Karyotypic abnormalities and clinical aspects of patients with multiple myeloma and related paraproteinemic disorders.

Karyotypic abnormalities were detected in the malignant cells of 6 of 18 patients with multiple myeloma (MM). Six patients with benign monoclonal gammopathy, one with amyloidosis of immunoglobulin origin, and two with Waldenstr?m's macroglobulinemia had normal karyotypes. All six MM patients with aneuploidy were in a group of 10 patients in an accelerated or relapse phase of their disease and four had high serum paraprotein levels (7.92, 6.24, 6.80, and 4.24 g/dl, respectively) when their abnormal karyotypes were detected. Five of the 6 MM patients with aneuploidy had received prior chemotherapy. Aneuploidy was not observed in 8 stable MM patients. Abnormalities of chromosome 14 were present in all 6 patients, with a 14q+ marker in 5 and loss of No. 14 in 1. A translocation between Nos. 11 and 14 was found in aneuploid cells of 2 patients who had plasma cell leukemia (PCL). However, the break point in the long arm of No. 11 differed in the 2 patients. A gain of Nos. 5, 9, and 11 was seen in 3 patients, a gain of No 1 in 2, and rearrangements of No. 1 in 5 MM patients, including all 4 who had a 14q+ marker chromosome initially. A deletion of chromosome 6 at band q25 was detected in 2 MM patients and a pericentric inversion of No. 6 (6p21 to 6q13) was seen in the patient with PCL. Three of 4 MM patients had a nonrandom loss of one chromosome 8. Two other MM patients, who were treated with melphalan and prednisone, developed acute nonlymphocytic leukemia (ANLL) 2+ and 4+ years after the diagnosis of MM. Marrow cells of one patient showed a 5q- chromosome and a constitutional translocation involving Nos. 13 and 14 during the preleukemic stage; during the leukemic phase, the karyotype evolved to 50 chromosomes including extra chromosomes 1, 6, 8, 10, and 21 and a missing 7, in addition to the originally detected 5q- and the 13/14 translocation. The peripheral blood from the other patient was hypodiploid, with a missing chromosome 7 and a translocation between 3q and 9p. These patterns of chromosome change resemble those of ANLL rather than MM and are similar to the changes seen in ANLL after treated malignant lymphoma.     

Adult T-cell leukemia. Chromosome analysis of 15 cases

Chromosome studies was conducted on 15 patients with adult T-cell leukemia. Cells with chromosomal abnormality were seen in 14 of the 15 patients. The modal chromosome number was near diploid range in all the patients. The most common abnormality was 14q+ marker chromosome and partial deletion of the long arm of chromosome 6, i.e., 6q-, which were seen in eight and seven cases, respectively. Donor chromosomes involved in the 14q+ marker chromosome varies, i.e., Yq, #5p, #5q, #9q, #10q or #12q, except for two patients whose donor chromosome origins were unable to determine. The break point in 14q+ marker chromosome was band at q32. The 6q- chromosome was due to a deletion in one patient and interstitial deletion in six patients. A 14q- chromosome having break point at q24 was found in one patient and duplication of Yq chromosome in two patients. In addition, four patients showed a 5q- chromosome or a 9q- chromosome which was due to a translocation or deletion. The significance of these chromosome abnormalities was discussed.     

Nonrandom rearrangement of chromosome 14 at band q32.33 in human lymphoid malignancies with mature B-cell phenotype

