The P16/cyclin D1/Rb pathway in neuroendocrine tumors of the lung

Rb protein in its hypophosphorylated form acts as a cell cycle regulator for G1 arrest. Both cyclin D1 overexpression and P16(INK4) loss of protein produce persistent hyperphosphorylation of Rb with resultant evasion of cell cycle arrest. To better establish the mechanisms of loss of Rb function in neuroendocrine lung tumors, we performed an immunohistochemical analysis of the P16(INK4)/cyclin D1/Rb pathway in the spectrum of neuroendocrine tumors, including 34 typical carcinoids (TCs), 25 atypical carcinoids (ACs), 42 large cell neuroendocrine carcinomas (LCNECs), and 79 small cell lung carcinomas (SCLCs). Absence of Rb expression was not observed in TCs but was seen in 21% of ACs, 68% of LCNECs, and 87% of SCLCs. P16 was expressed in 91% of TCs, 77% of ACs, 78% of LCNECs, and 93% of SCLCs. Cyclin D1 was overexpressed in 6% of TCs, 20% of ACs, 9.5% of LCNECs, and 1.3% of SCLCs. There was an inverse relationship between Rb and P16 in high-grade tumors (P < 0.001) and a direct relationship between cyclin D1 and Rb (P < 0.001) in all tumors, demonstrating that P16 and cyclin D1 act exclusively on the Rb pathway for cell cycle regulation. Overall, the Rb pathway (Rb/P16(INK4)/cyclin D1) was altered more frequently in ACs than in TCs (P = 0.001) and more frequently in LCNECs than in ACs (P = 0.001). Although Rb-negative tumors had shorter survival in the overall group (P < 0.001) as a result of lack of Rb in most SCLCs, cyclin D1 overexpression and P16 loss did not influence survival in any individual category. We conclude that Rb pathway of G1 arrest is consistently compromised in high-grade neuroendocrine lung tumors (92%), primarily through loss of Rb protein, and is intact in low-grade TCs. In ACs an intermediate level of alterations (59%) is seen, consistent with their less-aggressive behavior compared with high-grade tumors. The specific profile of the Rb pathway parameters might provide specific therapeutic targets in neuroendocrine lung tumors.     

Using the mitosis-specific marker anti-phosphohistone H3 to assess mitosis in pulmonary neuroendocrine carcinomas

Counting mitotic figures (MFs) is one of the essential factors for determining the histologic grade of pulmonary neuroendocrine carcinoma (NEC). We analyzed MFs by using a mitotic-specific antibody of phosphohistone H3 (PHH3) in 113 lung NECs (66 typical carcinoids [TCs], 12 atypical carcinoids [ACs], 20 large cell NECs [LCNECs], and 15 small cell lung carcinomas [SCLCs]). Subdivided by histologic subtype, the mean PHH3-stained MFs (mPHMFs) were 0.09 per high-power field (hpf) in TCs, 0.39/hpf in ACs, 7.84/hpf in LCNECs, and 9.42 in SCLCs. From the 5-year overall survival rate for mPHMFs, an mPHMF of more than 1.0 was the best threshold in all NECs and an mPHMF of more than 0.4 was the best threshold for differentiating ACs from TCs. These values correspond to 4/10 hpf and 10/10 hpf. We showed that the PHH3-based mitosis-counting method is a reliable, easy method for counting mitoses in pulmonary NECs.     

Coexpression of c-kit and bcl-2 in small cell carcinoma and large cell neuroendocrine carcinoma of the lung.

