Chromosome abnormalities in pancreatic adenocarcinoma

Adenocarcinoma of the pancreas is the fifth most common cause of cancer deaths in the United States, yet few cytogenetic studies of this tumor have been reported. We analyzed 26 primary tumors to identify which chromosome abnormalities occur most frequently in this neoplasm. One carcinoma was well differentiated and mucin producing, 18 were moderately well differentiated, and seven were poorly differentiated. Only normal karyotypes were obtained from nine carcinomas. The remaining 17 carcinomas frequently had normal metaphase cells in addition to simple to highly complex karyotypes. The modal chromosome number in 20 carcinomas was diploid or near-diploid; four carcinomas had both a major near-diploid and near-triploid or near-tetraploid component, and two were near-tetraploid. Numerical abnormalities included loss of whole copies of chromosomes 6, 17, and 18, and gains of chromosome 20. Structural abnormalities were frequent, with 1p, 2p, 3p, 4q, 6q, 7q, 1 1q, and 17p recurrently involved. Results of this study were combined with karyotypes of 19 other primary adenocarcinomas of the pancreas reported in the literature. The combined data involving 1 17 breakpoints suggest that careful analysis of chromosome 20, proximal 1 q. 6q, proximal 8p. and proximal 17p could be productive in defining genes involved in adenocarcinoma of the pancreas. Genes Chrom Cancer 9:93-100 (1994).© 1994 Wiley-Liss, Inc.     

Chromosome aberrations in 35 primary ovarian carcinomas.

Cytogenetic analysis was performed on short-term cultures of primary ovarian carcinomas from 62 patients. Cytogenetic analysis was successful in 59 cases. Clonal chromosome aberrations were detected in 35 tumors. Only numerical changes or a single structural change were found in five carcinomas: trisomy 12 was the sole anomaly in two tumors, one tumor had the karyotype 50,XX, + 5, + 7, + 12, + 14, a fourth tumor had a balanced t(1;5), and the fifth tumor had an unbalanced t(8;15). The fact that four of these five carcinomas were well differentiated suggests that simple karyotypic changes are generally characteristic of these less aggressive ovarian tumors. The majority of the cytogenetically abnormal tumors (n = 30) had complex karyotypes, with both numerical and structural aberrations and often hypodiploid or near-triploid stemlines. The numerical imbalances (comparison with the nearest euploid number) were mostly losses, in order of decreasing frequency -17, -22, -13, -8, -X, and -14. The structural aberrations were mostly deletions and unbalanced translocations. Recurrent loss of genetic material affected chromosome arms 1p, 3p, 6q, and 11p. The breakpoints of the clonal structural abnormalities clustered to several chromosome bands and segments: 19p13, 11p13-15, 1q21-23, 1p36, 19q13, 3p12-13, and 6q21-23. The most consistent change (16 tumors) was a 19p + marker, and in 12 of the tumors the 19p + markers looked alike.     

Genomic aberrations in diffuse low-grade gliomas

The current classification of diffuse low-grade gliomas is based mainly on histopathological criteria, which cannot accurately predict the highly variable clinical course observed in patients with such tumors. In an attempt to increase pathogenetic understanding of these tumors, we investigated 38 WHO Grade II astrocytomas, oligodendrogliomas, and oligoastrocytomas using a combination of G-band chromosome analysis and high-resolution comparative genomic hybridization (HR-CGH). Abnormal karyotypes were found in 41% of tumors. Karyotypes of astrocytomas and oligodendrogliomas were near-diploid whereas oligoastrocytomas also displayed near-tetraploid clones. The most common aberrations were losses of chromosomes X, Y, 3, 4, 6, and 11 and gains of chromosomes 8 and 12. The only recurrent structural rearrangement was del(6)(q21). HR-CGH analysis verified karyotyping findings but also revealed frequent losses at 1p, 17q, and 19q and gains of 7q, 10p, 11q, and 20p. Among the tumors were two gemistocytic astrocytomas, a subgroup of diffuse astrocytomas with a particular predisposition for progression but not studied cytogenetically before; one showed a near-diploid, complex karyotype with structural aberrations of chromosomes 1, 3, and 11 whereas both displayed simple aberrations including loss of 11p by HR-CGH. Our findings suggest that within diffuse low-grade gliomas are genetically distinct entities that do not fit the currently used classification. In addition, tumors with complex chromosomal aberrations had a higher tendency for aggressive tumor behavior (shorter progression-free survival) than tumors displaying simple aberrations only (P = 0.07). This could help identify genetic subsets of patients with low-grade glioma who might benefit from early antineoplastic therapy.     

