Mutational Analysis of PUMA Gene in Non-small Cell Lung Cancers

Nam Jin Yoo; Jong Woo Lee; Sung Hak Lee; Sug Hyung Lee

doi:10.6058/jlc.2006.5.2.92

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Yoo, Lee, Lee, and Lee: Mutational Analysis of PUMA Gene in Non-small Cell Lung Cancers

Original Article

J Lung Cancer 2006;5(2):92-95.

Published online: 18 December 2006

DOI: https://doi.org/10.6058/jlc.2006.5.2.92

Mutational Analysis of PUMA Gene in Non-small Cell Lung Cancers

Nam Jin Yoo, M.D., Jong Woo Lee, M.S., Sung Hak Lee, M.D., Sug Hyung Lee, M.D.

¹Dartment of Patholoqv. Colleae of Medicine. The Catholic University of Korea, Seoul, Korea

Address for correspondence Sug Hyuna Lee, MD. DeDartment of Patholoqv. Colleae of Medicine. The Catholic University of Korea. 505. Banoo-dong, Seochogu, Seoul 137-701. Korea Tel: 82-2-590-1188 Fax; 82-2-537-6586 E-mail; suhulee@catholio.aakr

Received 10 November 2006 Accepted 1 December 2006

This is an Open Access article distributed under the terms of the Creative Commons Attribution Non-Commercial License (http://creativecommons.org/licenses/by-nc/3.0) which permits unrestricted non-commercial use, distribution, and reproduction in any medium, provided the original work is properly cited.

Abstract

Purpose:

It has become clear that, together with proliferation, deregulation of apoptosis plays a pivotal role in tumorigenesis, and the somatic mutations of apoptosis-related genes have been reported in human cancers. PUMA, a proapoptotic member of Bcl-2 family, mediates p53-deependent and -independent apoptosis. The aim of this study was to explore whether alteration of PUMA protein expression is a characteristic of human lung cancers.

Materials and Methods:

To explore the possibility that the genetic alterations of PUMA might be involved in the development of human cancers, we analyzed the entire coding region and all splice sites of human PUMA gene in 100 human non-small cell lung cancers (NSCLCs) by polymerase chain reaction (PCR)-based single-strand conformation polymorphism (SSCP),

Results:

The PCR-SSCP analysis detected no mutation in the entire coding regions and all splice sites of human PUMA gene in the 100 NSCLCs.

Conclusion:

The data presented here suggested that PUMA gene mutation may not contribute to the pathogenesis of human NSCLCs. (J Lung Cancer 2006;5{2):92-95)

Keywords: Non-small cell lung cancer, PUMA, Apoptosis, Mutation

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Fig. 1

Representative SSCP of PUMA gene in the non-small cell lung cancers. The exon 2 of the PUMA oene were amplified by PCR using a specific primer set. The PCR products from the representative cases of non-small cell lung cancers were visualized on SSCP. SSCP of DNA from the non-small cell lung cancers (T) shows no aberrant bands as compared to SSCPs from the normal tissues (N),

Table 1.

Sequences of PCR Primer Sets for PUMA Gene Amplification

Pimers	Exon	Sequence	Annealing Tm(°C)	Size (bp)
2A	1	F 5’-CTGGTACTTCCCTGCTGACC-3’	58	172
		R 5’-AGAGGCCGCAGGACACTG-3’
2B	1	F 5’-CTGCCCGCTGCCTACCTCT-3’	66	195
		R 5’-CTTCCCGGCTCCTATCACCC-3’
3	2	F 5’-GGCGGAGCAGCACCTGGAGTCG-3’	56	187
		R 5’-TCCCACCTGCCGTCTACCCCACC-3’
4	2	F 5’-CTCAGTCCCCTGCTAACTGC-3’	56	187
		R 5’-CGAGTCCCTGACGTCCAC-3’

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