It has been shown that tyrosine kinase oncoprotein c-kit and antiapoptotic molecule bcl-2 are overexpressed in several types of malignancy, including small cell carcinoma (SCLC) and large cell neuroendocrine carcinoma (LCNEC) of the lung. Whether these 2 molecules are coexpressed in lung neuroendocrine tumors has not been investigated. Here, we analyzed immunohistochemical results to determine expression and coexpression patterns of c-kit and bcl-2 in the spectrum of lung neuroendocrine tumors. Using a polyclonal antibody against c-kit and a monoclonal antibody against bcl-2, our data demonstrated that all 7 cases (100%) of SCLC included in this study were positive for both c-kit and bcl-2. Among 14 LCNECs, 7 (50%) stained positive for c-kit and 9 (64%) for bcl-2. All cases of high grade neuroendocrine carcinomas (SCLCs and LCNECs) that showed positive staining for c-kit coexpressed bcl-2. In contrast, all typical and atypical carcinoids (TC and AC) were negative for c-kit, and only 1 of 16 (6.3%) TCs and 1 of 6 (16.7%) ACs stained positive for bcl-2. These results indicate a progressive increase in the frequency of c-kit and bcl-2 expression and coexpression, from carcinoid tumors (TC and AC) to LCNEC and to SCLC. High grade neuroendocrine carcinomas are more likely to coexpress c-kit and bcl-2 when compared with carcinoid tumors. The high frequency of coexpression of these 2 molecules in high grade neuroendocrine carcinomas of the lung suggests that they may be involved in the carcinogenic pathway, given their important roles in carcinogenesis. Therapeutic targeting on both c-kit and bcl-2 molecules might be beneficial in the management of patients with high grade neuroendocrine carcinomas of the lung in the future.     

PAX-5 expression in pulmonary neuroendocrine neoplasms: its usefulness in surgical and fine-needle aspiration biopsy specimens

The World Health Organization classification of lung tumors recognizes 4 histologic subtypes of pulmonary neuroendocrine carcinomas (NECs), which include typical carcinoids (TCs), atypical carcinoids (ACs), small cell carcinomas (SCCs), and large cell NECs (LCNECs). These tumors can be misclassified owing to morphologic parallels, indicating the necessity for adjunctive tests for correct classification. We evaluated immunohistochemical expression of PAX-5 in histologic and fine-needle aspiration (FNA) specimens of pulmonary NECs. Staining was stratified by intensity (0 to 3+) and percentage of cells stained as focal (<10%) or diffuse (=10%). PAX-5 expression was present in 29/37 (78%) of high-grade NECs (22/26 SCCs, 1/2 LCNECs, and 6/9 combined tumors) and none of 51 TCs and ACs; FNA specimens showed concordant staining. This study confirmed that PAX-5 is a useful marker in FNA and surgical specimens for the discrimination of low- to intermediate-grade NECs from high-grade NECs with 100% specificity and 79% sensitivity in surgical specimens.     

The frequency of neuroendocrine cell hyperplasia in patients with pulmonary neuroendocrine tumours and non-neuroendocrine cell carcinomas

Aims:  To evaluate the frequency of neuroendocrine cell hyperplasia (NEH) in resected neuroendocrine tumours and non-neuroendocrine cell carcinomas and to study its relationship to selected clinical parameters.
Methods and results:  Random blocks without tumour from resected typical carcinoids (TCs, n  = 46), atypical carcinoids (ACs, n  = 14), large cell neuroendocrine carcinomas (LCNECs, n  = 18), small cell carcinomas (SCLCs, n  = 22), adenocarcinomas (ADENOs, n  = 26) and squamous cell carcinomas (SCCs, n  = 18) were stained for CD56 and evaluated for linear proliferations, cell aggregates (>4 CD56+ cells), and tumourlets (<5 mm with basement membrane invasion). There was a statistically significant difference between the frequency of NEH in all neuroendocrine tumours (TC/AC/LCNEC/SCLC, 35/100, 35%) ( P  = 0.009) when compared with non-neuroendocrine carcinomas (ADENO/SCC, 6/44, 14%) and in the frequency of NEH in TC (21/46, 46%) versus all other tumours (AC/LCNEC/SCLC/SCC/ADENO, 20/98, 20%) ( P  = 0.001). There was increased frequency of NEH in peripheral TCs (8/13, 62%) compared with central TCs (14/33, 43%) ( P  = 0.33). There was no association between smoking history and NEH. Clinical and imaging data showed no evidence of an increased frequency of obliterative bronchiolitis in patients with NEH.
Conclusions:  NEH is significantly increased in the background lung of neuroendocrine tumours when compared with non-neuroendocrine carcinomas, supportive data for NEH having neoplastic potential.     

