Significance of trisomy 7 and 12 in thyroid lesions with follicular differentiation: a cytogenetic and in situ hybridization study

In a group of benign and malignant follicular thyroid lesions, previously analyzed by conventional cytogenetics, single- and double-target fluorescence in situ hybridization studies with pericentromeric probes specific for chromosomes 7 and 12 were performed, by using isolated nuclei from paraffin-embedded specimens of: 11 goiters, 21 adenomas, 9 follicular carcinomas, and adjacent normal thyroid tissue. Nonisotopic in situ hybridization with the same probes was used in 4-microm histologic sections of four follicular carcinomas. By fluorescence in situ hybridization analysis, the percentage of goiters, adenomas, and follicular carcinomas with gains of No. 7 was 18.2%, 52.4%, and 66.0%, respectively, and with gains of No. 12 was 9.0%, 42.9%, and 66.0%, respectively. The percentage of the same lesions (goiters, adenomas, carcinomas) exhibiting polysomies of No. 7 and No. 12, as assessed by cytogenetic analysis, was 5.0% and 0.0%, 20.0% and 20.0%, and 15.8% and 10.5%, respectively. Numerical alterations of these chromosomes were not observed in normal tissue. These findings reveal that gain of chromosomes 7 and 12 is a characteristic of the morphologically altered thyroid tissue; polysomies of chromosomes 7 and 12 are more frequent in thyroid lesions than it can be detected by conventional cytogenetic studies; the increasing frequency of polysomies of chromosomes 7 and 12 from hyperplastic lesions to benign and malignant tumors seem to substantiate the existence of a multistep pathway, ie, normal thyroid --> goiter --> adenoma --> follicular carcinoma in the pathogenesis of some thyroid neoplasms.     

Interphase cytogenetics in oncocytic adenomas and carcinomas of the thyroid gland

Follicular neoplasms of oncocytic type in the thyroid gland frequently cause diagnostic problems and prognostic uncertainties. To identify numerical chromosomal aberrations of possible pathogenetic importance, we determined chromosome copy numbers in situ in interphase nuclei of 31 oncocytic adenomas and 25 oncocytic carcinomas. Archival formaldehyde-fixed, paraffin-embedded tumor samples and normal control thyroid tissues were arranged in arrays and analyzed by fluorescence in situ hybridization (FISH). We used pericentromeric or locus specific probes for chromosomes 1, 7, 8, 9, 11, 12, 17, 18, 22, and X as well as for the oncogenes Her2/neu, cyclin D1, N-myc, and c-myc. The average number of aneusomies per nucleus was significantly higher in carcinomas than in adenomas, and in both, monosomies were more frequent than polysomies. Loss of chromosome 22 was found in 8 of 21 (38%) carcinomas; in 5 cases, it was associated with chromosome 2 monosomy. Conversely, chromosome 2 aberrations were not found in adenomas. Monosomies for chromosome 8 and X were detected in most adenomas and carcinomas. The most common gains in adenomas and carcinomas were for chromosome 7 (13.8% and 32.0% of the cases, respectively), chromosome 12 (9.6% and 12.0%), and chromosome 17 (19.3% and 32.0%). None of the adenomas with trisomy 17 was associated with gains for chromosomes 7 and 12. None of the analyzed oncogenes was found to be amplified by FISH analysis. Our results indicate that numerical chromosomal aberrations in oncocytic follicular tumors of the thyroid gland are common findings and suggest that different patterns of aberrations may occur in these neoplasms.     

Numerical chromosomal aberrations in thyroid tumors detected by double fluorescence in situ hybridization

Double fluorescence in situ hybridization with DNA probes specific for the (peri)centromeric regions of chromosomes 3, 7, 9, 11, 12, 18, and X was performed on fresh isolated nuclei and frozen tissue sections prepared from 2 nodular hyperplasias, 2 adenomas, and 7 papillary carcinomas of the thyroid in order to detect numerical chromosomal changes. Numerical chromosomal aberrations were found in all malignant specimens examined. A consistent presence of at least two trisomies was detected in most cases, especially in the follicular variant specimens; the highest degree of trisomy was observed for chromosome 12. Isolated monosomies of moderate degree for different chromosomes were found in 1 adenoma and 2 papillary carcinomas. Severe monosomy of chromosome 9 was the only significant feature observed in the single metastatic papillary carcinoma. Genes Chrom Cancer 9:180-185 (1994). © 1994 Wiley-Liss, Inc.     

