Inamura Kentaro, Ninomiya Hironori, Nomura Kimie, Tsuchiya Eiju, Satoh Yukitoshi, Okumura Sakae, Nakagawa Ken, Takata Ayako, Kohyama Norihiko, Ishikawa Yuichi
Division of Pathology, The Cancer Institute, Japanese Foundation for Cancer Research (JFCR), Koto-ku, Tokyo 135‑8550, Japan.
Department of Thoracic Surgery, Kitasato University School of Medicine, Sagamihara, Kanagawa 228‑8555, Japan.
Oncol Rep. 2014 Aug;32(2):475-82. doi: 10.3892/or.2014.3263. Epub 2014 Jun 13.
The carcinogens in cigarette smoke are distinct from asbestos. However, an understanding of their differential effects on lung adenocarcinoma development remains elusive. We investigated loss of heterozygosity (LOH) and the p53 mutation in 132 lung adenocarcinomas, for which asbestos body burden (AB; in numbers per gram of dry lung) was measured using adjacent normal lung. All cases were classified into 9 groups based on a matrix of cumulative smoking (CS in pack‑years; CS=0, 0<CS<25, ≥25 CS) and AB (AB=0, 0<AB<1,000, ≥1,000 AB). AB=0 indicates a lower level than the detection limit of ~100. LOH frequency increased only slightly with the elevation of CS in the AB=0 groups. In the AB>0 groups, LOH frequency increased as AB and/or CS was elevated and was significantly higher in the ≥1,000 AB, ≥25 CS group (p=0.032). p53 mutation frequency was the lowest in the AB=0, CS=0 group, increased as AB and/or CS rose, and was significantly higher in the ≥1,000 AB, ≥25 CS group (p=0.039). p53 mutations characteristic of smoking were frequently observed in the CS>0 groups contrary to non-specific mutations in the CS=0, AB>0 groups. Combined effects of asbestos and smoking were suggested by LOH and p53 analyses. Sole exposure to asbestos did not increase LOH frequency but increased non‑specific p53 mutations. These findings indicate that the major carcinogenic mechanism of asbestos may be tumor promotion, acting in an additive or synergistic manner, contributing to the genotoxic effect of smoking. Since this study was based on a general cancer center's experience, the limited sample size did not permit the consideration that the result was conclusive. Further investigation with a large sample size is needed to establish the mechanism of asbestos-induced lung carcinogenesis.
香烟烟雾中的致癌物与石棉不同。然而,对于它们对肺腺癌发展的不同影响仍缺乏了解。我们调查了132例肺腺癌中的杂合性缺失(LOH)和p53突变情况,同时使用相邻的正常肺组织测量了石棉小体负荷(AB;每克干肺中的数量)。所有病例根据累积吸烟量(CS,以包年计;CS = 0、0 < CS < 25、≥25 CS)和AB(AB = 0、0 < AB < 1000、≥1000 AB)的矩阵分为9组。AB = 0表示低于约100的检测限。在AB = 0组中,LOH频率仅随CS的升高略有增加。在AB>0组中,LOH频率随着AB和/或CS的升高而增加,并且在≥1000 AB、≥25 CS组中显著更高(p = 0.032)。p53突变频率在AB = 0、CS = 0组中最低,随着AB和/或CS的升高而增加,并且在≥1000 AB、≥25 CS组中显著更高(p = 0.039)。与CS = 0、AB>0组中的非特异性突变相反,在CS>0组中经常观察到吸烟特征性的p53突变。LOH和p53分析提示了石棉和吸烟的联合作用。单独接触石棉不会增加LOH频率,但会增加非特异性p53突变。这些发现表明,石棉的主要致癌机制可能是肿瘤促进作用,以相加或协同的方式起作用,有助于吸烟的遗传毒性作用。由于本研究基于一个普通癌症中心的经验,样本量有限,因此不能认为结果具有决定性。需要进一步进行大样本量研究以确定石棉诱导肺癌发生的机制。