Analysis of p53, K-ras-2, and C-raf-1 in pulmonary neuroendocrine tumors. Correlation with histological subtype and clinical outcome.

Neuroendocrine tumors of lung, including typical carcinoid (TC), atypical carcinoid (AC), large cell neuroendocrine carcinoma (LCNEC), and small cell lung carcinoma (SCLC) constitute a spectrum of malignancies in which the pathologist at times has difficulty in discerning tumor subtype and aggressiveness in a reproducible fashion. Therefore, 59 primary neuroendocrine lung tumors including 10 TCs, 26 ACs, 15 LCNECs, and 8 SCLCs were selected from cases collected from 1976 to 1988 and immunostained for p53 protein. All of these tumors were also genotyped for specific point mutational damage affecting p53 (exons 5, 7, and 8; with ACs additionally sequenced for p53 exon 6); 13 tumors for K-ras-2 (exon 1); and 31 tumors for c-raf-1 (exon 15) growth-regulatory genes. Genotyping was performed on topographically selected, minute tumor samples removed from unstained formalin-fixed, paraffin-embedded tissue sections (topographic genotyping) using polymerase chain reaction and direct sequencing. The distribution of p53 immunohistochemical staining had four patterns: negative in TCs, one-half of ACs, 3 of 15 LCNECs, and 1 of 8 SCLCs; less than 10% but more than five tumor cells per 10 high power fields (focal) in a subset (7 of 26) of aggressive ACs; 10 to 49% of tumor cells (patchy) in a subset (6 of 26) of ACs with a higher grade of aggressiveness; and 50 to 100% of tumor cells (diffuse), exclusively seen in LCNECs (12 of 15) and SCLCs (7 of 8). Three patterns of immunohistochemical staining intensity of p53 protein were seen: negative, weak or mild, and moderate to marked. SCLCs and LCNECs accounted for cases of moderate to marked staining and were the only ones to have mutations in p53 exons 5, 7, or 8. No mutations were found in AC and TC, showing absent to weak staining and no staining, respectively. The difference in distribution and staining intensities between LCNEC and SCLC compared with AC and TC was statistically significant (P < 0.001). Patients having AC with patchy p53 immunostaining usually had survival limited to 3 years, whereas those having AC with focal p53 immunostaining subsequently developed metastatic or recurrence of AC disease (P < 0.05). The absence of point mutations in cases with patchy or focal immunostaining suggests increased expression of wild-type p53 tumor suppressor protein likely in response to growth deregulation in a more aggressive subtype of AC. A novel hypothesis is presented in regard to these findings. K-ras-2 and c-raf-1 gene sequence analysis showed no evidence of point mutational change in any of the tumors studied. The TC and AC categories are therefore genetically distinct from the higher grade neuroendocrine SCLC and LCNEC. Immunohistochemistry for p53 on AC lung tumors may be helpful to delineate cases at higher risk for aggressive behavior. Additionally, although LCNEC is categorized as a non-small-cell carcinoma, it is more akin genetically and immunohistochemically to SCLC.     

Apoptosis-related factors p53, Bcl2, and Bax in neuroendocrine lung tumors.