Detection of numerical chromosome anomalies in interphase cells of benign and malignant thyroid lesions using fluorescence in situ hybridization

Benign and malignant thyroid tumors constitute a wide range of neoplasias showing recurrent chromosome abnormalities. In an attempt to characterize specific numerical chromosome abnormalities in thyroid tissues, we present here the findings from a study of archival samples depicted by 10 malignant tumors, 30 benign lesions, and 10 normal thyroid tissues. Fluorescence in situ hybridization was performed on noncultured samples using biotinylated centromere-specific probes for chromosomes 7, 10, and 17. Trisomy or tetrasomy 7 were present in 19 benign and in 7 malignant tumors. Trisomy 10 or 17 were observed in 18 adenomas or goiters and in 9 carcinomas, and monosomy 17 was seen in 2 carcinomas. Our findings suggest that such abnormalities are an in vivo phenomenon and may be important in the neoplastic proliferation of thyroid gland.     

Adenomas and follicular carcinomas of the thyroid display two major patterns of chromosomal changes

It was recently shown by flow and static cytometry that a large sub-group of follicular adenomas of the thyroid--fetal/embryonal adenomas--display an aneuploid phenotype. It was also shown that thyroid lesions with a DNA content within the triploid range were either fetal adenomas or follicular carcinomas with a fetal adenoma growth pattern. Follicular tumours with growth patterns other than the so-called fetal adenoma-like pattern were usually diploid or near-diploid. In an attempt to clarify the pattern of chromosomal imbalances in follicular tumours, comparative genomic hybridization (CGH) analysis was performed in a series of 18 follicular neoplasms (ten fetal/embryonal and four common follicular adenomas and four minimally invasive follicular carcinomas). For each tumour, the DNA content was determined by flow cytometry and, in some cases, also by static cytometry. Finally, the copy number of selected chromosomes was determined by interphase fluorescence in situ hybridization (FISH) using centromere probes. With the exception of the single diploid fetal adenoma, all fetal adenomas displayed several DNA copy number changes, with frequent gains of several chromosomes, which were found to be either tetrasomic or trisomic by FISH. This genetic pattern was also present in the single case of follicular carcinoma with aneuploidy and fetal adenoma-like growth pattern. Follicular adenomas other than fetal adenomas, and the remaining follicular carcinomas, showed more losses than gains of chromosomes. These results suggest that follicular tumourigenesis may follow at least two pathways: one characterized by prominent aneuploidy and numerous gains, in which the tumours display a fetal adenoma-like growth pattern; and another accompanied by less obvious aneuploidy or even quasi-diploidy and dominant chromosome losses, in which the tumours display a common follicular architecture.     

Incidence of chromosome numerical changes in multiple myeloma: fluorescence in situ hybridization analysis using 15 chromosome-specific probes.