Spectral karyotyping and chromosome banding studies of primary breast carcinomas and their lymph node metastases

Three primary breast tumors and their lymph node metastases were characterized by G-banding, spectral karyotyping (SKY), and fluorescence in situ hybridization (FISH). In each case, the karyotypic abnormalities detected were similar in the primary tumor and its matched metastasis. Two of the pairs had near-diploid karyotypes with three to four chromosomal aberrations, whereas the third pair had a near-pentaploid chromosome content and many marker chromosomes in the primary tumor and a near-tetraploid chromosome number with almost the same marker chromosomes in the metastasis. SKY and FISH confirmed the karyotypic similarities between the primary tumors and their metastases and, in addition, improved the identification and characterization of marker chromosomes. One of the tumor pairs with near-diploid karyotypes had gain of 8q, 16q, and 17q, whereas the other had gain of 1q and chromosome 8 material in the form of ring chromosomes. The third pair had more complex chromosomal translocations and numerical changes resulting in net gain of material from chromosomes X, 1, 2, 6, 7, 14, 16, 19, and 20, and chromosome arms 8q and 11q, as well as net loss of material from chromosomes 3, 13, 18, 21, and 22. The present study underscores the need to combine conventional chromosome banding and molecular cytogenetic techniques in the cytogenetic analysis of solid tumors.     

Consistent chromosomal losses in head and neck squamous cell carcinoma cell lines

Clonal chromosomal abnormalities were characterized in nine cell lines established from squamous cell carcinomas of the head and neck. Aneuploidy was a common feature; one cell line was near-diploid, three were near-triploid, four were near-tetraploid, and one cell line showed extensive variation in chromosome numbers. Consistent numerical abnormalities included loss of the sex chromosomes in six cell lines, losses of chromosomes 2 and 21 in six and five cell lines, respectively, and gain of chromosome 20 in five cell lines. Recurrent structural rearrangements included del(10)(q22-q26) (seven cell lines), i(5)(p10) (six cell lines), i(8)(q10) (six cell lines), add(19)(q13) (six cell lines), del(4)(q21-q31.3) (five cell lines), i(3)(q10) (four cell lines), del(12)(p11.1-p12) (four cell lines), and add (18)(q21-q23) (four cell lines). Other changes were noted in lower frequencies. Loss of specific regions on chromosomes 2, 3p, 4q, 5q, 8p, 10q, 12p, 18q, 19q, and 21 suggests that they may represent sites of putative tumor suppressor genes, loss of which may play a role in the pathogenesis of squamous cell carcinomas of the head and neck. Alternatively, gain of chromosomal region 3q, 5p, and 8q due to isochromosome formation suggests that more than one mechanism is involved in malignant transformation. Cytogenetic evidence of gene amplification was found in two cell lines; as an hsr(11)(q 13) in one and as dmins in the other. The clonal karyotypes of four cell lines were compared with those of their respective primary tumors. In all cell lines, clonal evolution had occurred, with loss of some rearrangements present in the primary tumors or the gain of additional abnormalities.     