Chromosomes were studied in 61 patients with differentiated B-cell malignancies including 21 with non-Hodgkin's lymphoma (NHL), three with hairy cell leukemia (HCL), eight with Waldenstr?m's macroglobulinemia (WM), and 29 with plasma cell disorder. Chromosomally abnormal clones were identified in 35 of 61 patients studied: all with NHL, all with HCL, three of eight with WM, and eight of 29 with plasma cell disorder. The most recurrent chromosomal abnormality, observed in 26 of the 35 patients whose chromosomes were abnormal, was a rearrangement involving chromosome 14, in which an additional segment was attached at band 32 in the long arm to form a 14q+ marker chromosome. This rearrangement was seen in 17 patients with NHL, three with HCL, one with WM, and five with plasma cell disorder. In NHL, the rearrangement correlates with histological subclasses: t(14;18) in all four patients with malignant lymphoma (ML)-follicular, mixed small cleaved and large cell; t(8;14) or its variant form, t(8;22), in all six with ML-small noncleaved cell; and t(11;14) in two of three with ML-diffuse, mixed small and large cell. A t(14;18) was also found in each patient with ML-diffuse, large cell, WM, and multiple myeloma, and a variant three-way translocation, t(5;18;14) (q13;q21;q32), in one with ML-diffuse, small cleaved cell. The donor sites for these 14q+ were assigned to oncogene loci: c-myc (8q24), bcl-1 (11q13), and bcl-2 (18q21). Moreover, the donor sites were also located near immunoglobulin light chain gene loci in each patient with leukemic ML-diffuse, mixed small and large cell, t(2;14) (p13;q32.3), and HCL, t(14;22)(q32.3;q11.2). These findings suggest that chimeric DNA formation, not only between an immunoglobulin gene and a certain oncogene, but also between the IgH gene and one of the IgL genes may be potentially relevant in malignant B-cell proliferation.     

Characteristic chromosomal abnormalities in biopsies and lymphoid-cell lines from patients with burkitt and non-burkitt lymphomas

The karyotypes of cells from 10 Burkitt lymphoma (BL) biopsies, eight cell lines established from BL and nine cell lines from non-BL sources were studied by chromosome banding techniques. With the exception of the BL-derived cell lines BJAB, GC-BJAB, Maku and U-8691 all biopsies and lines of Burkitt origin contained an extra band at the distal region of the long arm of one chromosome 14. An extra band on chromosome 14 was also found in cells of one non-BL biopsy, in cells from a lymphosarcoma-derived cell line and in a longestablished cell line derived from the pleural exudate of a patient with Hodgkin's disease. A distal region at the long arm of one chromosome 8 was missing in all metaphase figures of good technical quality in the same material. The size, morphology and stainability of missing region corresponded fairly well to the extra region at chromosome 14. We therefore suggest that the chromosome 14 marker represents a translocation between chromosomes 8 and 14,t (8q-; 14q+). The translocation was present neither in lymphocytes of peripheral blood of five Burkitt patients nor in five lymphoblastoid cell lines of non-BL origin. Trisomy 7 was found in two of the 10 BL biopsies, in two BL-derived cell lines, in one non-BL biopsy, in two lymphosarcoma-derived cell lines and in one cell line derived from a patient with Hodgkin's disease.     

A 14q+ chromosome in a B-cell acute lymphocytic leukemia and in a luekemic non-endemic Burkitt lymphoma.

Chromosome analysis using banding staining techniques was carried out on cells from a B-cell acute lymphocytic leukemia (ALL) of the Burkitt type and a case of non-endemic Burkitt lymphoma presenting as ALL. In both patients a marker chomo-some 14q+ was found which was morphologically identical to those reported for endemic and non-endemic Burkitt lymphoma and a few other B-cell malignancies. However, the origin of the translocated segment could not be identified in either case. In addition, both patients had a 13q+ chromosome with a breakpoint in the 13q3 region but involving different material of unknown origin. Other marker chromosomes in the B-cell ALL included rearrangements of chromosome arms 1q and 6q. Serial studies showed that cells with a partial duplication of the long arm of chromosome No. 1, in addition to the 14q+ chromosome, were important in the karyotype evolution of the malignant cell population. In this patient the 14q + chromosome had a brightly fluorescing satellite region indicating the probable monoclonal development of the leukemic cell population. From this and other reports it appears that the B-cell type of ALL is characterized by a 14q+ chromosome. Because of the pathological and cytogenetic similarities between certain types of B-cell ALL and Burkitt lymphoma it is suggested that they may be different manifestations of the same disorder.     