The presence of complex karotypes with frequent numerical and structural abnormalities has been reported in 20 to 50% of multiple myeloma (MM) patients. This variability is mainly due to the difficulty of conventional cytogenetics to obtain tumor metaphases representative of all possible neoplastic clones in MM. To gain insight into the real incidence of numerical chromosome changes in MM we have studied by fluorescence in situ hybridization technique 15 different human chromosomes, 1, 3, 6, 7, 8, 9, 10, 11, 12, 13, 15, 17, 18, X, and Y, in a series of 52 MM patients. In all cases, the DNA index assessed by a propidium iodide/CD38 double-staining technique with flow cytometry was simultaneously investigated for correlation, with fluorescence in situ hybridization results. Additional aims of this study were 1) to analyze whether the abnormalities detected were common to all plasma cells or were present in only a subpopulation of tumor cells, 2) to explore changes caused by disease progression, and 3) to establish possible associations among the altered chromosomes. Although the overall incidence of numerical abnormalities was 67%, this frequency increased to 80% in the 41 cases in which 7 or more chromosomes were analyzed. Trisomies were significantly more common than monosomies (84% versus 16%). Chromosomes 9 and 15 were the most frequently altered (52% and 48% of cases, respectively), with all of their abnormalities corresponding to trisomies. The most frequent losses involved chromosomes 13 (26%) and X in females (32%). Other common numerical changes corresponded to chromosomes 1 (39%), 11 (37%), 6 (32%), 3 (31%), 18 (29%), 7 (28%), and 17 (22%). By contrast, chromosomes 8(13%), 10(8%), and 12(3%) were rarely altered. DNA aneuploidy by flow cytometry was detected in 67% of patients, and a high degree of correlation was observed between the DNA index obtained by flow cytometry and the chromosome index derived from fluorescence in situ hybridization studies, calculated according to two mathematical formulas (coefficient of correlation of 0.82 and 0.91 when at least 7 or 12 chromosomes were considered, respectively). The frequency of numeric chromosome aberrations was higher in those patients with progressive disease and, interestingly, trisomy of chromosome 8 was exclusively detected in this latter group of patients. Our study shows that, with the exception of chromosome 8, a possible marker of clonal evolution, the numeric chromosome changes are present in nearly all malignant plasma cells (r > 0.84). Finally, frequent associations between chromosomal aberrations were observed (ie, chromosomes 6, 7, 9, and 17; 7 and 15; and 11 and 17). By excluding them, it was found that two triple combinations of chromosome-specific probes, chromosomes 1 and 9 together with either chromosome 13 or 15, could be a useful marker for detection of residual disease, as it permits the identification of most MM patients displaying numerical changes.     

Distribution of Leu-7 antigen (HNK-1) in thyroid tumors: its usefulness as a diagnostic marker for follicular and papillary carcinomas.

The reactivity of the anti-Leu-7 monoclonal antibody was tested in 39 neoplastic and nonneoplastic thyroid tissue specimens. These included eight colloid goiters, 14 follicular adenomas, nine papillary carcinomas, five follicular carcinomas, two medullary carcinomas, and one metastatic follicular carcinoma in bone. We observed strong cytoplasmic and/or cell membrane positivity in all follicular and papillary carcinomas, in both primary and metastatic tumors. However, the medullary thyroid carcinomas tested were negative. We also observed weak and only occasional staining with anti-Leu-7 antibody in colloid goiter and follicular adenomas. The staining in the benign thyroid lesions was usually focal, less than 10% of the cells; however, in cases of follicular and papillary carcinomas, both in primary and metastatic tumors, the staining was diffuse and strong. Some of the colloid material in colloid goiters and follicular adenomas showed faint homogenous staining with anti-Leu-7 antibody. Our findings suggest that anti-Leu-7 monoclonal antibody is a marker that may facilitate the differentiation between benign and malignant thyroid lesions, with the exception of medullary carcinoma. In addition, caution should be taken when using this antibody to diagnose metastatic lesions, as other metastatic carcinomas have also been reported to be positive. This antibody should be used in conjunction with a panel of antisera to complement a morphologic diagnosis.     

Clinical impact of chromosome 1 aberrations in neuroblastoma: a metaphase and interphase cytogenetic study.

Neuroblastoma tumors are characterized by aberrations of chromosome 1. Rapid detection of these chromosomal aberrations at diagnosis could give important clues to outcome and therapy. We attempted to detect numerical and structural aberrations of chromosome 1 not only by classical metaphase cytogenetics but also by interphase cytogenetics in order to overcome difficulties of karyotyping due to diminished metaphase quality and quantity in primary neuroblastoma samples. Karyotypic changes of chromosome 1 in 53 primary neuroblastomas were evaluated. In addition, we successfully performed interphase cytogenetics using single and double in situ hybridization procedures with chromosome 1-specific repetitive DNA probes on nuclei preparations obtained from 46 and 20 tumors, respectively. Polysomies of structurally normal chromosomes 1 were predominantly seen in tumors with good prognosis, whereas deletions of 1p material were nearly exclusively confined to progressive tumors. Numerical and structural chromosome 1 aberrations as studied by metaphase and interphase cytogenetics are thus valuable prognostic markers in neuroblastoma.     

