Key Pathways in Cancer and Targeted Treatment

Cancer is often characterized by dysregulation in cellular pathways and the checkpoints which control cell proliferation, growth, differentiation, and apoptosis. Within the genome there are two types of genes which carefully control cell proliferation and cell death, which are often the driving force behind oncogenesis. Proto-oncogenes drive cell cycle progression while tumor suppressor genes act as checkpoints on the cell cycle; mutations or dysregulation in these types of genes are seen across most if not all cancer types.

The most commonly mutated gene in cancer is TP53, a transcription factor ¹ which acts as a tumors suppressor gene. The protein P53 is a critical component of multiple cellular pathways including response to DNA damage ². The intracellular levels of P53 are kept low by ubiquitination, however when a cell is under stress the ubiquitination is inhibited and P53 accumulates in the cell ¹. The accumulation of P53 triggers transcriptional activation of genes associated with apoptosis, acting as a tumor suppressor ¹. In cancer, mutations in TP53 can cause the protein to be expressed in much smaller amounts or not at all. Additionally, mutations can cause P53 to gain additional function or loose the correct function ³. As P53 is involved in DNA damage response ⁴, the lack of functioning P53 means a cell with DNA damage will not undergo apoptosis, resulting in the survival of mutated, potentially cancerous cells. Current treatment strategies involve promoting the activation of functioning P53 and preventing its degradation ⁵, although these are still in trial stages.

Recently, PD-1 and PD-L1 have been at the forefront of cancer research and development, as cancer cells use the PD-1/PD-L1 pathway to escape immune system detection. PD-L1 is normally found in the placenta, lungs and tonsils, tissues that promote immune tolerance ⁶, however, certain cancer types have been shown to express PD-L1 to create immune tolerance to the tumor. Treatment strategies currently being trialed for breast, lung and gastrointestinal cancers that overexpress PD-L1 mainly target the PD-1 receptor present on T-cells by using targeted immunotherapies ⁶. Additionally, there are also trials for antibodies targeting PD-L1 ⁷ on the cancer cells. The over expression of PD-L1 is used to avoid apoptosis signals ⁸, usually initiated by T-cells, and in fact downregulates the immune response to the tumor through apoptosis of immune cells that would otherwise have recognized the tumor ⁹.

In cancer, the lack of differentiation and the accumulation of immature cells can inhibit the normal function of the tissue. In acute promyelocytic leukaemia ^APL the accumulation of immature myeloid cells is caused by a genetic translocation ^t15;17, resulting the production of a fusion protein, PML-RARα ¹⁰. The PML-RARα fusion protein alters the ability of the Retinoic Acid Receptor to function properly, a critical component of stem cell differentiation, resulting in the accumulation of non-functioning cells. When RARα functions properly it prevents transcriptional activation until retinoic acid binds. This then allows a conformational change in the DNA, promoting transcription of genes related to differentiation ¹¹. The current treatment recommendation for APL includes the use of all-trans retinoic acid ^ATRA ¹², although the mechanism of action is not clearly understood. It is thought that ATRA forces differentiation by inducing the normal function of the RARα protein, or inducing expression of a non-mutated allele ¹³, alternatively, it could promote degradation of the PML-RARα fusion protein ¹¹ by autophagy, reducing the presence of the non-functioning protein making way for normal transcription. The idea of differentiation therapy has been proposed in different cancer types including breast cancer and glioblastoma ¹², with clinical trials underway to target other pathways associated with differentiation.

There are many different cellular pathways which control proliferation, growth, differentiation and apoptosis. Although biologically there are redundancies in these pathways to prevent tumorigenesis and cancer survival, there are critical pathways like PD-1/PD-L1 and P53 that are critical components of normal cellular functions. By establishing reliable cell line models, further strategies to overcome common mutations in cancer can be developed.

This is but a highlight of three key pathways involved in various cancers, but all of these pathways involve a variety of different receptors, effectors, ligands, and other signalling molecules. Our HAP1 and Cancer cell lines include key genes across many different cancer pathways, as assessed by Kegg Pathway Analysis. Check out the table below for your gene of interest.

