In culture they exhibit much less clumping than many other suspension lines, presumably due to the downregulation of surface adhesion molecules by bcr:abl.[5] However, another study suggests that bcr:abl over-expression may actually increase cell adherence to cell culture plastic.[6] K562 cells can spontaneously develop characteristics similar to early-stage erythrocytes, granulocytes and monocytes[7] and are easily killed by natural killer cells[8] as they lack the MHC complex required to inhibit NK activity.[2] They also lack any trace of Epstein-Barr virus and other herpesviruses. In addition to the Philadelphia chromosome they also exhibit a second reciprocal translocation between the long arm of chromosome 15 with chromosome 17.[1]
Two sub-lines are available which express MHC class-I A2[9] and A3.[10]
Many factors and components play a role in the cell cycle of K562 cells in terms of growth, cell differentiation, and apoptosis.[12] The growth of these leukemic cells are controlled by either initiating cell differentiation or apoptosis to occur.[13]
Cell differentiation is induced by the deacetylase activity in these “undifferentiated progenitor cells,” which alters the phenotype and morphology of the K562 cells.[12] The change in phenotype induces a decrease in the growth rate and leads the K562 cells to the terminal path of becoming mature erythroids, monocytes, and mature macrophages.[12] These changes can also drive the leukemic cells to a state of stress, which allows for increased sensitivity of the cells to drugs that initiate apoptosis.[12]
The problem with K562 cells, and many other cancer cell types, is an overabundance of Aurora kinases.[14] These kinases play a role in the formation of spindles, separation of chromosomes, as well as cytokinesis.[14] These functions are necessary in cells in order to divide and regenerate tissues, and play a maintenance role in homeostatic functions. However, the overabundance of Aurora kinases allows for uncontrolled cellular division, resulting in cancer.[14] Inhibiting these is an important regulation mechanism of cancer, because it prevents cells from progressing into mitosis.[14]
Apoptosis is an important mechanism in regulating K562 cells and can be induced by the changes in the metabolic state of the cells.[12] There are many different cellular components involved in the cycle of apoptosis such as BCR/ABL, Bcl-2, Bax protein, and cytochrome C.[13] The tumor suppressor gene p53 is also important in the cell cycle regulation of K562 cells.[15] This gene targets the cyclin-dependent kinase inhibitor, p21, and causes cell differentiation, cell cycle arrest in G1, and ultimately apoptosis.[15] When the levels of these components are thrown off, they can either no longer inhibit apoptosis of the cancer cells, a role fulfilled by BCR/ABL, or they cause apoptosis to be induced, in the same vein as Bax and cytochrome C.[13] These components are key in the mitochondria, and due to this, it has been supported that apoptosis uses the mitochondrial apoptosis pathway.[13] The offset of these cellular components from their balance point causes morphological changes, which result in the K562 cells being arrested in the G2/M phase of the cell cycle.[13] This arrest leads to “shrinkage, blebbing, nuclear fragmentation, chromatin condensing” and other morphological changes that cause the cell to program death at this point.[13]
The ability to induce these changes in K562 cell cycle and cell cycle regulation provides targets for cancer drugs.[16] One of these drugs is Imatinib, which inhibits BCR/ABL causing growth to cease and apoptosis to begin.[16] Another important group of regulators of the K562 line are Sirtuins, referred to as SIRTS.[12] These play a role in cellular stress, metabolism, and autophagy, by interacting with deacetylases activity in the cell.[12] Other methods being focused on in the regulation of K562 cells include therapeutic methods like polyphyllin D, which caused differentiation from the progenitor state to occur, and for apoptosis to begin.[13]
Klein E, Ben-Bassat H, Neumann H, Ralph P, Zeuthen J, Polliack A, Vánky F (October 1976). "Properties of the K562 cell line, derived from a patient with chronic myeloid leukemia". International Journal of Cancer. 18 (4): 421–431. doi:10.1002/ijc.2910180405. PMID789258. S2CID36818335.
Lozzio BB, Lozzio CB, Bamberger EG, Feliu AS (April 1981). "A multipotential leukemia cell line (K-562) of human origin". Proceedings of the Society for Experimental Biology and Medicine. 166 (4): 546–550. doi:10.3181/00379727-166-41106. PMID7194480. S2CID7571401.
Lozzio BB, Lozzio CB (1979). "Properties and usefulness of the original K-562 human myelogenous leukemia cell line". Leukemia Research. 3 (6): 363–370. doi:10.1016/0145-2126(79)90033-X. PMID95026.
Britten CM, Meyer RG, Kreer T, Drexler I, Wölfel T, Herr W (January 2002). "The use of HLA-A*0201-transfected K562 as standard antigen-presenting cells for CD8(+) T lymphocytes in IFN-gamma ELISPOT assays". Journal of Immunological Methods. 259 (1–2): 95–110. doi:10.1016/S0022-1759(01)00499-9. PMID11730845.
Yang C, Cai H, Meng X (July 2016). "Polyphyllin D induces apoptosis and differentiation in K562 human leukemia cells". International Immunopharmacology. 36: 17–22. doi:10.1016/j.intimp.2016.04.011. PMID27104314.
Fan Y, Lu H, An L, Wang C, Zhou Z, Feng F, etal. (April 2016). "Effect of active fraction of Eriocaulon sieboldianum on human leukemia K562 cells via proliferation inhibition, cell cycle arrest and apoptosis induction". Environmental Toxicology and Pharmacology. 43: 13–20. doi:10.1016/j.etap.2015.11.001. PMID26923230.
Chylicki K, Ehinger M, Svedberg H, Bergh G, Olsson I, Gullberg U (June 2000). "p53-mediated differentiation of the erythroleukemia cell line K562". Cell Growth & Differentiation. 11 (6): 315–324. PMID10910098.
Wang J, Li Q, Wang C, Xiong Q, Lin Y, Sun Q, etal. (January 2016). "Knock-down of CIAPIN1 sensitizes K562 chronic myeloid leukemia cells to Imatinib by regulation of cell cycle and apoptosis-associated members via NF-κB and ERK5 signaling pathway". Biochemical Pharmacology. 99: 132–145. doi:10.1016/j.bcp.2015.12.002. PMID26679828.
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