[Preneoplastic lesions of pulmonary carcinoma]. / Vorläuferläsionen des Lungenkarzinoms.

The World Health Organization (WHO) 2004 classification includes 3 categories of pulmonary preneoplastic lesions, including squamous dysplasia and carcinoma in situ (CIS) for squamous cell carcinoma, atypical adenomatous hyperplasia (AAH) for the majority of adenocarcinomas and diffuse idiopathic pulmonary neuroendocrine cell hyperplasia (DIPNECH) for carcinoids. The distinction of the 3 grades of squamous dysplasia and CIS is mainly based on the degree by which the basal cell zone is expanded, the degree of cellular atypia and the level of mitoses. The category AAH consists of a proliferation of atypical epithelial cells with Clara cells or type 2 pneumocyte features. They grow along the alveolar septae in a lepidic fashion, sometimes reaching into the terminal bronchioles. In contrast to the newly described adenocarcinoma in situ (AIS), AAH is smaller (≤ 5 mm), has a lower cell density and a lower degree of cellular atypia. The putative cancer stem cells of peripheral adenocarcinomas reside in the bronchioloalveolar duct junction, while those of central squamous cell carcinomas are located in the basal cell compartment of the bronchi. This review provides an overview of the current knowledge on preneoplastic lesions of the lungs and their clinical impact.

Localization of the invadopodia-related proteins actinin-1 and cortactin to matrix-contact-side cytoplasm of cancer cells in surgically resected lung adenocarcinomas.

OBJECTIVES: Actin-associated proteins at cell-matrix-contact sites form invadopodia in cancer cells and participate in migration, matrix degradation and invasion. We investigated an alteration of subcellular localization of invadopodia-related actin-associated proteins, actinin-1 and cortactin, in lung adenocarcinomas, its clinical significance, and its possible regulatory factors. METHODS: Invadopodia-related proteins, actinin-1 and cortactin, were immunohistochemically examined in 90 cases of lung adenocarcinomas. Expression of invadopodia-associated proteins and their possible regulators in lung adenocarcinomas were examined by real-time RT-PCR, database search, and immunohistochemistry. RESULTS: Actinin-1 and cortactin showed matrix-contact-side localization in adenocarcinoma cells, but rarely in normal bronchiolar epithelial cells, alveolar cells, or precursor lesion atypical adenomatous hyperplasia cells. Immunoelectron-microscopic examination of adenocarcinoma cells revealed actinin-1 localization to matrix-contact-side cytoplasm with cytoplasmic protrusions. Matrix-contact-side localization of actinin-1 and cortactin was correlated with tumor stages, lymph node metastasis, vascular permeation, and loss of basement membrane. The tumor-specific survival rate was worse for the group in which matrix-contact-side localization of cortactin was high than for the low group. mRNA of the Rho guanine exchange factor epithelial cell transforming sequence-2 (Ect2) tended to be overexpressed in lung adenocarcinomas and cytoplasmic expression of Ect2 tended to be correlated with matrix-contact-side localization of actinin-1. CONCLUSION: Matrix-contact-side localization of invadopodia-related proteins in the lung adenocarcinoma cells were correlated with invasion, metastasis, and poor prognosis. Ect2 was a possible regulator of matrix-contact-side localization of invadopodia-related proteins.

Epidermal growth factor receptor mutation and p53 overexpression during the multistage progression of small adenocarcinoma of the lung.