Neuroendocrine (NE) lung tumors comprise four classes of progressive aggressiveness for which proliferation and apoptosis rates could both contribute to their distinctive behavior. As p53 mutations may favor escape from apoptosis through changes in Bcl2-Bax expression balance, which are survival and apoptotic genes, respectively, we studied 121 NE lung tumors (16 typical carcinoids (TC), 5 atypical carcinoids (AC), 29 large-cell NE carcinomas (LCNECs), and 71 small-cell lung carcinomas (SCLCs) using immunohistochemistry. We quantified apoptosis by terminal-deoxynucleotidyl-transferase-mediated deoxyuridine triphosphate nick end labeling (TUNEL) in 31 of these cases. There was a significant increase of p53 mutant immunophenotype (defined as immunoreactivity with at least two antibodies for at least 20% of tumor cells) between atypical/typical carcinoids group and the LCNEC/SCLC group (P = 0.0003). There was an inverse correlation (P < 0.0001) between the scores of Bax and Bcl2 expression in individual tumors and a significant inversion of the Bcl2. Bax ratio between low-grade (typical and atypical carcinoids) and high-grade (LCNECs and SCLCs) tumors with a predominant Bax expression in the first group and predominant Bcl2 expression in the second. Whereas carcinoids had variable apoptotic indexes, LCNECs had high indexes (1.3 to 6.8%), Bcl2 overexpression, Bax down-regulation, and Bcl2.Bax ratio > 1 correlated with lower apoptotic index in both LCNEC and the pool of LCNECs and SCLCs (P < 0.05) and a lower survival rate in the group of atypical and typical carcinoids and LCNECs (P < 0.002). The highest levels of Bcl2 expression and Bcl2.Bax ratios were associated with p53 mutant immunophenotype (P = 0.02). Our results suggest that aggressiveness in NE lung tumors could be linked, in addition to proliferation, to apoptosis-related factors.     

High-grade neuroendocrine carcinomas of the lung express K homology domain containing protein overexpressed in cancer but carcinoid tumors do not

K homology domain containing protein overexpressed in cancer (KOC) is a member of the insulin-like growth factor (IGF) messenger RNA-binding protein family and is expressed during embryogenesis and in certain malignancies. KOC, known as L523S and IGF messenger RNA-binding protein 3, was shown to be frequently expressed in high-grade neuroendocrine carcinomas of the lung in our immunohistochemical studies using a monoclonal antibody against human KOC. Specifically, all 10 small cell lung carcinomas (SCLCs) exhibited strong cytoplasmic staining, 9 with diffuse positivity and 1 with focal positivity. Among 14 large cell neuroendocrine carcinomas (LCNECs), 9 exhibited strong and diffuse cytoplasmic staining, and 5 cases showed focal immunoreactivity. In contrast, no KOC was detected in 21 typical and atypical carcinoids, except for one atypical carcinoid with oncocytic cells showing weak cytoplasmic staining. Although SCLCs exhibited a strong and diffuse staining pattern more frequently (90%) than LCNECs (64%), the difference did not reach statistical significance (P = .3408). Interestingly, our immunohistochemical studies demonstrated that IGF-II, reportedly regulated by KOC, was comparably expressed in SCLC, LCNEC, and typical and atypical carcinoids, irrespective of KOC expression status of the tumors. These results support the formulation that KOC may play an important role in the regulation of biologic behavior of high-grade neuroendocrine carcinomas. In addition, detection of KOC expression may be diagnostically useful in distinguishing high-grade neuroendocrine carcinomas from carcinoid tumors. Our findings of equivalent IGF-II expression in KOC-positive SCLC and LCNEC and KOC-negative carcinoid tumors suggest different regulatory mechanisms involved in the control of IGF-II expression in these tumors.     

