Authenticated Lung Cancer Cell Lines for Cancer Research

Lung cancer is the leading cause of cancer-related death. Patients are frequently diagnosed at an advanced stage due to a relative lack of clinical symptoms. Lung cancer accounts for 13.2% of all new cancers and 25.9% of all cancer deaths each year. The overall five-year survival rate of lung cancer is lowest (18.1%) when compared to most other cancers¹, but prognosis varies dramatically with pathological classification, disease stage, and patient demographics such as gender and age at diagnosis.

Types of lung cancer

The pathological classification of lung cancer is evolving. It is currently histopathologically classified into small-cell lung cancer (SCLC) and non-small-cell lung cancer (NSCLC)—which includes squamous cell carcinoma and adenocarcinoma.  NSCLC, sometimes referred to as large cell lung carcinoma, accounts for the majority (85%) of lung cancer diagnoses.

NSCLC (Frequency: 85%)	SCLC (Frequency: 15%)
Squamous cell carcinoma Arises from the proximal airway; more closely correlated with smoking than other NSCLC Origin: Bronchial epithelium cells that line airways Adenocarcinomas Arise from the distal airway; dominant subtype in nonsmoking patients Origin: mucus-producing glands and cells	Small-cell lung cancer Arises from neuroendocrine cells due to heavy carcinogen exposure. Origin: Tracheal basal cell progenitors, pulmonary neuroendocrine cells2
Cell lines: PC9, LO68, LUDLU-1, COR-L105, SKLU1, SKMES1, NCI-H727, LC-2/AD, NCIH358, ChaGo-K-1, MOR/CPR, MOR/0.4R, MOR/0.2R, NCIH-322	Cell lines: H69, H69V, CORL-47, COR-L51, COR-L88, DMS53, DMS79, DMS454, COR-L311, COR L303, COR-L95, NCI-H69/CPR, NCI-H69/LX4, NCI-H69/LX10 , NCI-H69/LX20, SHP-77, NCI-H510A, DMS92, DMS153, COR-L279, DMS 273

Risk factors

The incidence of lung cancer is declining in developed countries, due in part to smoking education and regulation. Incidence rates are rising, however, in less developed countries. That 80% of men and 50% of women with lung cancer are smokers demonstrates smoking as the lifestyle risk factor. Environmental risk factors include passive smoke exposure, air pollution, and other sources of particulate inhalation.

Mutations

Genetic predisposition amplifies the risk of lung cancer, and lung adenocarcinoma is more associated than other histotypes with genetic factors. The most frequently reported somatic mutations in lung cancer are in the genes for TP53, LRP1B, KRAS, KEAP1, KMT2C, FAT4, CDKN2A, EGFR, and FAT2.

Select cell lines from the table below based on mutation, and click on genes to find relevant products (antibodies, shRNA, siRNA, primers, CRISPR plasmids) for your research application.

Table 1. Lung cancer cell lines with specific mutations

Mutated gene	Cell lines
TP53	PC9, NCIH-322, LC-2/AD, DMS 273, NCI-H69/CPR, COR-L279, NCI-H727, SHP-77, DMS153, LUDLU-1
LRP1B	NCIH-322, DMS 273, CALU 1, COR-L279, NCI-H727, SHP-77, DMS153, CORL-47, DMS 79, DMS 454
KRAS	A549, CALU 1, CORL23, NCI-H727, SHP-77, SKLU1, MOR/CPR, NCIH358
KEAP1	A549, SHP-77, LUDLU-1, MOR/CPR, DMS 454
KMT2C	A549, CORL23, COR-L47, SKLU1, COR-L105, DMS 454, SKMES1, NCIH358
FAT4	A549, NCI-H727, COR-L47, ChaGo-K-1
CDKN2A	PC9, CORL23
EGFR	PC9, SK MES 1
FAT2	NCI-H358

Small molecules/monoclonal antibodies

Small molecule compounds and antibodies can be used to target specific cancer cells and block tumor growth and progression. The most common drugs used to target lung cancer include:

• Cisplatin
• Docetaxel
• Gemcitabine
• Paclitaxel
• Vinorelbine

Applications

Cancer cell lines have been at the heart of cancer research, and provide an accessible, cost-effective model for cellular behavior and response. Based on the characteristics of the cell line and experimental need, cell lines may be used in one or more applications. Some examples of application-specific use for cell lines associated with lung cancer are included below.