INTRODUCTION: A progression model of atypical adenomatous hyperplasia (AAH) to bronchioloalveolar carcinoma (BAC) to invasive adenocarcinoma (ADC) has been proposed. However, the genetic alterations of the AAH-BAC-ADC sequence are not clearly established. We examined the mutation of the epidermal growth factor receptor (EGFR) gene and p53 protein overexpression in the AAH, BAC, and small ADC to understand their role in the pulmonary ADC pathogenesis. METHODS: Twenty AAH, 43 BAC (21 Noguchi type A and 22 type B), and 47 small ADC (Noguchi type C) were enrolled in this study. EGFR mutations at exons 18-21 and p53 protein overexpression were examined by polymerase chain reaction-direct sequencing and immunohistochemistry, respectively. RESULTS: Mutations of the EGFR gene were noted in 45 (40.9%) lesions, which included 7 (35.0%) of AAH, 15 (34.9%) of BAC, and 23 (48.9%) of ADC. Twenty-six (23.6%) of the mutations were detected as exon 19 deletion, 18 (16.4%) as exon 21 point mutation, and 1 (0.9%) as exon 18 point mutation. Overexpression of p53 protein was found in 19 (17.2%) lesions, none of AAH, 4 (9.8%) of BAC, and 15 (31.9%) of ADC. Multivariate analysis showed that p53 overexpression was associated with invasive ADC (P = 0.003). CONCLUSIONS: High frequency and similar incidence of EGFR mutation in AAH, BAC, and ADC support that EGFR gene mutation occurs in the early stage of pulmonary ADC development and tumor initiation from the preneoplastic lung parenchyma to neoplastic conditions. On the contrary, p53 overexpression is a late event during tumor development and plays a role in the progression of the peripheral pulmonary ADC.

Sequential molecular changes during multistage pathogenesis of small peripheral adenocarcinomas of the lung.

INTRODUCTION: We investigated EGFR and KRAS alterations among atypical adenomatous hyperplasia and small lung adenocarcinomas with bronchioloalveolar features to understand their role during multistage pathogenesis. METHODS: Sixty lesions measuring 2 cm or less were studied, including 38 noninvasive lesions (4 atypical adenomatous hyperplasias, 19 Noguchi type A and 15 type B) and 22 invasive lesions (type C) based on the World Health Organization classification and Noguchi's criteria. EGFR and KRAS mutations were examined using PCR-based assays. EGFR copy number was evaluated using fluorescence in situ hybridization. RESULTS: EGFR and KRAS mutations were found in 26 (43.3%) and 5 (8.3%) lesions, respectively. Increased EGFR copy number status was identified in 10 lesions (16.7%), both mutant and wild type. EGFR or KRAS mutations were present in 39.5% and 7.9% (respectively) of noninvasive lesions and 50% or 9.1% (respectively) of invasive lesions. EGFR copy number was increased in 7.9% and 31.8% of noninvasive and invasive lesions (P = 0.029). Multivariate analysis revealed that increased EGFR copy number was the only significant factor to associate with invasive lesions (P = 0.035). CONCLUSIONS: EGFR and KRAS mutations occur early during the multistage pathogenesis of peripheral lung adenocarcinomas. By contrast, increased EGFR copy number is a late event during tumor development and plays a role in the progression of lung adenocarcinoma independent of the initiating molecular events.

Association of KRAS polymorphisms with risk for lung adenocarcinoma accompanied by atypical adenomatous hyperplasias.

The pulmonary adenoma susceptibility 1 (Pas1) gene affects susceptibility to the development of lung adenomas in mice with a subset of the adenomas progressing to adenocarcinoma (ADC). In this study, genotype distributions for 10 polymorphisms in the human counterparts for three mouse candidate Pas1 genes, KRAS, CASC1/LAS1 and LRMP, were examined in a hospital-based case-control study consisting of 364 lung ADC cases and 253 controls. All the ADC cases were subjected to lobectomy and subsequent pathological investigation of atypical adenomatous hyperplasia (AAH), a putative precursor for peripheral lung ADC, including bronchioloalveolar carcinoma, in the resected lobes. Eighty-one (22%) of the ADC cases carried at least one AAH lesion in addition to the primary ADC and 34 (9%) of them carried multiple AAH lesions. None of the 10 polymorphisms examined showed significant associations with overall lung ADC risk (P > 0.05). However, minor allele carriers for two polymorphisms in the KRAS gene, KRAS-1 and -6, showed significantly increased odds ratios (ORs) for ADC accompanied by multiple AAHs [OR = 3.0; 95% confidence interval (CI) = 1.4-6.2, P = 0.004 and OR = 2.4; 95% CI = 1.1-4.7, P = 0.02, respectively]. Minor haplotypes including the minor allele for the KRAS-6 polymorphism showed increased ORs for ADC accompanied by multiple AAHs, and KRAS transcripts from the minor allele for this polymorphism were more abundantly detected in lung tissues than those from the major allele. Thus, KRAS polymorphisms were indicated to be involved in risk for the development of AAHs that progress to ADC by causing differential KRAS oncogene expression in the lungs.