Neuroendocrine differentiation in endocrine and nonendocrine lung carcinomas

Bronchial carcinoids and small cell lung cancer (SCLC) are currently recognized as neuroendocrine (NE) neoplasms. However, non-SCLC (NSCLC) may also express NE properties. Paraffin-embedded sections of a comprehensive panel of 113 lung carcinomas were analyzed for the expression of three general markers common to all NE cells, namely, chromogranin A, Leu-7 and neuron-specific enolase (NSE), five specific NE secretory products, and four other tumor markers by immunohistochemistry using the sensitive avidin-biotinylated peroxidase technique. The authors were able to demonstrate the following: (1) most, but not all carcinoids and SCLCs expressed multiple NE markers in a high percentage of tumor cells; (2) up to a half of NSCLC cases contained small subpopulations of cells expressing NE in a high percentage of tumor cells; (2) up to half of NSCLC cases contained small subpopulations of cells expressing NE markers; and (3) occasional NSCLCs showed staining patterns indistinguishable from SCLC. Specifically, 7 of 77 NSCLCs expressed four or more NE markers. NE markers in NSCLCs were more commonly expressed in adenocarcinomas and large cell carcinomas and rarely in squamous cell carcinomas. For comparison, the mean number of NE markers expressed by all cases of NSCLC was 1.5, carcinoids 6.0, and SCLCs 3.8. Individual "marker counts" were not useful in categorizing lung tumors as carcinoids and SCLC versus NSCLC. Instead, 95% of the tumors were correctly classified, applying a statistical model created from staining indices of the three general NE markers (chromogranin A, Leu-7, NSE) and three other tumor markers (carcinoembryonic antigen, keratin, vimentin). Because NSCLCs with NE features might have different clinical characteristics than other NSCLCs, immunohistochemistry provides an effective manner to identify this biologically interesting subset of NSCLCs in routine paraffin sections.     

Morphometry confirms the presence of considerable nuclear size overlap between "small cells" and "large cells" in high-grade pulmonary neuroendocrine neoplasms

We morphometrically evaluated 5-micron H&E-stained sections from 28 surgically resected high-grade pulmonary neuroendocrine neoplasms, including 16 small cell lung carcinomas (SCLCs) and 12 large cell neuroendocrine carcinomas (LCNECs). For each case, 200 tumor nuclei and 20 to 100 normal lymphocytes were measured. The frequency distributions of tumor cell/lymphocyte (TC/L) size ratios were plotted in bins ranging from 1 to 6, classified into 6 histogram types with TC/L size ratio peaks ranging from 2 to 6 (A-E) and a histogram with a wide distribution (F). SCLCs fit histograms A through E; LCNECs, A through F. Morphometry demonstrated considerable nuclear size overlap in high-grade neoplasms. Approximately one third of SCLCs exhibited considerable numbers of neoplastic cells that were larger than 3 normal lymphocytes, while 4 of 12 LCNECs had a predominant number of small cells. Ten tumors exhibited a B histogram with a "borderline" peak TC/L of 3. The rule that a TC/L size ratio larger than 3 helps distinguish "large" from "small" neoplastic cells was confirmed in only 9 of 28 cases. The use of more generic terminology such as "high-grade neuroendocrine carcinoma" or "grade III neuroendocrine carcinoma" for SCLC and LCNEC is discussed.     

Gastrin-releasing peptide gene expression in small cell and large cell undifferentiated lung carcinomas.

Gastrin-releasing peptide (GRP; mammalian bombesin) is present in the neuroendocrine cells of human fetal lung and in small cell lung carcinomas (SCLCs), where it may act as a growth factor. Considering the potential importance of GRP as a tumor marker, we have conducted a retrospective immunohistochemical analysis of 176 lung tumors for markers of GRP gene expression, as well as several other markers of neuroendocrine cell differentiation: chromogranin A, neuron-specific enolase, and calcitonin. The majority of carcinoids contained mature GRP, in contrast to only a minority of SCLCs and large cell lung carcinomas (LCLCs). However, a majority of SCLCs and LCLCs contained proGRP immunoreactivity. In situ hybridization did not add any information beyond what was obtained using proGRP antisera. In spite of sharing these neuroendocrine cell markers, SCLCs are associated with a graver prognosis than LCLCs. No prognostic significance was associated with immunostaining for GRP or several other markers of neuroendocrine cell differentiation.     