Importance of using comparative genomic hybridization to improve detection of chromosomal changes in childhood acute lymphoblastic leukemia

We used comparative genomic hybridization (CGH) and conventional cytogenetics (CC) to define chromosomal changes and to evaluate the usefulness of CGH in 65 patients having childhood acute lymphoblastic leukemia (ALL). Subsequently, fluorescence in situ hybridization (FISH) was used to evaluate the CGH and cytogenetic results. Comparative genomic hybridization revealed DNA copy number changes in 49 (75%) patients (including 7 patients with unsuccessful cytogenetics and 2 patients with normal karyotype). A total of 85 losses and 195 gains were detected. The most commonly gained chromosomes were 21 (35%), X (31%), 18 (27%), 10 (26%), 6 (25%), 17 (25%), 4 (23%), and 14 (22%). Losses were most frequently observed on chromosomes 9p (18%) and 12p (11%). Other losses were detected on chromosomes 13q (9%), 6q (9%), 7p (8%), and chromosome X (6%). Conventional cytogenetics revealed chromosomal changes in 53 (82%) patients. The employment of CGH and FISH together with CC analysis revealed chromosomal changes in 62 (95%) of the childhood ALL patients investigated. The CGH completed CC results in 36 patients; in 9 patients, the changes escaped detection without using CGH. The results of our study were compared to 6 other CGH studies previously reported. Our observations underline the benefits of supplementing routine cytogenetic investigation in childhood ALL by FISH and CGH, because small unbalanced changes may escape detection when conventional cytogenetics is the only diagnostic method used.     

Comprehensive conventional and molecular cytogenetic characterization of B-CPAP, a human papillary thyroid carcinoma-derived cell line

Cell lines derived from different thyroid tumor histotypes are useful for the in vitro study of both the phenotypic and genetic features of these cancers. Although karyotypic changes are known to be associated with thyroid lesions, the chromosome patterns of only a few cell lines have been published. Herein, we report an extensive conventional and molecular cytogenetic investigation of the human papillary thyroid carcinoma derived cell line B-CPAP. Morphological studies and expression of tumor markers in this cell line have been reported previously, but no detailed characterization on the origin of the chromosome markers is available. B-CPAP cells have a rather stable hypertriploid karyotype, with chromosome polysomies and structural chromosome abnormalities featuring whole chromosome arm imbalances. Chromosome banding revealed a main clone with nine chromosome markers, and fluorescence in situ hybridization (FISH) with whole chromosome paint (wcp), partial chromosome paint (pcp), and centromeric probes clarified their origin. The use of centromeric probes provided accurate refinement of the rearrangements classified as whole-arm translocations by banding and FISH with wcp probes. Both chromosomal and array-based comparative genomic hybridization experiments confirmed the cytogenetic characterization of this cell line. Moreover, the use of fluorescence immunophenotyping and interphase cytogenetics as a tool for the investigation of neoplasms (FICTION) technique, which simultaneously shows nuclear ploidy and cytoplasmic immunofluorescence, detailed the oncocytic feature of the cells. Intriguingly, despite their origin, they lack most of the features expressed in papillary thyroid tumor cells and have a chromosomal pattern reminiscent of that of a subgroup of oncocytic malignant thyroid tumors.     