A subset of lung adenocarcinomas and atypical adenomatous hyperplasia-associated foci are genotypically related: an EGFR, HER2, and K-ras mutational analysis.

Atypical adenomatous hyperplasia (AAH) is considered the preinvasive lesion of pulmonary adenocarcinoma, and mutations of EGFR, HER2, and K-ras are involved in the early stage of lung adenocarcinoma carcinogenesis, also predicting clinical response to anti-EGFR small molecule inhibitors. We analyzed 18 cases of primary lung adenocarcinoma with concomitant AAH foci from 13 patients for mutations of EGFR (exons 18-21), HER2 (exons 19-20), and K-ras (exon 2) by direct sequencing polymerase chain reaction. Among mutated cases, concordant mutations of EGFR or K-ras in adenocarcinoma and related AAH were observed in 5 (63%) of 8 cases. In particular, 3 of 4 adenocarcinomas with EGFR mutations (all L858R point mutations in women, never or former smokers) had a concomitant and identical mutation in AAH, and 2 of 4 adenocarcinomas with K-ras mutations (both at codon 12 in women, a never and a current smoker) showed the same mutation in concomitant AAH. All cases were wild-type for HER2. Mutations of EGFR and K-ras genes represent an early event in lung adenocarcinomagenesis, and AAH convincingly seems to be a precursor lesion in a subset of cases of adenocarcinoma.

Epidermal growth factor receptor gene mutations in atypical adenomatous hyperplasias of the lung.

Activating epidermal growth factor receptor (EGFR) gene mutations are frequently detected in lung adenocarcinomas, especially adenocarcinomas with a nonmucinous bronchioloalveolar carcinoma component. EGFR-mutated lung adenocarcinomas respond well to EGFR tyrosine kinase inhibitors. We previously found that most (88%) pure nonmucinous bronchioloalveolar carcinomas (adenocarcinoma in situ) already harbor EGFR mutations, indicating that the mutations are an early genetic event in the pathogenesis. We examined 54 atypical adenomatous hyperplasias, precursor lesions of lung adenocarcinomas, obtained from 28 Japanese patients for the hotspot mutations of EGFR exons 19 and 21 and K-ras codon 12. EGFR mutations were observed in 17 of the 54 (32%) atypical adenomatous hyperplasias examined: Ten and seven atypical adenomatous hyperplasias had deletion mutations at exon 19 or point mutations (L858R) at exon 21, respectively. We did not observe apparent histological differences between atypical adenomatous hyperplasias with and without EGFR mutations. K-ras mutation (G12S) was detected in only one atypical adenomatous hyperplasia. As EGFR mutational frequency of atypical adenomatous hyperplasias was much lower than that of nonmucinous bronchioloalveolar carcinomas, we surmise that EGFR-mutated atypical adenomatous hyperplasias, but not atypical adenomatous hyperplasias with wild-type EGFR, are likely to progress to nonmucinous bronchioloalveolar carcinomas.

Mutation of the epidermal growth factor receptor gene in the development of adenocarcinoma of the lung.

