gamma-chain signalling in emergency natural killer cell lymphopoiesis. Nat Commun. 2016;7:13708 pubmed publisher
  47. Tripathi D, Venkatasubramanian S, Cheekatla S, Paidipally P, Welch E, Tvinnereim A, et al. A TLR9 agonist promotes IL-22-dependent pancreatic islet allograft survival in type 1 diabetic mice. Nat Commun. 2016;7:13896 pubmed publisher
  48. Ma C, Mishra S, Demel E, Liu Y, Zhang N. TGF-? Controls the Formation of Kidney-Resident T Cells via Promoting Effector T Cell Extravasation. J Immunol. 2017;198:749-756 pubmed publisher
  49. Hidaka T, Ogawa E, Kobayashi E, Suzuki T, Funayama R, Nagashima T, et al. The aryl hydrocarbon receptor AhR links atopic dermatitis and air pollution via induction of the neurotrophic factor artemin. Nat Immunol. 2017;18:64-73 pubmed publisher
  50. Di Marco Barros R, Roberts N, Dart R, Vantourout P, Jandke A, Nussbaumer O, et al. Epithelia Use Butyrophilin-like Molecules to Shape Organ-Specific γδ T Cell Compartments. Cell. 2016;167:203-218.e17 pubmed publisher
  51. Lewis G, Wehrens E, Labarta Bajo L, Streeck H, Zuniga E. TGF-? receptor maintains CD4 T helper cell identity during chronic viral infections. J Clin Invest. 2016;126:3799-3813 pubmed publisher
  52. Ushiki T, Huntington N, Glaser S, Kiu H, Georgiou A, Zhang J, et al. Rapid Inflammation in Mice Lacking Both SOCS1 and SOCS3 in Hematopoietic Cells. PLoS ONE. 2016;11:e0162111 pubmed publisher
  53. Ladle B, Li K, Phillips M, Pucsek A, Haile A, Powell J, et al. De novo DNA methylation by DNA methyltransferase 3a controls early effector CD8+ T-cell fate decisions following activation. Proc Natl Acad Sci U S A. 2016;113:10631-6 pubmed publisher
  54. Guo H, Cranert S, Lu Y, Zhong M, Zhang S, Chen J, et al. Deletion of Slam locus in mice reveals inhibitory role of SLAM family in NK cell responses regulated by cytokines and LFA-1. J Exp Med. 2016;213:2187-207 pubmed publisher
  55. Chopra M, Biehl M, Steinfatt T, Brandl A, Kums J, Amich J, et al. Exogenous TNFR2 activation protects from acute GvHD via host T reg cell expansion. J Exp Med. 2016;213:1881-900 pubmed publisher
  56. He R, Hou S, Liu C, Zhang A, Bai Q, Han M, et al. Follicular CXCR5- expressing CD8(+) T cells curtail chronic viral infection. Nature. 2016;537:412-428 pubmed publisher
  57. Kritikou J, Dahlberg C, Baptista M, Wagner A, Banerjee P, Gwalani L, et al. IL-2 in the tumor microenvironment is necessary for Wiskott-Aldrich syndrome protein deficient NK cells to respond to tumors in vivo. Sci Rep. 2016;6:30636 pubmed publisher
  58. Xu A, Bhanumathy K, Wu J, Ye Z, Freywald A, Leary S, et al. IL-15 signaling promotes adoptive effector T-cell survival and memory formation in irradiation-induced lymphopenia. Cell Biosci. 2016;6:30 pubmed publisher
  59. Reynaldi A, Smith N, Schlub T, Venturi V, Rudd B, Davenport M. Modeling the dynamics of neonatal CD8+ T-cell responses. Immunol Cell Biol. 2016;94:838-848 pubmed publisher
  60. Bal S, Bernink J, Nagasawa M, Groot J, Shikhagaie M, Golebski K, et al. IL-1?, IL-4 and IL-12 control the fate of group 2 innate lymphoid cells in human airway inflammation in the lungs. Nat Immunol. 2016;17:636-45 pubmed publisher
  61. Kabat A, Harrison O, Riffelmacher T, Moghaddam A, Pearson C, Laing A, et al. The autophagy gene Atg16l1 differentially regulates Treg and TH2 cells to control intestinal inflammation. elife. 2016;5:e12444 pubmed publisher
  62. Pelly V, Kannan Y, Coomes S, Entwistle L, Rückerl D, Seddon B, et al. IL-4-producing ILC2s are required for the differentiation of TH2 cells following Heligmosomoides polygyrus infection. Mucosal Immunol. 2016;9:1407-1417 pubmed publisher
  63. Ludigs K, Jandus C, Utzschneider D, Staehli F, Bessoles S, Dang A, et al. NLRC5 shields T lymphocytes from NK-cell-mediated elimination under inflammatory conditions. Nat Commun. 2016;7:10554 pubmed publisher
  64. Howitt M, Lavoie S, Michaud M, Blum A, Tran S, Weinstock J, et al. Tuft cells, taste-chemosensory cells, orchestrate parasite type 2 immunity in the gut. Science. 2016;351:1329-33 pubmed publisher
  65. Polansky J, Bahri R, Divivier M, Duitman E, Vock C, Goyeneche Patino D, et al. High dose CD11c-driven IL15 is sufficient to drive NK cell maturation and anti-tumor activity in a trans-presentation independent manner. Sci Rep. 2016;6:19699 pubmed publisher
  66. Moretto M, Khan I. IL-21 Is Important for Induction of KLRG1+ Effector CD8 T Cells during Acute Intracellular Infection. J Immunol. 2016;196:375-84 pubmed publisher
  67. Verma S, Weiskopf D, Gupta A, McDonald B, Peters B, Sette A, et al. Cytomegalovirus-Specific CD4 T Cells Are Cytolytic and Mediate Vaccine Protection. J Virol. 2016;90:650-8 pubmed publisher