Chromosome analysis of 97 primary breast carcinomas: Identification of eight karyotypic subgroups

Chromosome banding analysis of 97 short-term cultured primary breast carcinomas revealed clonal aberrations in 79 tumors, whereas 18 were karyotypically normal. In 34 of the 79 tumors with abnormalities, two to eight clones per case were detected; unrelated clones were present in 27 (34%) cases, whereas only related clones were found in seven. These findings indicate that a substantial proportion of breast carcinomas are of polyclonal origin. Altogether eight abnormalities were repeatedly identified both as sole chromosomal anomalies and as part of more complex karyotypes: the structural rearrangements i(1)(q10), der(1;16)(q10;p10), del(1)(q11–12), del(3)(p12–13p14–21), and del(6)(q21–22) and the numerical aberrations +7, +18, and +20. At least one of these changes was found in 41 (52%) of the karyotypically abnormal tumors. They identify a minimum number of cytogenetic subgroups in breast cancer and are likely to represent primary chromosome anomalies in this type of neoplasia. Other candidates for such a role are translocations of 3p12–13 and 4q21 with various partner chromosomes and inversions of chromosome 7, which also were seen repeatedly. Additional chromosomal aberrations that give the impression of occurring nonrandomly in breast carcinomas include structural rearrangements leading to partial monosomies for 1p, 8p, 11p, 11q, 15p, 17p, 19p, and 19q and losses of one copy of chromosomes X, 8, 9, 13, 14, 17, and 22. The latter changes were seen consistently only in complex karyotypes, however, and we therefore interpret them as being secondary anomalies acquired during clonal evolution.     

Nonrandom pattern of cytogenetic abnormalities in squamous cell carcinoma of the larynx

Cytogenetic analysis of short-term cultures from 105 squamous cell carcinomas of the larynx (LSCC) revealed clonal chromosome aberrations in 56 tumors. Simple karyotypic changes (less than four aberrations per clone) were found in 24 cases, and the remaining 32 tumors had complex karyotypes with multiple numerical as well as unbalanced structural rearrangements. Extensive intratumor heterogeneity, in the form of multiple related subclones or unrelated clones, was observed in a large fraction of the tumors. The structural changes most often affected chromosomes 3, 1, 11, 7, 2, 15, 5, 4, 8, and 12, with rearrangements in the centromeric regions, i.e., the centromeric bands p10 and q10 and the juxtacentromeric bands p11 and q11, accounting for 43% of the total breakpoints. The most common imbalances brought about by numerical and unbalanced structural rearrangements were loss of chromosomal region 3p21-pter, chromosome arms 4p, 6q, 8p, 10p, 13p, 14p, 15p, and 17p, and gain of chromosomal regions 3q21-qter, 7q31-pter, and 8q. Among 17 recurrent aberrations identified, the most common were i(8q), hsr(11)(q13), i(3q), i(5p), and del(3)(p11). No statistically significant association was found between major karyotypic features and histological differentiation or TNM stage. The karyotypic features of the LSCC were also compared with previously published oral SCC, a subgroup of SCC that has been more extensively characterized cytogenetically. No clear-cut karyotypic differences were found between LSCC and oral SCC, with the exception that i(8q) was significantly more frequent among the latter.     

Endometrial stromal sarcoma t(7;17)(p15-21;q12-21) is a nonrandom chromosome change.

Short-term cultures of four abdominal smooth muscle tumors, three leiomyosarcomas and one leiomyoma, were analyzed cytogenetically. A low-grade malignant, epithelioid leiomyosarcoma had a normal karyotype. The other two leiomyosarcomas had abnormal karyotypes; one was near-diploid, and the other was near-triploid. Structural rearrangements of the short arm of chromosome 16 and monosomies of chromosomes 14, 15, and 22 were observed in both tumors. When our cases and previously published abdominal leiomyosarcomas are viewed in conjunction, loss of chromosomes 14, 15, and 22 are the most frequent abnormalities. The leiomyoma, the second cytogenetically abnormal nonuterine leiomyoma reported to date, had a hyperdiploid karyotype with a chromosome number of 56 and structural rearrangements of chromosomes 9, 14, and 19. The only aberrations similar to those observed in the previously reported esophageal leiomyoma were trisomies of chromosomes 7 and 8.     