The position of pulmonary carcinoids within the spectrum of neuroendocrine tumors of the lung and other tissues

Bronchopulmonary carcinoids comprise 25% of all human carcinoids. The World Health Organization divides them into typical (TC) and atypical forms (ATC), distinguished by differences in mitotic counts lower or higher than 2/2 mm(2) and the presence or absence of necrosis. The reproducibility of this classification with respect to the borderline cases with 1-2 mitotic counts/2 mm(2) has been questioned. We have analyzed 15 TCs and 20 ATCs by comparative genomic hybridization. Loss of 11q was the most frequent aberration in ATC (55%), but was observed only twice in TC (13%). Deletions of 3p were seen only in ATC (25%). Meta-analysis of our data and data from 218 neuroendocrine tumors and 50 non-small-cell lung carcinomas obtained from the literature revealed differences between carcinoids and carcinomas. For example, loss of 5q is frequent in lung carcinomas (75%) but is rarely seen in carcinoids (1.4%). Deletions of 11q are less frequent in neuroendocrine lung carcinomas than in ATC. To obtain a more objective survey of the relationship of pulmonary carcinoids to other neuroendocrine tumors and lung carcinomas, we created a hierarchical clustering dendrogram. This statistical approach resulted in a clear separation of carcinoids and carcinomas, which both built up different clusters. In summary, this study demonstrates the benefit of chromosomal analysis supplementary to the diagnosis of bronchopulmonary carcinoids. We also identified the feasibility of hierarchical clustering to get some clues on relationship between different tumor types. This study further argues against a transition of ATC to high-grade neuroendocrine lung carcinoma.     

Deletions of 11q22.3-q25 Are Associated with Atypical Lung Carcinoids and Poor Clinical Outcome

Carcinoids are slow-growing neuroendocrine tumors that, in the lung, can be subclassified as typical (TC) or atypical (AC). To identify genetic alterations that improve the prediction of prognosis, we investigated 34 carcinoid tumors of the lung (18 TCs, 15 ACs, and 1 unclassified) by using array comparative genomic hybridization (array CGH) on 3700 genomic bacterial artificial chromosome arrays (resolution ≤1 Mb). When comparing ACs with TCs, the data revealed: i) a significant difference in the average number of chromosome arms altered (9.6 versus 4.2, respectively; P = 0.036), with one subgroup of five ACs having more than 15 chromosome arms altered; ii) chromosomal changes in 30% of ACs or more with additions at 9q (≥1 Mb) and losses at 1p, 2q, 10q, and 11q; and iii) 11q deletions in 8 of 15 ACs versus 1 of 18 TCs (P = 0.004), which was confirmed via fluorescence in situ hybridization. The four critical regions of interest in 45% ACs or more comprised 11q14.1, 11q22.1-q22.3, 11q22.3-q23.2, and 11q24.2-q25, all telomeric of MEN1 at 11q13. Results were correlated with patient clinical data and long-term follow-up. Thus, there is a strong association of 11q22.3-q25 loss with poorer prognosis, alone or in combination with absence of 9q34.11 alterations (P = 0.0022 and P = 0.00026, respectively).Pulmonary carcinoids comprise a group of usually smoking-unrelated neuroendocrine tumors. Compared with poorly differentiated neuroendocrine tumors of the lung, ie, large-cell neuroendocrine carcinoma and small-cell lung cancer, carcinoids are well-differentiated and characterized by a low metastatic rate and a relatively favorable prognosis. On the basis of histopathologic features (number of mitoses and presence of necrosis), lung carcinoid tumors are classified as typical carcinoids (TCs) or atypical carcinoids (ACs), although classification is sometimes difficult and its reliability to predict disease outcome is variable.¹ Compared with TCs, in general, ACs more often exhibit malignant behavior and are associated with a lower 5-year survival rate (61% to 88% and 92% to 100%, respectively).² Metastases will develop in 4% to 64% of patients with carcinoids (TCs, 4% to 14%, and ACs, 35% to 64%), usually in regional lymph nodes but also at distant sites including liver, bone, brain, subcutaneous tissue, and breast.^2,3 Although most patients remain cancer-free within 5 years after surgery, there is no curative treatment available for metastatic disease.A few studies have reported clinical and molecular factors associated with higher risk of developing metastases or with poor disease outcome. Clinical factors with prognostic value include size 3.5 cm or larger, mitotic index, degree of differentiation, presence of necrosis, co-secretion of peptides, and metastasis.^4,5 Immunohistochemistry on TC samples revealed that a high Ki-67 labeling index or up-regulation of the anti-apoptotic proteins Bcl-2 and p53 were associated with metastatic disease and shorter survival time, whereas immunostaining for the adhesion molecule CD44 was associated with localized disease and lower mortality.⁶ An additional study of 121 pulmonary neuroendocrine tumors including 21 carcinoids demonstrated a shift to low Bax and high Bcl-2 expression in association with ACs, resulting in an unfavorable prognosis.⁷ The Rb pathway is more often modified in ACs than in TCs. P16 negativity was observed in 23% of ACs, compared with 9% of TCs, and absent staining for pRb in 21% of ACs and no TCs.⁸Genomic alterations contribute to carcinogenesis by changing the expression levels of critical oncogenes and tumor-suppressor genes. In lung carcinoid tumorigenesis, few p53 and no EGFR or KRAS gene mutations have been detected, although the percentage of lung carcinoids expressing EGFR is higher in TCs than in ACs.^9,10 Previous studies have primarily demonstrated multiple endocrine neoplasia type 1 (MEN1) gene mutations and/or chromosome 11q deletions.^11–17 MEN1 is a syndrome in which an inherited mutation in the MEN1 gene, located at 11q13, predisposes to formation of multiple neuroendocrine tumors. Although formation of bronchial carcinoid tumors has been observed in only 2% of patients with MEN1,¹⁸ functional inactivation of menin, the MEN1 gene product, has been implicated in the tumorigenesis of sporadic lung carcinoids. In these bronchial carcinoids not associated with MEN1 syndrome, the frequency of loss of heterozygosity at 11q (36%) is higher than the somatic MEN1 mutation rate (18%), pointing to the presence of other tumor-suppressor genes at this chromosome arm and/or involvement of epigenetic silencing mechanisms.¹²To improve the discrimination between pulmonary carcinoid tumors with a favorable or poor prognosis and to identify critical genetic events in lung carcinoid tumorigenesis, we investigated 34 reclassified bronchial carcinoids by using array-based comparative genomic hybridization (array CGH) with a resolution of ≤1 Mb (megabase). Fluorescence in situ hybridization (FISH) was used to determine chromosome copy numbers and to validate array CGH data. Furthermore, the array CGH data were correlated with available histopathologic data and long-term clinical follow-up.     