  68. Pearce V, Bouabe H, MacQueen A, Carbonaro V, Okkenhaug K. PI3Kδ Regulates the Magnitude of CD8+ T Cell Responses after Challenge with Listeria monocytogenes. J Immunol. 2015;195:3206-17 pubmed publisher
  69. Littwitz Salomon E, Akhmetzyanova I, Vallet C, Francois S, Dittmer U, Gibbert K. Activated regulatory T cells suppress effector NK cell responses by an IL-2-mediated mechanism during an acute retroviral infection. Retrovirology. 2015;12:66 pubmed publisher
  70. Li Y, Shen C, Zhu B, Shi F, Eisen H, Chen J. Persistent Antigen and Prolonged AKT-mTORC1 Activation Underlie Memory CD8 T Cell Impairment in the Absence of CD4 T Cells. J Immunol. 2015;195:1591-8 pubmed publisher
  71. Weigelin B, Bolaños E, Teijeira A, Martinez Forero I, Labiano S, Azpilikueta A, et al. Focusing and sustaining the antitumor CTL effector killer response by agonist anti-CD137 mAb. Proc Natl Acad Sci U S A. 2015;112:7551-6 pubmed publisher
  72. Hernández P, Mahlakõiv T, Yang I, Schwierzeck V, Nguyen N, Guendel F, et al. Interferon-λ and interleukin 22 act synergistically for the induction of interferon-stimulated genes and control of rotavirus infection. Nat Immunol. 2015;16:698-707 pubmed publisher
  73. Moguche A, Shafiani S, Clemons C, Larson R, Dinh C, Higdon L, et al. ICOS and Bcl6-dependent pathways maintain a CD4 T cell population with memory-like properties during tuberculosis. J Exp Med. 2015;212:715-28 pubmed publisher
  74. Becker P, Hervouet C, Mason G, KWON S, Klavinskis L. Skin vaccination with live virus vectored microneedle arrays induce long lived CD8(+) T cell memory. Vaccine. 2015;33:4691-8 pubmed publisher
  75. Li C, Li W, Xiao J, Jiao S, Teng F, Xue S, et al. ADAP and SKAP55 deficiency suppresses PD-1 expression in CD8+ cytotoxic T lymphocytes for enhanced anti-tumor immunotherapy. EMBO Mol Med. 2015;7:754-69 pubmed publisher
  76. Wensveen F, Jelenčić V, Valentić S, Šestan M, Wensveen T, Theurich S, et al. NK cells link obesity-induced adipose stress to inflammation and insulin resistance. Nat Immunol. 2015;16:376-85 pubmed publisher
  77. Yuan X, Dee M, Altman N, Malek T. IL-2Rβ-dependent signaling and CD103 functionally cooperate to maintain tolerance in the gut mucosa. J Immunol. 2015;194:1334-46 pubmed publisher
  78. White C, Villarino N, Sloan S, Ganusov V, Schmidt N. Plasmodium suppresses expansion of T cell responses to heterologous infections. J Immunol. 2015;194:697-708 pubmed publisher
  79. Schwartz C, Turqueti Neves A, Hartmann S, Yu P, Nimmerjahn F, Voehringer D. Basophil-mediated protection against gastrointestinal helminths requires IgE-induced cytokine secretion. Proc Natl Acad Sci U S A. 2014;111:E5169-77 pubmed publisher
  80. Backer R, Helbig C, Gentek R, Kent A, Laidlaw B, Dominguez C, et al. A central role for Notch in effector CD8(+) T cell differentiation. Nat Immunol. 2014;15:1143-51 pubmed publisher
  81. Xie L, Choudhury G, Winters A, Yang S, Jin K. Cerebral regulatory T cells restrain microglia/macrophage-mediated inflammatory responses via IL-10. Eur J Immunol. 2015;45:180-91 pubmed publisher
  82. Ebert S, Becker M, Lemmermann N, Büttner J, Michel A, Taube C, et al. Mast cells expedite control of pulmonary murine cytomegalovirus infection by enhancing the recruitment of protective CD8 T cells to the lungs. PLoS Pathog. 2014;10:e1004100 pubmed publisher
  83. Kim E, Gasper D, Lee S, Plisch E, Svaren J, Suresh M. Bach2 regulates homeostasis of Foxp3+ regulatory T cells and protects against fatal lung disease in mice. J Immunol. 2014;192:985-95 pubmed publisher
  84. Nussbaum J, Van Dyken S, von Moltke J, Cheng L, Mohapatra A, Molofsky A, et al. Type 2 innate lymphoid cells control eosinophil homeostasis. Nature. 2013;502:245-8 pubmed publisher
  85. Zhang N, Bevan M. TGF-? signaling to T cells inhibits autoimmunity during lymphopenia-driven proliferation. Nat Immunol. 2012;13:667-73 pubmed publisher
  86. Randall K, Chan S, Ma C, Fung I, Mei Y, Yabas M, et al. DOCK8 deficiency impairs CD8 T cell survival and function in humans and mice. J Exp Med. 2011;208:2305-20 pubmed publisher
  87. Banh C, Fugere C, Brossay L. Immunoregulatory functions of KLRG1 cadherin interactions are dependent on forward and reverse signaling. Blood. 2009;114:5299-306 pubmed publisher
  88. Badovinac V, Harty J. Manipulating the rate of memory CD8+ T cell generation after acute infection. J Immunol. 2007;179:53-63 pubmed
  89. Stephens G, Andersson J, Shevach E. Distinct subsets of FoxP3+ regulatory T cells participate in the control of immune responses. J Immunol. 2007;178:6901-11 pubmed