Clonal karyotypic abnormalities in colorectal adenomas: Clues to the early genetic events in the adenoma-carcinoma sequence

Cytogenetic analysis of short-term cultures from colorectal adenomas revealed acquired clonal chromosome aberrations in 14 of 17 tumors. In 4 adenomas, only numerical changes were found, whereas 10 had structural rearrangements. Trisomy 7 was found as the sole change in one of the tumors and together with other numerical changes in another. A + 7 was also present in one case with structural aberrations. Other recurrent numerical aberrations were ?14 and ?18, both found in 2 adenomas with structural karyotypic changes; in addition, one chromosome 14 was lost in one of the tumors with only numerical changes. The chromosome most often involved in structural aberrations was chromosome I. In 6 cases, the rearrangements led to changes in l p, always with loss of material. The breakpoints were at l p32–36. One adenoma had deletion of l p as the only change. Other chromosomes that were involved in changes in more than 2 cases were chromosomes 8, 13, and 17. These rearrangements typically led to gain of 8q and 13q and loss of 17p. The adenomas with structural abnormalities were generally larger and had a higher degree of dysplasia than did the adenomas with numerical changes only or those with a normal karyotype. All adenomas with a tubulovillous or villous architecture had structural rearrangements. Our findings confirm that a subset of colorectal adenomas exists that have only numerical chromosome aberrations. They also support our previous conclusion that loss of material from distal l p is an early event in colorectal tumorigenesis, but that other cytogenetic aberrations follow and typically are present already at the adenomatous stage. The accumulation of chromosome-level mutational events in adenomas correlates with the pathologic features: the more malignancy-like the phenotype, the more complex the karyotype. There seems to be no single aberration that distinguishes colorectal adenomas from carcinomas, however. Genes Chromosom Cancer 10:190–196 (1994). © 1994 Wiley-Liss, Inc.     

Spectral karyotyping identifies recurrent complex rearrangements of chromosomes 8, 17, and 20 in osteosarcomas

Conventional cytogenetic studies have shown that osteosarcomas (OSs) are often highly aneuploid, with a large number of both structural and numerical chromosomal alterations. To investigate the complexity of OS karyotypes in detail, we applied spectral karyotyping (SKY) to a series of 14 primary OS tumors and four established OS cell lines. A total of 531 rearrangements were identified by SKY, of which 300 breakpoints could be assigned to a specific chromosome band. There was an average of 38.5 breakpoints identified by SKY per primary tumor. Chromosome 20 was involved in a disproportionately high number of structural rearrangements, with 38 different aberrations being detected. Chromosomal rearrangements between chromosomes 20 and 8 were evident in four tumors. FISH analysis using a 20q13 subtelomeric probe identified frequent involvement of 20q in complex structural rearrangements of OS cell lines. Characterization of the structural aberrations of chromosomes 8 and 17 by use of SKY demonstrated frequent duplication or partial gains of chromosome bands 8q23-24 and 17p11-13. Other chromosomes frequently involved in structural alteration were chromosomes 1 (47 rearrangements) and 6 (38 rearrangements). Centromeric rearrangements often involving chromosomes 1, 6, 13, 14, 17, and 20 were present. Four of the 14 primary OS tumors were characterized by nonclonal changes that included both structural and numerical alterations. In summary, OS tumors have a very high frequency of structural and numerical alterations, compounded by gross changes in ploidy. This intrinsic karyotype instability leads to a diversity of rearrangements and the acquisition of composite chromosomal rearrangements, with the highest frequency of alteration leading to gain of 8q23-24 and 17p11-13 and rearrangement of 20q. These findings suggest that specific sequences mapping to these chromosomal regions will likely have a role in the development and progression of OS.     