Recently, a mutation of the epidermal growth factor receptor (EGFR) gene has been reported to be implicated in the development of pulmonary adenocarcinoma. However, the involvement of the mutation in atypical adenomatous hyperplasia (AAH) and multiple adenocarcinomas still remains unclear. We herein examined the EGFR mutations in 9 AAH and 31 adenocarcinoma lesions obtained from 30 Japanese patients. Nine patients had synchronous or metachronous multiple adenocarcinomas and/or AAH. Mutations in exons 18-21 of EGFR gene were analysed using polymerase chain reaction and direct sequence methods. EGFR mutations were detected in 4 (44%) of 9 AAH and in 7 (23%) of 31 adenocarcinomas. A gefitinib-resistant point mutation (T790M) in exon 20 without gefitinib treatment was detected in 1 AAH and 1 adenocarcinoma. The patient with T790M mutated AAH, which also had an exon 19 mutation of D761Y, had synchronous adenocarcinoma, which had only an exon 19 mutation of D761Y. The other exon 19 mutations were all in-frame deletions. In the two patients with synchronous AAH and adenocarcinoma, AAH had mutations at exon 19 although adenocarcinoma did not have any mutations. In the patient with synchronous 2 adenocarcinomas, each had different mutations (exons 19 and 21). In two patients with double adenocarcinomas, 1 adenocarcinoma harbored exon 21 mutations, while the other demonstrated no mutations. Although EGFR mutations appeared to be partially associated with the early steps of adenocarcinoma development, such mutations may possibly occur randomly even in multiple lesions in a single patient.

Molecular alterations in atypical adenomatous hyperplasia occurring in benign and cancer-bearing lungs.

Atypical adenomatous hyperplasia (AAH) is considered to be a precursor lesion of the lung adenocarcinoma. Several genetic abnormalities have been reported in AAH associated with adenocarcinoma, but little is known about AAH associated with benign lung lesions. To address this we compared the molecular characteristics of AAH present in benign conditions to those coexisting with carcinoma. Seven cases of AAH from resected non-neoplastic lungs (AAH-B) and 12 cases from lungs resected for primary lung carcinoma (AAH-M) were analyzed for loss of heterozygosity (LOH) using 21 polymorphic microsatellite markers situated in proximity to known tumor suppressor genes on chromosomes 3p, 5q, 7p, 9p, 10q, and 17p. Direct DNA sequencing for K-ras mutation was also performed. There was a broad range of LOH in both groups. No LOH was identified in 3 cases (25%) of AAH-M, but all cases of AAH-B showed LOH (P=0.26). Six cases (50%) of AAH-M and 3 cases (43%) of AAH-B showed loss at 1 marker (P=0.99). LOH at 2 or more markers was identified in 3 (25%) cases of AAH-M and 4 (57%) cases of AAH-B (P=0.32). LOH was most frequently detected on chromosomes 3p and 10q in both groups. The difference in overall fractional allelic loss between the 2 groups did not reach statistical significance. K-ras mutations were not identified in either group. Our results showed a significant overlap in LOH patterns between AAH with or without coexistent lung malignancy. Therefore, AAH may represent a smoking induced low-grade neoplastic lesion that may be a precursor lesion of only a subset of invasive lung adenocarcinoma.

Genetic relationship among atypical adenomatous hyperplasia, bronchioloalveolar carcinoma and adenocarcinoma of the lung.

