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Cytotoxic T cell image

All viruses, and some bacteria, multiply in the cytoplasm of infected cells. Once inside cells, these pathogens are not accessible to attack by antibodies and can be eliminated only by the destruction of the infected cells. These infected cells are destroyed by Cytotoxic T Cells, a subset of T lymphocytes that express the CD8 glycoprotein (CD8+) on their surface. 

Cytotoxic T Cells form part of the adaptive immune system and fulfill a role similar to that of the NK cell in the innate immune system. These cells survey the body for the presence of virus-infected and cancerous cells, which they kill by inducing the target cell to apoptose. The elimination of infected cells without the destruction of healthy tissue requires the cytotoxic mechanisms of CD8 T cells to be both powerful and accurately targeted.

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Primary CD8+ Cytotoxic T Cells (ATCC® PCS-800-017™)

Function

Blood vessels graphic

Viral and mutant proteins are found inside infected or cancerous cells. Cells degrade their endogenous proteins via antigen processing, resulting in peptide fragments, some of which are presented by MHC Class I to the T cell antigen receptor (TCR) on CD8+ T cells. Virally infected or cancerous cells will present some viral or mutant protein peptide fragments via MHC class I in this manner. If the T Cell Receptor (TCR) on the cytotoxic T cell is specific for that antigen, it binds to the complex of the class I MHC molecule and the antigen, and the CD8+ T cell destroys the infected cell.

Cytotoxic T cells release the cytotoxins perforin, granzymes, and granulysin in order to kill their target cells. Perforin forms pores in the cell membrane of the target cell, creating an aqueous channel through which granzyme and granulysin can enter. Once in the cytoplasm the target cell the serine protease function of granzyme triggers the caspase cascade, which is a series of cysteine proteases that eventually lead to apoptosis.

CD8+ T cells also release the cytokines Interferon-γ (IFN- γ), TNF-α, and TNF-β, which contribute to the immune response. IFN-γ directly inhibits viral replication, and induces the increased expression of MHC class I in infected cells. This increases the chance that infected cells will be recognised as target cells by CD8+ T cells. IFN-γ also activates macrophages, recruiting them to sites of infection both as effector cells and as antigen-presenting cells.

Immune Cell Differentiation and Expansion Kits:

Human CIK Cell Expansion Kit New!
Expands human CD3+CD56+ cytokine-induced killer (CIK) cell populations from PBMCs.

Cell Activation Reagents

Cell Activation Cocktail
A 500X cocktail of Monensin, PMA, and Ionomycin for activating immune cells.

Resources for in vitro Differentiation and Expansion:

 

T Cells

Molecule

Species

Source

Catalog #

IL-2

Human

E. coli

202-IL

 

Mouse

E. coli

402-ML

 

Rat

E. coli

502-RL

       

Antibodies

Species

Clone

Catalog # (Applications)

CD3

Human

UCHT1

MAB100 (FA, FC, ICC/IF, IP)

 

Mouse

145-2C11

MAB484 (Depl., FA, FC, IP)

CD28

Human

37407

MAB342 (FA, WB)

 

Human

Polyclonal

AF-342-PB (FA, FC, ICC/IF, IHC)

 

Mouse

794716

MAB4832 (FA, FC)

 

Cytokine-induced Killer (CIK) Cells

Molecule

Species

Source

Catalog #

IL-2

Human

E. coli

202-IL

 

Mouse

E. coli

402-ML

 

Rat

E. coli

502-RL

IFN-g

Human

E. coli

285-IF

 

Human

HEK293

10067-IF

 

Mouse

E. coli

485-MI

 

Rat

E. coli

585-IF

Antibodies

Species

Clone

Catalog # (Applications)

CD3

Human

UCHT1

MAB100 (FA, FC, ICC/IF, IP)

 

Mouse

145-2C11

MAB484 (Depl., FA, FC, IP)

Resources for Cytotoxic T Cell research

Cell Resource

Click on the images below to find out more about other immune cell types.

Macrophage cellNeutrophil cellRegulatory T CellCytotoxic T CellNatural killer CellDendritic cell

B CellHelper T CellMyleoid Derived CellMemory T Cell