Genetic profiling of colorectal cancer liver metastases by combined comparative genomic hybridization and G-banding analysis

The majority of genetic studies of colorectal carcinogenesis have focused on changes found in primary tumors. Despite the fact that liver metastases are a leading cause of colorectal cancer deaths, the molecular genetic basis of the advanced disease stages remains poorly understood. We performed comparative genomic hybridization (CGH) on 17 liver metastases from colorectal carcinomas and compared the quantitative profile with the qualitative profile previously obtained with chromosome banding. An average of 12.6 aberrations per tumor was found by CGH. Chromosome 18 and chromosome arms 4q, 8p, and 17p were most frequently lost, whereas chromosomes 7 and 20 and chromosome arms 6p, 8q, and 13q were most frequently gained. We compared the chromosome banding and CGH data after converting the karyotypes into net copy number gains and losses. Ten tumors showed agreement between the findings of the two techniques, whereas five tumors did not (in two cases, no mitotic cells were obtained for banding analysis). All five discordant cases had a "simple" abnormal or normal karyotype, but revealed multiple changes by CGH. A likely explanation for this discrepancy is that in vitro growth before G-banding selected against the cancer cells. Interestingly, by comparing the CGH profiles of the "complex" vs. the "simple"/normal karyotype groups, deletion of 8p and gain of 16q were seen more frequently in the former group. The liver metastases had the same aberrations as seen in primary colorectal carcinomas, summarized in a literature survey. However, these aberrations were seen more frequently in liver metastases, which may be attributable to increased genetic instability.     

Cytogenetic analysis in human breast carcinoma. II. Seven cases in the triploid/tetraploid range investigated using direct preparations

This report presents karyotypes of seven breast carcinomas with high ploidy from our total of 111 cases. These karyotypes were highly complex and there was no indication of a specific deletion of 16p12----pter as indicated by the previous analysis of some near-diploid tumors. A comparison of numerical changes did not demonstrate a common loss of chromosome #16 as in the near-diploid tumors, but an equivalent loss of chromosomes #8 and #13 was found.     

Karyotypic characterization of urinary bladder transitional cell carcinomas

Samples from 34 primary transitional cell carcinomas (TCCs) of the bladder were short-term-cultured and processed for cytogenetic analysis after G-banding of the chromosomes. Clonal chromosome abnormalities were detected in 27 tumors and normal karyotypes in 3, and the cultures from 4 tumors failed to grow. Losses of genetic material were more common than gains, indicating that loss of tumor suppressor genes may be of major importance in TCC pathogenesis. There was no clonal heterogeneity within individual tumors, consonant with the view that TCCs are monoclonal in origin. The most striking finding was the involvement of chromosome 9 in 92% of the informative cases, as numerical loss of one chromosome copy in 15 cases, but as structural rearrangement in 8. The changes in chromosome 9 always led to loss of material; from 9p, from 9q, or of the entire chromosome. A total of 16 recurrent, unbalanced structural rearrangements were seen, of which del(1)(p11), add(3)(q21), add(5)(q11), del(6)(q13), add(7)(q11), add(11)(p11), i(13)(q10), del(14)(q24), and i(17)(q10) are described here for the first time. The karyotypic imbalances were dominated by losses of the entire or parts of chromosome arms 1p, 9p, 9q, 11p, 13p, and 17p, loss of an entire copy of chromosomes 9, 14, 16, 18, and the Y chromosome, and gains of chromosome arms 1q and 13q and of chromosomes 7 and 20. The chromosome bands and centomeric breakpoints preferentially involved in structural rearrangements were 1q12, 2q11, 5q11, 8q24, 9p13, 9q13, 9q22, 11p11, and 13p10. Rearrangements of 17p and the formation of an i(5)(p10) were associated with more aggressive tumor phenotypes. There was also a general correlation between the tumors' grade/stage and karyotypic complexity, indicating that progressive accumulation of acquired genetic alterations is the driving force behind multistep bladder TCC carcinogenesis.     

A case of acute lymphoblastic leukemia with severe hypodiploidy

A case of acute lymphoblastic leukemia with a severe hypodiploid chromosome constitution is reported. The modal chromosome number was 36, and the karyotype of these cells was 36,X, -X, -2, -3, -5, -7, -9, -12, -13, -15, -16, -17, -20, +21, +mar,del(1) (p13.1p22.3),inv(3)(q13.3q29). In addition to a haploid set, extra copies of chromosomes #6, #10, #14, #18, and #21 were found, as in most cases with severe hypodiploid karyotypes. A second, near-triploid cell line was also observed. An examination of chromosomal heteromorphisms suggested that the severe hypodiploid clone originated either from a near-triploid cell or from a common precursor cell.     