Atypical adenomatous hyperplasia (AAH) has been recently defined by WHO as a small lesion, not exceeding 5mm in major axis, composed of slightly enlarged alveolar septa lined by pneumocytes with plump, atypical nuclei. AAH is frequently found in tissue surrounding lung adenocarcinoma and is considered a precursor of this subtype of lung cancer by many Authors. However, the genetic relationship between adenocarcinoma and the associated foci of AAH is not well defined. In particular, it is not clear whether multiple foci of AAH and of adenocarcinoma in the same patients are clonally related to each other or represent independent neoplastic foci. To clarify if AAH and the associated cancer are clonally related, we evaluated the genetic distance between these two lesions in 16 patients, using direct sequencing of mitochondrial DNA (D-loop region). Furthermore, LOH analysis for 7 microsatellites (D3S1478 at 3p21, D3S1300 at 3p14.2, D9S942 at 9p21, D5S346 at 5q21, D17S261 at 17p13.1, D18S46 at 18q21, D19S246 at 19q13.2) was also performed. Our results indicate that, in at least 9 out of 13 informative cases (69.2%), AAH and the associated cancer were not clonally related as they showed a different mutation pattern in the mitochondrial D-loop region. These findings were also in agreement with the LOH data which showed losses in different loci in at least three cases. On the contrary an identical LOH pattern between BAC and AAH was found in one case. Similar but not identical LOH pattern between AAH and related tumors was found in other three cases. Therefore, our results suggest that AAH and the associated cancer are genetically independent in agreement with the concept of cancerization field. Less frequently AAH foci could represent an early spread of cells from the main tumor, rather than a precursor lesion.

LAT1 expression in normal lung and in atypical adenomatous hyperplasia and adenocarcinoma of the lung.

No previous study has investigated neutral large amino acid transporter type 1 (LAT1) in normal lung cells, or in atypical adenomatous hyperplasia(s) (AAH) and nonmucinous bronchioloalveolar carcinoma(s) (NMBAC) of the lung. The authors examined: (1) the levels of LAT1 mRNA/glyceraldehyde-3-phosphate dehydrogenase (GAPDH) mRNA in 41 normal lung tissues and 34 NMBAC using semiquantitative reverse transcription-polymerase chain reaction; (2) LAT1 mRNA and protein expressions in 35 normal lung tissues, 34 AAH (11 lesions were interpreted as low-grade AAH and 23 as high-grade AAH), and 43 NMBAC using in situ hybridization and immunohistochemistry; and (2) the association of the incidences of LAT1 mRNA and protein expressions with cell proliferation in these lesions. The level of LAT1 mRNA/GAPDH mRNA (1) tended to be higher in NMBAC (12.0+/-8.1) than in normal lung tissues (1.0+/-0.2), and (2) covered a much wider range (from 0 to 276) in NMBAC than in normal lung tissues (from 0 to 5.8), with six NMBAC having values higher than 7.0, while 5.8 was the highest value detected in normal lung tissues. In peripheral normal lung tissues, LAT1 mRNA and protein were detected in bronchial surface epithelial cells and alveolar macrophages (but not in nonciliated bronchiolar epithelial cells, or in alveolar type I or type II cells). In bronchial surface epithelial cells, LAT1 protein appeared to be of a nodular type, which was considered to be a nonfunctional protein pattern. The incidences of positive expressions for LAT1 mRNA and protein were 54.5 and 27.3% in low-grade AAH, 65.2 and 52.2% in high-grade AAH, and 65.1 and 79.1% in NMBAC, respectively. In the case of LAT1 protein expression, significant differences could be shown between total (low-grade plus high-grade) AAH and NMBAC, and between low-grade AAH and NMBAC. Thus, in terms of the incidence of LAT1 protein expression, high-grade AAH appeared intermediate between low-grade AAH and NMBAC. The Ki-67 labeling index (a cell proliferation score) was significantly higher in those AAH and NMBAC that were LTA1-protein-positive than in their LAT1-protein-negative counterparts. In conclusion, LAT1 expression may increase with the upregulation of metabolic activity and cell proliferation in high-grade AAH and NMBAC.

A case of multiple atypical adenomatous hyperplasia of the lung detected by computed tomography.

Multiple atypical adenomatous hyperplasia (AAH) of both lungs in a 72-year-old male, detected by computed tomography, is reported. The lesions of the right lung were resected for diagnosis via video-assisted thoracoscopic surgery (VATS). The resected specimen had 22 AAH lesions up to 10 mm in size. For nine of these lesions, the expressions of carcinoembryonic antigen (CEA), c-erbB-2 oncoprotein and p53 gene product were examined by immunohistochemistry and the loss of heterozygosity (LOH) on chromosomes was investigated by polymerase chain reaction analysis. These lesions showed a variety of expressions for CEA, c-erbB-2 and p53 oncoprotein. Three of the nine lesions showed LOH on chromosome 13q, although this was not exhibited in the largest one. These results indicate that each AAH in this case has independent genetic abnormalities and is multicentric.