Chromosome abnormalities in tumor cells from patients with sporadic Wilms' tumor

The karyotype of nine of 11 Wilms' tumors was successfully analyzed using chromosome banding techniques. Peripheral lymphocytes had a normal karyotype in all six analyzed cases. Cultured cells from one tumor had a normal karyotype; however, they appeared to be fibroblasts. A chromosome 11 deletion, del(11)(p13p14), similar to that seen in patients with sporadic aniridia, was found as the sole abnormality in cells from one tumor. Abnormalities of chromosome 1 resulting in trisomy for the long arm (q21-q31) were found in five cases. Two of them had a translocation involving 1q and 16q, although the breakpoints in each chromosome appeared to differ in the two cases. Two patients had an isochromosome of the long arm, i(1q), and a fifth case had a duplication of the long arm as a result of karyotypic evolution. Chromosome 16 abnormalities were found in three cases, resulting in the partial monosomy of the long arm, sharing q22 as a common deletion. The same three cases also had trisomy 1q due to an unbalanced translocation of 1q or an i(1q). Trisomy for both chromosomes 9 and 12 were present in three cases. Two patients each had whole or partial trisomy of chromosomes 6, 7, 8, 17, and 18. Our data show that although an 11p deletion can occur as a mutation confined to tumor cells, the most common changes are trisomy for 1q, and less often a deletion of 16q.     

Acute monocytic leukemia chromosome studies

Cytogenetic studies have been performed on 34 acute monocytic leukemia (M5) patients, 24 of the a type and 10 of the b type. No chromosomal abnormalities were found in 12 cases, in spite of the fact that the mitoses concerned monocytes. Different chromosomal aberrations were present in the other cases. In 12 of them, an abnormality of the chromosome 11 long arm was observed (mainly in the poorly differentiated type of M5), on bands q22–q24 in nine cases and on band q14 in three cases. The chromosome 11 long arm thus appears preferentially rearranged in M5 although this is not apparent in every case. Concomitant study of the mitoses with cytological and cytogenetic techniques suggests that erythroblasts may not be involved in the M5 leukemic process.     

Extra translocation +der(1q9p) is a prognostic indicator in myeloproliferative disorders.

An identical extra derivative chromosome resulting from a translocation between the long arm of chromosome 1 and the short arm of chromosome 9, +der(1q9p), has been observed in three patients with a myeloproliferative disorder. Two patients had polycythemia vera in transformation (erythroleukemia in one patient and refractory anemia in the second), whereas the third patient had myelofibrosis which later evolved into acute myelomonocytic leukemia. The two patients who developed overt leukemia did not receive any previous cytotoxic treatment. Non-isotopic in situ hybridization was performed in two patients, allowing for the localization of the breakpoints in 1q12 and 9q12. A similar rearrangement has been previously described in patients with polycythemia vera, either at diagnosis or in advanced stages of the disease. These data suggest that this chromosome abnormality may be consistently associated with myeloproliferative disorders showing a high propensity to transformation, which is not treatment related, and the finding of the +der(1q9p) may represent a poor prognostic sign when observed in the chronic phase.     

肺癌染色体遗传标记 2q~- 在癌变和发展中的意义

目的研究肺癌发生过程中的细胞遗传学改变，探讨肺癌发生的遗传学机理。方法应用荧光原位杂交（ＦＩＳＨ）技术，对１例已永生化并趋于恶性的人支气管上皮细胞系Ｍ，以及１２例临床原发非小细胞肺癌（ＮＳＣＬＣ）标本中２号和３号染色体改变进行了研究。结果２ｑ－和３ｐ－高频发生。Ｍ细胞系的晚期代数ＭＰ７１及检测的７例ＮＳＣＬＣ标本中的３例有２ｑ－，Ｍ细胞系及１２例标本中的５例有３ｐ－。结论２ｑ－也是肺癌中高发的细胞遗传学改变。可能在２ｑ上存在一个或几个肿瘤抑制基因，其丢失可导致ＮＳＣＬＣ的发生和发展。     

Regional deletion and amplification on chromosome 6 in a uveal melanoma case without abnormalities on chromosomes 1p, 3 and 8