Existence of two distinct processes of chromosomal evolution in near-diploid colorectal tumors

The comparison of all the karyotypes established in each of 18 near-diploid colorectal tumors made it possible to reconstruct a clonal evolution and to distinguish between early and late chromosomal aberrations. Because no abnormalities were observed in all tumors, and as even the most frequent changes, i.e., monosomy 17p and monosomy 18, may be present in mosaic, no chromosomal change can be regarded as a common primary event in the carcinogenetic process. However, the repeated occurrence of several changes favors the hypothesis of two karyotypic evolutionary processes. In most tumors, monosomy 17p and 18 were found, and the karyotypic evolution involved mainly several additional monosomies due to unbalanced rearrangements or losses that affect, by order of decreasing frequency, chromosomes 1p, 4, 14, 5q, 6q, 2p, and 11q, as well as gains of chromosomes 20, 8q, 13, 17q, and X. In this group of tumors, the mean number of chromosomes remains close to 46. In the other tumors, either only a monosomy 17p or a monosomy 18 was found and the karyotypic evolution involved essentially trisomies, resulting from gains with, by order of decreasing frequency, a preferential involvement of chromosomes 7, 8q, 13, 17q, 20, X, 2p, 5, and 16, the only additional recurrent deletion affecting chromosome 1p. In these tumors, the mean chromosome number is close to 51. Ten out of 11 polyploid sidelines emerged from monosomic-type tumors.     

Near-Diploid karyotypes with recurrent chromosome abnormalities characterize early-stage endometrial cancer

Cytogenetic investigation was attempted on 15 endometrial tumors. Whenever possible, a combination of direct harvesting and short-term culture (with or without prior methotrexate synchronization) was used. The analysis was successful in 13 cases: 12 carcinomas of stage I and one atypical hyperplasia. Clonal abnormalities were found in 10 tumors, whereas the remaining three showed a normal karyotype. The modal chromosome number was near-diploid. The abnormal karyotypes contained relatively simple numerical or structural aberrations in all but one tumor, a serous papillary carcinoma with multiple complex changes as well as cytogenetic evidence of intratumor heterogeneity. Gain of 1q, trisomy for chromosomes 2, 7, 10 (this trisomy was shown by in situ hybridization to be present also in a large number of interphase cells), and 12, and loss of chromosome 22 were recurrent aberrations; these are also the cytogenetic anomalies that have been consistently associated with endometrial carcinomas in previous studies. The utilization of both direct harvesting and short-term culture in several cases increased the frequency with which abnormal karyotypes were found; sometimes aberrations were found by the first method but not by the other, and vice versa. Never were different clonal anomalies found by the two approaches in the same case. Synchronization of the cultures generally led to chromosome preparations with more mitoses and of better quality. Again, no different anomalies were found in synchronized and standard cultures from the same tumor.     

Chromosome features of two retinoblastomas

Giemsa-banded chromosomal analysis of two unilateral retinoblastoma tumors from unrelated patients with normal constitutional chromosomes revealed near-diploid karyotypes with multiple structural rearrangements. The two tumors shared aberrations of trisomy 1q, monosomy 16 and 17, and 21p+. Other aberrations were unique to each tumor. One tumor expressed a del(13) and trisomy 6p.     