Fine chromosomal localization of the mouse Par2 gene that confers resistance against urethane-induction of pulmonary adenomas.

BALB/cByJ mice are 14 times more resistant to urethane-induction of pulmonary adenomas than the susceptible A/J strain. Our previous linkage analysis of (A/J x BALB/cByJ)F1 x A/J backcross mice provided statistical evidence that a major resistance locus of BALB/cByJ with a dominant effect, designated Par2 (Pulmonary adenoma resistance 2), exists within an approximately 25 cM section of distal chromosome 18. To facilitate molecular identification of the Par2 locus, the present study was conducted to finely localize its chromosomal position utilizing Par2-congenic mice. Male BALB/cByJ mice were mated with female C57BL/6J mice carrying recessive Par2 alleles and their male F1 progeny were backcrossed to female BALB/cByJ mice. A male backcross mouse heterozygous within the Par2 interval of 25 cM was randomly selected and again backcrossed to female BALB/cByJ mice. This backcross-selection cycle was simply repeated to produce semi-congenic mice with a general BALB/cByJ genetic background except for the Par2 interval, where the mice were heterozygous with paternal C57BL/6J alleles and maternal BALB/cByJ alleles. After the 6th or 7th backcross, nine male mice possessing a recombination within the paternal Par2 interval were retained and crossed to female A/J mice. Resultant progeny were treated with urethane and examined for lung tumor development in order to deduce the Par2 genotypes of the recombinants through linkage analysis. By comparing the deduced Par2 genotype of each recombinant with its recombinational breakpoint, the Par2 locus was confined to an approximately 0.5 cM region flanked by D18Mit103 and D18Mit188 loci. Our results indicate that fully congenic mice conventionally established by at least nine simple backcrosses or by the speed congenic method are not necessarily required for fine mapping of quantitative trait loci. In the case of the Par2 locus, we found that semi-congenic mice after as few as four simple backcrosses were useful for this purpose. The map information obtained in this study should enable subsequent positional cloning of the Par2 gene.

Atypical adenomatous hyperplasia of the lung: a probable forerunner in the development of adenocarcinoma of the lung.

An increasingly large body of work suggests that atypical adenomatous hyperplasia (AAH) of the lung may be a forerunner of pulmonary adenocarcinoma. Recognizing this fact, the World Health Organization now acknowledges the existence of AAH while noting difficulties that may be encountered in distinguishing AAH from the nonmucinous variant of bronchioloalveolar carcinoma. Regrettably, a universally acceptable definition of morphologic criteria for the diagnosis of AAH has not been achieved. This review of the literature examines the epidemiology, gross appearance, light microscopic findings, morphometry, immunohistochemistry, and molecular features of AAH and suggests a set of histopathologic features that may help the practicing pathologist identify this intriguing lesion. These features include the following: irregularly bordered focal proliferations of atypical cells spreading along the preexisting alveolar framework; prominent cuboidal to low columnar alveolar epithelial cells with variable degree of atypia but less than that seen in adenocarcinoma; increased cell size and nuclear-cytoplasmic ratio with hyperchromasia and prominent nucleoli, generally intact intercellular attachment of atypical cells with occasional empty-looking spaces between them without high cellularity and without tufting or papillary structures; and slight thickening of the alveolar walls on which the AAH cells have spread, with some fibrosis but without scar formation or significant chronic inflammation of the surrounding lung tissue. Several lines of evidence indicate that AAH is a lesion closely associated with adenocarcinoma of the lung, suggesting AAH may be involved in the early stage of a complex multistep carcinogenesis of pulmonary adenocarcinoma.