Follicular thyroid carcinoma: Chromosome analysis of 19 cases

Short-term cultures of 19 follicular thyroid carcinomas were examined cytogenetically. Clonal chromosomal changes were detected in 12 tumors. Two follicular carcinomas had only numerical alterations: one with a hyperdiploid karyotype with trisomies/polysomies of chromosomes 7 and 12, similar to the karyotypes previously identified in a sub-group of benign thyroid lesions, and the other with monosomy 20. In the remaining ten cases several structural chromosome anomalies were found. Loss of the short arm of chromosome 3 was observed in one tumor. In two widely invasive and metastasizing follicular carcinomas there was a t(7;8)(p15;q24) as the sole abnormality in one case and a der(8)t(7;8)(p15;q24) together with other cytogenetic alterations in the other case. This finding suggests that t(7;8)(p15;q24) may be related to an aggressive behavior of follicular thyroid carcinomas. Genes Chromosomes Cancer 21:250–255, 1998. © 1998 Wiley-Liss, Inc.     

Characterization of the C-MYC amplicon in a case of acute myeloid leukemia with double minute chromosomes

Chromosome G-banding analysis of metaphase cells from 16 primary breast carcinomas revealed the presence of multiple polysomies in near-diploid as well as in polyploid cells. Chromosome 17 was preferentially gained in 7 tumors, followed in frequency by chromosomes 1, 12, and 19 (5 tumors each), and chromosomes 5, 6, 7, 16, and 18 (4 tumors each). Eleven of the 16 carcinomas had, apart from the clones exhibiting the numerical gains, other unrelated clones. Nine of these 11 cases had clones with structural chromosome aberrations, 5 of which had structural aberrations involving the short arm of chromosome 3. The biologic significance, if any, of this seemingly nonrandom coexistence of multiple polysomies with structural aberrations of 3p is at present not known. The pattern of numerical chromosome aberrations observed in the present study is comparable to previous results from fluorescence in situ hybridization (FISH) studies, with the use of centromeric probes on interphase cells. However, unlike FISH studies, which have been focused on chromosomes 1, 3, 7, 8, 11, 16, and 17, the cytogenetic results reveal that other chromosomes also may be nonrandomly gained as part of multiple polysomies in breast carcinomas. In addition, the tumors with multiple polysomies were generally of high histologic grade and with metastasis to axillary lymph nodes, suggesting that multiple wholechromosome gains may be a pathway of genetic evolution or progression or both in some breast carcinomas.     

DNA aneuploidy in follicular adenomas of the thyroid gland.

The nuclear DNA content of 67 follicular adenomas and 7 adenomatous goiters was determined by flow cytometry. The DNA analysis was done with the use of paraffin-embedded tissue, but in 14 cases of follicular adenoma fresh material obtained by fine needle aspiration biopsy was also available. An abnormal DNA stemline was found in 27% (18/67) of the adenomas and in 1 (14%) of the adenomatous goiters. Four (29%) of the 14 adenomas analyzed from fresh samples were aneuploid. In none of the 12 aneuploid or 40 diploid adenomas followed for more than 5 years (mean, 7.2 years) did distant metastases develop after surgical removal of the adenoma. The paraffin blocks of cases with DNA aneuploidy were sectioned subserially at 1-mm intervals, but none of these tumors showed invasion into the capsule or blood vessels. It is concluded that DNA aneuploidy is common in histologically benign follicular adenomas of the thyroid, and that DNA aneuploidy does not appear to be associated with adverse prognosis in follicular adenomas if the tumor is surgically removed.     

肺癌胸水间期细胞遗传学异常变化的研究

目的 探讨肺癌胸水肿瘤细胞的间期细胞遗传学改变,并将其结果与传统细胞学结果进行比较。方法 用７号、１１号、１７号、Ｘ染色体着丝粒特异的ＤＮＡ探针,以２６例肺癌胸水标本进行双色荧光原位杂交（ｆｌｕｏｒｅｓｃｅｎｃｅ ｉｎ ｓｉｔｕ ｈｙｂｒｉｄｉｚａｔｉｏｎ,ＦＩＳＨ）结果 在１９例肺癌阳性胸水标本中,７号、Ｘ、１７号、１１号染色体出现超二倍体的病例分别为１６例（８４．２％）、１４例（７３．７％）、     

Aneuploidy in oncocytic lesions of the thyroid gland: diffuse accumulation of mitochondria within the cell is associated with trisomy 7 and progressive numerical chromosomal alterations

