Welcome Guest
Sign In
Register
Products
Popular Categories
Antibody Search
ELISA Kit Search
Biomolecules
Flow Cytometers
Thermal Cyclers
Microscopes
Transfection Reagents
Featured Products
New Products
Articles
Resources
eBooks
Bench Tips
Tech Insights
Editorial Articles
News
Product Reviews
Future Lab
Multimedia
Biocompare Webinars
Immunotherapy
Reproducibility
Transformative Technologies
Podcasts
Tech Talks
Bench Tip Videos
All Videos and Webinars
Life Science Webinars
Write a Review
Antibodies
Kits/Reagents
Equipment
Services
Resources
Promotions
Events
AACR SPOTLIGHT
Register
Sign In
Biocompare
Products
Antibodies
Antibodies
CD366 (TIM3) Antibody
CD366 (TIM3) Antibody from Thermo Fisher Scientific
Be the first to write a review!
Citations:
(24)
Supplier Page
Supplier Page from
Thermo Fisher Scientific for
CD366 (TIM3) Antibody
Thermo Fisher Scientific's
CD366 (TIM3) Antibody
is a Rat monoclonal antibody. The
CD366 (TIM3) Antibody
was generated using HAVCR2 as the antigen. It reacts with Mouse. This antibody has been shown to work in applications such as: Flow Cytometry.
Product Specs
Company Info
Citations
Reviews
Product Specs
Item
CD366 (TIM3) Antibody
Company
Thermo Fisher Scientific
Price
Pricing Info
Supplier Page
View Company Product Page
Catalog Number
14-5870-82
Quantity
100 µg
Applications
Flow Cytometry
Concentration
0.5 mg/mL
Conjugate/Tag
Unconjugated
Format
PBS with 0.09% sodium azide; pH 7.2
Reactivity
Mouse
Target
CD366 (TIM3)
Isotype
IgG2a kappa
Clone
RMT3-23
Host
Rat
NCBI Full Gene Name
hepatitis A virus cellular receptor 2
NCBI Gene Aliases
TIM-3, Tim3, Timd3
Clonality
Monoclonal
Purity
Affinity chromatography
Storage Temperature
4° C
Antibody Type
Primary
Storage
4° C
Add to Compare List
Thermo Fisher Scientific
Thermo Fisher Scientific
81 Wyman Street
Waltham
,
MA
02451
United States
Phone
: 800-678-5599
Fax: 800-331-2286
Company Profile
Website:
www.thermofisher.com
Citations (24)
(1)
TIM3 Expression in Anaplastic-Thyroid-Cancer-Infiltrating Macrophages: An Emerging Immunotherapeutic Target
Biology
November 3, 2022
Palacios LM, Peyret V, Viano ME, Geysels RC, Chocobar YA, Volpini X, Pellizas CG, Nicola JP, Motran CC, Rodriguez-Galan MC,
et al
.
(2)
Mobilizing phospholipids on tumor plasma membrane implicates phosphatidylserine externalization blockade for cancer immunotherapy
Cell reports
November 1, 2022
Wang W, Wu S, Cen Z, Zhang Y, Chen Y, Huang Y, Cillo AR, Prokopec JS, Quarato G, Vignali DAA,
et al
.
(3)
Breast cancer cell-derived extracellular vesicles promote CD8(+) T cell exhaustion via TGF-β type II receptor signaling
Nature communications
August 1, 2022
Xie F, Zhou X, Su P, Li H, Tu Y, Du J, Pan C, Wei X, Zheng M, Jin K,
et al
.
(4)
Functional assessment of the cell-autonomous role of NADase CD38 in regulating CD8(+) T cell exhaustion
iScience
May 20, 2022
Ma K, Sun L, Shen M, Zhang X, Xiao Z, Wang J, Liu X, Jiang K, Xiao-Feng Qin F, Guo F,
et al
.
(5)
PTENα functions as an immune suppressor and promotes immune resistance in PTEN-mutant cancer
Nature communications
August 26, 2021
Sun Y, Lu D, Yin Y, Song J, Liu Y, Hao W, Qi F, Zhang G, Zhang X, Liu L,
et al
.
(6)
Type 1 Cytotoxic T Cells Increase in Placenta after Intrauterine Inflammation
Frontiers in immunology
January 1, 2021
Liu J, Liu Y, Panda S, Liu A, Lei J, Burd I.