Application	Cell line used
Drug response studies	PC-9, a lung adenocarcinoma cell line employed to study effects of small molecule inhibitors
Target identification/validation	A549, a cell line model of NSCLC used to evaluate the role of CCL22 and IL-37 in epithelial-mesenchymal transition3
Toxicology studies	Cellular toxicity of carbon-based nanomaterials was tested in CALU-1 and other lung cancer cell lines4
Growth factor signaling	NCI-H292 (human airway epithelium cells) were employed to study the role of cigarette smoking in the pathogenesis of COPD5
Metastasis studies	Human small cell lung cancer cell line DMS273 was used as a model to study metastasis6
Xenograft models	Effect of ganetespib/erlotinib therapy was evaluated in non-small cell lung cancer (NCI-H322) xenograft tumors7
In vitro models	BEAS-2B cell lines derived from human bronchial epithelial cells were used as in vitro models to study carcinogenesis of heavy metals8
miRNA regulation studies	The biological role of miR-223 was investigated in PC-9  cell line9

ECACC Lung Cancer Cell Lines

Product No.	Cell Name	Cell Line Origin
86012804	A549	Human Caucasian lung carcinoma
10092305	AB1	Mouse malignant mesothelioma
10092306	AB12	Mouse malignant mesothelioma
10092307	AB22	Mouse malignant mesothelioma
10092308	AC29	Mouse malignant mesothelioma
10092310	AE17	Mouse malignant mesothelioma
6032203	BICR 3	Alveolus squamous cell carcinoma
4072111	BICR 78	Oral alveolus squamous carcinoma
93120818	CALU 1	Human Caucasian lung epidermoid carcinoma
96020948	ChaGo-K-1	Human lung bronchus carcinoma
10032301	CMT 64	Mouse lung carcinoma; metastasis
86082105	CMT64/61	Mouse C57BL/1CRF lung carcinoma
10032302	CMT 167 (clone of CMT 64)	Mouse lung carcinoma; metastasis
87061209	COLO 668	Human lung oat cell carcinoma
96042336	COR-L 23/CPR	Human Caucasian lung, large cell carcinoma
92031919	COR-L23	Human Caucasian lung large cell carcinoma
96042338	COR-L23/5010	Human Caucasian lung, large cell carcinoma, drug resistant
96042339	COR-L23/R	Human Caucasian lung large cell carcinoma
96020740	COR-L26	Human large cell lung cancer bone marrow aspirate
92031918	COR-L105	Human Caucasian lung adenocarcinoma
96020724	COR-L279	Human lung small cell carcinoma
96020722	COR-L303	Human lung small cell carcinoma
96020721	COR-L311	Human lung small cell carcinoma
92031915	COR-L47	Human Caucasian small cell lung carcinoma
92031916	COR-L51	Human Caucasian lung carcinoma
92031917	COR-L88	Human Caucasian lung small cell carcinoma
96020733	COR-L95	Human lung small cell carcinoma
95062823	DMS 53	Human Caucasian lung small cell carcinoma
95062824	DMS 79	Human lung small cell carcinoma
95062825	DMS 92	Human Caucasian lung small cell carcinoma, metastasis to bone marrow
95062827	DMS 153	Human Caucasian lung small cell carcinoma, metastasis to liver
95062830	DMS 273	Human lung, small cell carcinoma
95062832	DMS 454	Human Caucasian lung, small cell carcinoma
6092006	H400	Human oral squamous cell carcinoma, alveolar process
91091802	H69	Human Caucasian lung small cell carcinoma
91091803	H69V	Human lung small cell carcinoma
10092309	JU77	Human malignant mesothelioma
90040512	LA-4	Mouse A/He lung adenoma
94072247	LC-2/ad	Human lung adenocarcinoma
90020104	LL/2(LLc1)	Mouse C57BL Lewis lung carcinoma
10092311	LO68	Human malignant mesothelioma
92012463	LUDLU-1	Human Caucasian lung squamous cell carcinoma
90062272	Meta 7	Mouse TS/A lung metastases
90062271	Meta 10	Mouse TS/A lung metastases
90062270	Meta 15	Mouse TS/A lung metastases
86020603	MiCL1 (S+L-)	Mink lung, Moloney murine sarcoma virus infected
84112312	MOR	Human lung adenocarcinoma
96042335	MOR/0.2R	Human lung adenocarcinoma, drug-resistant
96042334	MOR/0.4R	Human lung adenocarcinoma, drug-resistant
96042328	NCI-H69/CPR	Human small cell lung cancer, drug-resistant
96042331	NCI-H69/LX10	Human small cell lung cancer, drug-resistant
96042332	NCI-H69/LX20	Human Caucasian small cell lung carcinoma
96042329	NCI-H69/LX4	Human Caucasian small cell lung carcinoma, drug-resistant
96042330	NCI-H69VCR/R	Human small cell lung cancer, drug-resistant
96042333	MOR/CPR	Human lung adenocarcinoma, drug-resistant
91091815	NCI-H292	Human lung, mucoepidermoid carcinoma
95111734	NCI-H322	Human Caucasian bronchioalveolar carcinoma
95111733	NCI-H358	Human Caucasian bronchioalveolar carcinoma
96020944	NCI-H510A	Human lung carcinoma, adrenal gland metastasis
94060303	NCI-H727	Human lung non-small cell carcinoma
90071810	PC-14	Human adenocarcinoma, differentiated
98110201	SHP-77	Human Caucasian lung small cell carcinoma, large cell variant
93120835	SK LU 1	Human Caucasian lung adenocarcinoma
93120837	SK MES 1	Human Caucasian lung squamous carcinoma
85011440	U937	Human Caucasian histiocytic lymphoma
87020406	V79-HG04	Hamster Chinese embyro lung fibroblast transformed