Oncocytic cells are characterized by a greatly increased number of mitochondria that distend the cell cytoplasm and result in a distinctive granular appearance of the cell on conventional histology sections. Oncocytes are frequently found in metabolically active human tissues including the thyroid gland, and, as a general rule, when their proportion in a thyroid tumor is greater than 75% the tumor is referred to as oncocytic (Hürthle cell) adenoma or carcinoma. Such tumors represent a subset of thyroid lesions, and recently, both interphase fluorescence in situ hybridization (FISH) and comparative genomic hybridization (CGH) studies reported that they may show aneuploidy, with widespread numerical chromosomal alterations. In contrast, very few cases have been studied by conventional cytogenetic analysis. Whether the cells with chromosomal changes are the same as those with mitochondrial accumulation or whether lesions only partially composed of oncocytic cells also have cytogenetic alterations is unclear. To investigate the relationship between acquisition of the oncocytic phenotype and numerical chromosomal changes, we analyzed a random selection of thyroid lesions with (18 cases) and without (11 cases) morphological evidence of oncocytic differentiation. Lesions with oncocytes included hyperplastic nodules, adenomas, Hürthle cell tumors, and papillary carcinomas with lymphocytic stroma (Whartin-like tumors of the thyroid). Karyotypic changes were analyzed by cytogenetic analysis, FISH, or CGH, and the results were compared with in situ analysis of mitochondrial accumulation by immunofluorescence. A striking correlation between the presence of oncocytes and the presence of aneuploid katyotypes was seen in the oncocytic follicular thyroid nodules, but not in the oncocytic papillary tumors. Structural chromosome changes or normal karyotypes were observed in the lesions lacking oncocytic features. Extending the FICTION technique to the evaluation of a cytoplasmic antigen (mitochondrial membrane antigen), we pursued the simultaneous visualization of both mitochondrial increase and numerical chromosomal alterations, and showed that oncocytes of follicular lesions are prone to become aneuploid. Our data support the contention that follicular tumors composed of oncocytes should be regarded as a distinct subset.     

Trisomy 1 and 8 occur frequently in hepatocellular carcinoma but not in liver cell adenoma and focal nodular hyperplasia. A fluorescence in situ hybridization study

Conventional cytogenetic studies revealed gains and structural aberrations of chromosome 1 to be the most consistent chromosomal aberrations in hepatocellular carcinoma (HCC). We investigated touch preparations of eight HCC, five cholangiocellular carcinomas (CCC), five liver cell adenomas (LCA), four focal nodular hyperplasias (FNH) as well as nine specimens of normal liver tissue using fluorescence in situ hybridization (FISH) with centromere specific probes for chromosomes 1 and 8. Polysomies of chromosome 1, especially trisomy 1, were found in five of eight HCC and four of five CCC but in no normal liver tissue or benign tumour. Only three of seven cases of HCC revealed trisomy 8 whereas the five benign liver tumours and all normal liver tissues examined had disomy 8. Our results confirm conventional cytogenetic findings in terms of chromosome 1 aberrations in HCC although they are not specific for these types of malignant liver tumours. Since -satellite probes were used in our study, only gains or losses including the centromeric regions of the chromosomes 1 and 8 could be detected. Nevertheless, our findings suggest that FISH may help in the differential diagnosis of malignant versus benign neoplasms of the liver.     

Chromosome imbalances in thyroid follicular neoplasms: a comparison between follicular adenomas and carcinomas