(7)
A Fas-4-1BB fusion protein converts a death to a pro-survival signal and enhances T cell therapy
The Journal of experimental medicine
December 7, 2020
Oda SK, Anderson KG, Ravikumar P, Bonson P, Garcia NM, Jenkins CM, Zhuang S, Daman AW, Chiu EY, Bates BM,
et al
.
(8)
Mapping the Lineage Relationship between CXCR5
+
and CXCR5
-
CD4
+
T Cells in HIV-Infected Human Lymph Nodes
Cell reports
September 17, 2019
Del Alcazar D, Wang Y, He C, Wendel BS, Del Río-Estrada PM, Lin J, Ablanedo-Terrazas Y, Malone MJ, Hernandez SM, Frank I,
et al
.
(9)
Mechanisms of action of ruxolitinib in murine models of hemophagocytic lymphohistiocytosis
Blood
July 11, 2019
Albeituni S, Verbist KC, Tedrick PE, Tillman H, Picarsic J, Bassett R, Nichols KE.
(10)
Down-Regulation of Tim-3 in Monocytes and Macrophages in
Plasmodium
Infection and Its Association with Parasite Clearance
Frontiers in microbiology
January 1, 2017
Hou N, Jiang N, Zou Y, Piao X, Liu S, Li S, Chen Q.
(11)
T-Cell Immunoglobulin- and Mucin-Domain-Containing Molecule 3 Signaling Blockade Improves Cell-Mediated Immunity Against Malaria
The Journal of infectious diseases
November 15, 2016
Hou N, Zou Y, Piao X, Liu S, Wang L, Li S, Chen Q.
(12)
Growth and metastasis of lung adenocarcinoma is potentiated by BMP4-mediated immunosuppression
Oncoimmunology
January 1, 2016
Chen L, Yi X, Goswami S, Ahn YH, Roybal JD, Yang Y, Diao L, Peng D, Peng D, Fradette JJ,
et al
.
(13)
Tim-3 induces Th2-biased immunity and alternative macrophage activation during Schistosoma japonicum infection
Infection and immunity
August 1, 2015
Hou N, Piao X, Liu S, Wu C, Chen Q.
(14)
Combined immune checkpoint protein blockade and low dose whole body irradiation as immunotherapy for myeloma
Journal for immunotherapy of cancer
January 1, 2015
Jing W, Gershan JA, Weber J, Tlomak D, McOlash L, Sabatos-Peyton C, Johnson BD.
(15)
Metastasis is regulated via microRNA-200/ZEB1 axis control of tumour cell PD-L1 expression and intratumoral immunosuppression
Nature communications
October 28, 2014
Chen L, Gibbons DL, Goswami S, Cortez MA, Ahn YH, Byers LA, Zhang X, Yi X, Dwyer D, Lin W,
et al
.
(16)
The influence of T cell Ig mucin-3 signaling on central nervous system autoimmune disease is determined by the effector function of the pathogenic T cells
Journal of immunology (Baltimore, Md. : 1950)
May 15, 2013
Lee SY, Goverman JM.
(17)
T cell Ig mucin-3 promotes homeostasis of sepsis by negatively regulating the TLR response
Journal of immunology (Baltimore, Md. : 1950)
March 1, 2013
Yang X, Jiang X, Chen G, Xiao Y, Geng S, Kang C, Zhou T, Li Y, Guo X, Xiao H,
et al
.
(18)
Transcutaneous vaccination via laser microporation
Journal of controlled release : official journal of the Controlled Release Society
September 10, 2012
Weiss R, Hessenberger M, Kitzmüller S, Bach D, Weinberger EE, Krautgartner WD, Hauser-Kronberger C, Malissen B, Boehler C, Kalia YN,
et al
.
(19)
CD8 T cells recruited early in mouse polyomavirus infection undergo exhaustion
Journal of immunology (Baltimore, Md. : 1950)
May 1, 2012
Wilson JJ, Pack CD, Lin E, Frost EL, Albrecht JA, Hadley A, Hofstetter AR, Tevethia SS, Schell TD, Lukacher AE.
(20)
Exposure to nicotine adversely affects the dendritic cell system and compromises host response to vaccination
Journal of immunology (Baltimore, Md. : 1950)
March 1, 2012
Nouri-Shirazi M, Guinet E.
Page
<<
<
1
2
>
>>
Reviews
Be the First to Write a Review!
CD366 (TIM3) Antibody from Thermo Fisher Scientific
Supplier Page
View Company Product Page
Pricing Info
Product Specs
Company Info
Citations
Reviews
Back To Top