Genomic aberrations in pediatric gliomas and embryonal tumors

The pathogenesis of pediatric central nervous system tumors is poorly understood. To increase knowledge about the genetic mechanisms underlying these tumors, we performed genome-wide screening of 17 pediatric gliomas and embryonal tumors combining G-band karyotyping and array comparative genomic hybridization (aCGH). G-banding revealed abnormal karyotypes in 56% of tumor samples (9 of 16; one failed in culture), whereas aCGH found copy number aberrations in all 13 tumors examined. Pilocytic astrocytomas (n = 3) showed normal karyotypes or nonrecurrent translocations by karyotyping but the well-established recurrent gain of 7q34 and 19p13.3 by aCGH. Our series included one anaplastic oligoastrocytoma, a tumor type not previously characterized genomically in children, and one anaplastic neuroepithelial tumor (probably an oligoastrocytoma); both showed loss of chromosome 14 by G-banding and structural aberrations of 6q and loss of 14q, 17p, and 22q by aCGH. Three of five supratentorial primitive neuroectodermal tumors showed aberrant karyotypes: two were near-diploid with mainly structural changes and one was near-triploid with several trisomies. aCGH confirmed these findings and revealed additional recurrent gains of 1q21-44 and losses of 3p21, 3q26, and 8p23. We describe cytogenetically for the first time a cribriform neuroepithelial tumor, a recently identified variant of atypical teratoid/rhabdoid tumor with a favorable prognosis, which showed loss of 1p33, 4q13.2, 10p12.31, 10q11.22, and 22q by aCGH. This study indicates the existence of distinct cytogenetic patterns in pediatric gliomas and embryonal tumors; however, further studies of these rare tumors using a multimodal approach are required before their true genomic aberration pattern can be finally established.     

Polyploidization and losses of chromosomes 1, 2, 6, 10, 13, and 17 in three cases of chromophobe renal cell carcinomas

Clonal chromosome aberrations identified after short-term culture are presented for three cases of chromophobe renal cell carcinomas (RCC). All tumors revealed abnormal karyotypes with a varying proportion of polyploid tumor cells. Common numerical abnormalities were combined losses of chromosomes 1, 2, 6, 10, 13, and 17. Clonal karyotypic evolution was demonstrated in one case in which several related clones could be identified. An additional balanced translocation t(3;14)(p24;q22) observed in this case proved to be of constitutional nature by cytogenetic analysis of normal kidney cells and peripheral blood lymphocytes. These cytogenetic findings provide further evidence that chromophobe renal cell carcinomas are characterized by a highly specific combination of chromosomal losses most commonly including chromosomes 1, 2, 6, 10, 13, and 17.     

Nonrandom karyotypic features in basal cell carcinomas of the skin.

Cytogenetic analysis of short-term cultured 44 basal cell carcinomas (BCC) revealed clonal karyotypic abnormalities in 38 tumors. Relatively complex karyotypes (at least four structural and/or numerical changes per clone) with unbalanced structural as well as numerical aberrations were found in eight (approximately 21%) of the BCC, while the remaining BCC (79%) had simple karyotypes (1 to 3 aberrations per clone). Numerical changes only were found in 16 tumors, 15 BCC displayed both numerical and structural aberrations, and the remaining 7 BCC showed only structural aberrations. Extensive intratumoral heterogeneity, in the form of cytogenetically unrelated clones, was found in 21 tumors, whereas related subclones were present in 10 tumors. In order to obtain an overall karyotypic picture in BCC, the findings of our previously published 25 BCC have been reviewed. Our combined data indicate that BCC are characterized by nonrandom karyotypic patterns. A large subset of BCC is characterized by nonrandom numerical changes, notably, +18, +X, +7, and +9. Structural rearrangements often affect chromosomes 1, 4, 2, 3, 9, 7, 16, and 17. A number of chromosomal bands are frequently involved, including 9q22, 1p32, 1p22, 1q11, 1q21, 2q11, 4q21, 4q31, 1p36, 2q37, 3q13, 7q11, 11p15, 16p13, 16q24, 17q21, and 20q13. When the genomic imbalance is assessed, it has been shown that several chromosome segments are repeatedly involved in losses, namely loss of the distal part of 6q, 13q, 4q, 1q, 8q, and 9p. A correlation analysis between the karyotypic patterns and the clinico-histopathologic parameters has been undertaken in the 44 BCC of the present series. The cytogenetic patterns show a significant correlation with tumor status (P=.025), that is, that cytogenetically more complex tumors are also those clinically the most aggressive. Also, the frequency of cytogenetically unrelated clones is significantly higher in recurrent BCC than that in primary lesions (P=.05). No clear-cut association has been found between the karyotypic patterns and histologic subtypes or tumor sites.