The underlying genetic events associated with follicular thyroid tumorigenesis are still ill defined. In this study, we performed a screening for chromosome imbalances by comparative genomic hybridization (CGH) in a group of 12 follicular adenomas (FAs) and 20 follicular carcinomas (FTCs) previously characterized by conventional cytogenetics and flow cytometry analysis. In general, a great similarity was observed between the CGH profiles of the FAs and FTCs. In both benign and malignant tumors, a combination of gains affecting 5, 7, 12, 17, 19, and 20 was observed. Chromosome 7 was the most frequently affected chromosome, with three regions of consensus gains: 7p11-12, 7q11.3-q21, and 7q31. Recurrent gains of chromosomes 5 and 12 involved 5p11, 5p15, 5q13-q22, 5q21-q23, 12p11, and 12q11-q12. DNA sequence losses were also observed in both tumor groups. Chromosomal arms deleted in at least five of the neoplasms were (in order of frequency): in adenomas, 15q, 2p/2q, 3q, 6p/6q, 11q, and 22q; and in FTCs, 3p, 2p, 8q, 1p, 2q, 3q, 6q, 8p, 9p, 11q, 13q, 6p, and 18q. The statistical evaluation of the CGH data demonstrated that 15q loss was significantly associated with FA. Two regions of minimal common loss were defined by CGH at 15: 15q11-q21 and 15q26-qter. The identification of these regions provides a basis for further molecular studies.     

Automated analysis of fluorescence in situ hybridization on fixed, paraffin-embedded whole tissue sections in B-cell lymphoma.

Certain recurrent cytogenetic abnormalities are diagnostic of a specific neoplasm and may portend prognosis. As conventional cytogenetics may not reveal a neoplastic clone, and unfixed material for fluorescence in situ hybridization may be unavailable, performing fluorescence in situ hybridization on fixed tissues is diagnostically and prognostically valuable. Manual interpretation of fluorescence in situ hybridization signals may be difficult on paraffin-embedded tissue sections due to truncated nuclei. Therefore, we investigated the use of an automated image acquisition and analysis system (MetaSystems) for interpretation of fluorescence in situ hybridization signals in tissue sections from dual fusion translocation probes. Three probe sets were analyzed on archival specimens with a confirmed diagnosis of mantle cell lymphoma, follicular lymphoma or Burkitt lymphoma. 100% of mantle cell lymphomas (7/7) were positive for t(11;14), 91% of follicular lymphomas (10/11) for t(14;18) and 100% of Burkitt lymphomas (9/9) for t(8;14). Successful hybridization was achieved using various tissue fixatives and fluorescence in situ hybridization interpretation was blinded with respect to the underlying diagnosis. Based on these results, automated analysis of fluorescence in situ hybridization on fixed tissues is accurate and valuable in the evaluation of B-cell lymphoma, and may provide pertinent diagnostic and prognostic information.     

Transition of high-grade cervical intraepithelial neoplasia to micro-invasive carcinoma is characterized by integration of HPV 16/18 and numerical chromosome abnormalities

Cervical intraepithelial neoplasia (CIN I, II, and III) and cases of CIN III associated with micro-invasive cervical carcinoma (CIN III & mCA) were analysed for evidence of episomal or integrated human papillomavirus (HPV) 16/18 DNA by fluorescence in situ hybridization (FISH). In parallel, numerical aberrations of chromosomes 1, 17, and X were determined in these lesions as indicators of genomic instability. HPV 16/18 DNA was present in 2 of 12 CIN I, 19 of 23 CIN II/III, and 10 of 12 CIN III & mCA. None of the CIN I and only two of the 19 HPV 16/18-positive solitary CIN II/III showed an integrated HPV pattern. However, all ten cases of HPV-positive CIN III & mCA showed this pattern. Transition of CIN II/III to CIN III & mCA therefore correlates strongly with viral integration (p<0.001). Chromosomal aberrations were detected in 23 of 31 HPV 16/18-positive lesions (14 solitary CIN I-III and nine CIN III & mCA) and 5 of 16 HPV-negative lesions. Nine of 21 HPV 16/18-positive solitary CIN I-III showed tetrasomy for all chromosomes tested, while trisomies for a single chromosome were seen in a further five of these HPV-positive lesions. In eight of ten HPV-positive CIN III & mCA, predominantly aneusomies and/or polysomies were detected. A significant correlation (p<0.02) was found between the chromosome copy number and the physical status of HPV, indicating that in its episomal form HPV induces genomic changes such as tetrasomies and single trisomies, while HPV integration correlates with aneusomies and polysomies, predominantly detected in CIN III & mCA. These data indicate that integration of HPV 16/18 DNA is a pivotal step in the transition of CIN to micro-invasive carcinoma.