ABL1	BIRC3	CDKN1B	FAS	FZD8	JAK1	MSH6	PIK3R2	RET	TP53
AKT1	BMP4	CDKN2A	FASLG	FZD9	JUN	MTOR	PIK3R3	RUNX1	TRAF1
AKT2	BRAF	CDKN2B	FGF2	GSK3B	KIT	NCOA4	PLCG1	RXRA	TRAF2
AKT3	BRCA2	CEBPA	FGFR1	GSTP1	KITLG	NFKB1	PLCG2	RXRB	TRAF3
APC	CASP3	CHUK	FGFR2	HDAC1	KRAS	NFKB2	PLD1	SMAD4	TRAF5
APPL1	CASP8	CTNNA1	FGFR3	HDAC2	LEF1	NFKBIA	PPARD	SMO	TRAF6
AR	CASP9	CTNNB1	FLT3	HIF1A	MAPK8	NOS2	PPARG	STAT1	VEGFA
ARAF	CBL	DAPK1	FN1	HRAS	MAPK9	NRAS	PRKCA	STAT3	VEGFB
ARNT	CCDC6	DAPK3	FOS	HSP90AA1	MAP2K1	NTRK1	PRKCG	STAT5B	XIAP
AXIN1	CCND1	E2F1	FOXO1	IGF1R	MAP2K2	PAX8	PTEN	STK4
AXIN2	CCNE1	EGFR	FZD1	IKBKB	MDM2	PGF	RAC1	SUFU
BAD	CCNE2	EGLN1	FZD3	ITGA2	MET	PIAS2	RAF1	TCF7L2
BAX	CDH1	EGLN2	FZD4	ITGA2B	MLH1	PIK3CA	RARA	TFG
BCL2	CDK2	ERBB2	FZD5	ITGA3	MMP2	PIK3CB	RASSF5	TGFB1
BCR	CDK4	ETS1	FZD6	ITGA6	MSH2	PIK3CD	RB1	TGFBR1
BIRC2	CDKN1A	FADD	FZD7	ITGB1	MSH3	PIK3R1	RELA	TGFBR2

Gene knockouts available in HAP1 Cell Line
Gene knockouts available in HAP1 and Cancer Cell Lines
Gene knockouts available in Cancer Cell Lines

References

Targeting p53 pathways: mechanisms, structures, and advances in therapy. Wang, H., Guo, M., Wei, H. et al. 92, s.l. : Sig Transduct Target Ther, 2023, Vol. 8.
An analysis of the clinical and biologic significance of TP53 loss and the identification of potential novel transcriptional targets of TP53 in multiple myeloma. Wei Xiong, Xiaosong Wu, Sarah Starnes, Sarah K. Johnson, Jeff Haessler, Siqing Wang, Lijuan Chen, Bart Barlogie, John D.
p53 mutations in cancer. . Muller, P., Vousden, K. 2013, Nat Cell Biol , Vol. 15.
The diversity of p53 mutations among human brain tumors and their functional consequences. Agata Zupanska, Bozena Kaminska,. 7, s.l. : Neurochemistry International,, 2002, Vol. 40.
Targeting p53 for the treatment of cancer,. Michael J. Duffy, Naoise C. Synnott, Shane O’Grady, John Crown,. s.l. : Seminars in Cancer Biology,, 2022, Vol. 79.
PD-1/PD-L1 blockade in cancer treatment: perspectives and issues. Hamanishi, J., Mandai, M., Matsumura, N. et al. 462–473, s.l. : Int J Clin Oncol, 2016, Vol. 21.
Efficacy of PD-1 or PD-L1 inhibitors and PD-L1 expression status in cancer: meta-analysis. Shen X, Zhao B. k3529, s.l. : BMJ, 2018, Vol. 362.
Regulation and Function of the PD-L1 Checkpoint. Chong Sun, Riccardo Mezzadra, Ton N. Schumacher. 3, s.l. : Immunity, 2018, Vol. 48.
PD-1/PD-L1 pathway: current researches in cancer. Han Y, Liu D, Li L. 3, s.l. : Am J Cancer Res, 2020, Vol. 10.
The theory of APL. Piazza, F., Gurrieri, C. & Pandolfi, P. 7216–7222, s.l. : Oncogene, 2001, Vol. 20.
All-Trans-Retinoic Acid Combined With Valproic Acid Can Promote Differentiation in Myeloid Leukemia Cells by an Autophagy Dependent Mechanism. Benjamin DN, O'Donovan TR, Laursen KB, et al. 848517, s.l. : Front Oncol., 2022, Vol. 12.
Cancer stem cells and differentiation therapy. Jin X, Jin X, Kim H. 10, s.l. : Tumor Biology, 2017, Vol. 39.
All-trans-retinoic acid treatment and retinoic acid receptor alpha gene rearrangement in acute promyelocytic leukemia: a model for differentiation therapy. Degos, L. 2, s.l. : nternational journal of cell cloning, 1992, Vol. 10.
p53 mutations in cancer. Muller, P., Vousden, K. s.l. : Nat Cell Biol, 2013, Vol. 15.