References

1. Cancer Stat Facts: Lung and Bronchus Cancer. [Internet]. Available from: https://seer.cancer.gov/statfacts/html/lungb.

2. Onaitis M, Hanna J. 2013. Cell of origin of lung cancer. J Carcinog. 12(1):6. https://doi.org/10.4103/1477-3163.109033

3. Chen Y, Zhou B, Wu X, Xu J, Zhang J, Chen Y, Liang S. 2016. CCL22 and IL-37 inhibit the proliferation and epithelial-mesenchymal transition process of NSCLC A549 cells. 36(4):2017-2024. https://doi.org/10.3892/or.2016.4995

4. Magrez A, Kasas S, Salicio V, Pasquier N, Seo JW, Celio M, Catsicas S, Schwaller B, Forró L. 2006. Cellular Toxicity of Carbon-Based Nanomaterials. Nano Lett.. 6(6):1121-1125. https://doi.org/10.1021/nl060162e

5. Shao MXG, Nakanaga T, Nadel JA. 2004. Cigarette smoke induces MUC5AC mucin overproduction via tumor necrosis factor-?-converting enzyme in human airway epithelial (NCI-H292) cells. American Journal of Physiology-Lung Cellular and Molecular Physiology. 287(2):L420-L427. https://doi.org/10.1152/ajplung.00019.2004

6. Sakamoto S, Inoue H, Ohba S, Kohda Y, Usami I, Masuda T, Kawada M, Nomoto A. 2015. New metastatic model of human small?cell lung cancer by orthotopic transplantation in mice. Cancer Sci. 106(4):367-374. https://doi.org/10.1111/cas.12624

7. Smith DL, Acquaviva J, Sequeira M, Jimenez J, Zhang C, Sang J, Bates RC, Proia DA. 2015. The HSP90 inhibitor ganetespib potentiates the antitumor activity of EGFR tyrosine kinase inhibition in mutant and wild-type non-small cell lung cancer. Targ Oncol. 10(2):235-245. https://doi.org/10.1007/s11523-014-0329-6

8. Park Y, Kim D, Dai J, Zhang Z. 2015. Human bronchial epithelial BEAS-2B cells, an appropriate in vitro model to study heavy metals induced carcinogenesis. Toxicology and Applied Pharmacology. 287(3):240-245. https://doi.org/10.1016/j.taap.2015.06.008

9. ZHAO F, HAN J, CHEN X, WANG J, WANG X, SUN J, CHEN Z. 2016. miR-223 enhances the sensitivity of non-small cell lung cancer cells to erlotinib by targeting the insulin-like growth factor-1 receptor. 38(1):183-191. https://doi.org/10.3892/ijmm.2016.2588