Abnormal p53 expression in lung neuroendocrine tumors. Diagnostic and prognostic implications.

The diagnostic and prognostic implications of p53 immunostaining have been investigated in 59 pulmonary neuroendocrine tumors, including typical carcinoids (n = 15), so-called "atypical carcinoids" (n = 22), and small cell lung carcinomas (SCLCs; n = 22). Immunocytochemistry was performed on formalin-fixed, paraffin-embedded samples using the monoclonal antibody PAb1801, which has been shown to be suitable for staining fixed and embedded tissue sections. p53 immunoreactivity was restricted to atypical carcinoids (45% of the cases being immunoreactive) and to SCLCs (which were positively stained in 59% of the cases), whereas it was consistently lacking in typical carcinoid tumors. When the group of the so-called "atypical carcinoids" was further reclassified, p53 immunostaining was strictly confined to those cases belonging to the histologically more aggressive subsets (well differentiated neuroendocrine carcinoma subsets II and III). Within the same tumor type, however, p53 immunoreactivity did not correlate with the clinical outcome of the disease and was not predictive of the length of survival. The data indicate that abnormal p53 expression (which is strictly dependent on structural abnormalities of the p53 gene) is detectable in the majority of neuroendocrine carcinomas of the lung and might represent a useful adjunct in the differential diagnosis of pulmonary neuroendocrine neoplasms, particularly in routinely fixed and embedded small bronchoscopic biopsies.