Uveal melanoma (UM) is the most common primary intraocular malignancy in adults. Loss of the long arm and gain of the short arm of chromosome 6 are frequently observed chromosomal aberrations in UM, together with loss of chromosome 1p36, loss of chromosome 3 and gain of chromosome 8. This suggests the presence of one or more oncogenes on 6p and tumor suppressor genes at 6q that are involved in UM development. Both regions, however, have not been well defined yet. Furthermore in other neoplasms gain of 6p and loss of 6q are frequently occurring events. In this case report, we describe the delineation of a partial gain on chromosome 6p and a partial deletion on 6q in a UM with the objective to pinpoint smaller candidate regions on chromosome 6 involved in UM development. Conventional cytogenetics, comparative genomic hybridization (CGH) and fluorescence in-situ hybridization (FISH) were used to delineate regions of loss and gain on chromosome 6 in this UM patient. With conventional cytogenetics a deleted region was found on chromosome 6q that was further delineated to a region ranging from 6q16.1 to 6q22 using CGH and FISH. A region of gain from 6pter to 6p21.2 was also demarcated with CGH and FISH. No other deletions or amplifications on recurrently involved chromosomes were found in this patient. This study indicates the presence of one or more tumor suppressor genes on chromosomal region 6q16.1-6q22 and the presence of one or more oncogenes on chromosomal region 6pter-6p21.2, which are likely to be important in UM and other tumors.     

Chromosome abnormalities in patients with hairy cell leukemia

We evaluated chromosomes from 20 patients with hairy cell leukemia (HCL) to ascertain the frequency and type of consistent chromosomal abnormalities. Samples from 17 patients were obtained from peripheral blood cultures grown 24 and 48 hours without phytohemagglutinin, or from bone marrow samples. Two male patients had similar, consistent abnormalities; one patient's karyotype was 46,X,+12; that of the second was 46,X,+C marker. In the latter case, the distal long arm of the C marker most closely resembled chromosome No. 12 from band q14 to q terminal, but the short arm and proximal long arm were of undetermined origin. Both karyotypes lacked the Y chromosome. A third patient had, in one sample, a single abnormal cell with an extra No. 3 and an extra No. 12 (48,XY,+3,+12), and in a later sample, a second cell of poor morphology which also could have been trisomic for no. 12. The two patients with consistent chromosome abnormalities had rapidly progressive disease and a relatively short clinical course from the time of diagnosis (5 and 7 months, respectively). Further data are needed, but the results thus far suggest that patients with consistent chromosome abnormalities could be considered as candidates for aggressive combination chemotherapy.     

14q translocations, having a break point at 14q13, in lymphoid malignancy.

In three patients with non-Hodgkin lymphomas and in one cell line (HPL-Hod) derived from pleural effusion cells of a patient with Hodgkin's disease, rearrangements of the long arm of chromosome No. 14(14q) were observed. These rearrangements appeared to be consistently associated with a 14q translocation, suggestive of occurrence of a break at 14q13. The translocation in an individual case could occur with 1p, 2q, 4q, and another 14q. A 14q13 translocation may be comparable with a 14q32 translocation, which has often been observed in various types of lymphoid malignancy.     

Nonrandom chromosomal abnormalities in primary uveal melanoma

We report on 14 cases of clonal chromosomal anomalies in patients with primary uveal melanoma. An increased dosage of chromosome 8 or of parts of the long arm of chromosome 8 (8q) were detected in eight patients (57%). The smallest multiplied area of 8q appeared to be the region 8q2.1----qter. Monosomy of chromosome 3 was seen in six patients (43%), five of which were associated with anomalies of chromosome 8. Increased dosage of parts of chromosome 8q and loss of heterozygosity of chromosome 3, or the combination of both, seemed to be nonrandom for uveal melanoma and may distinguish it genetically from cutaneous malignant melanoma. Anomalies of chromosome 6, mostly resulting in additional material of 6p or a deletion of 6q, were found in six patients (43%). These anomalies, which seem to be common features of cutaneous malignant melanoma, were considered secondary rather than primary changes in uveal melanoma, since they were present only in subclones in most cases. Loss of the Y chromosome, restricted to tumor cells, was detected in four male patients, and loss of one X chromosome was detected in a female patient.     

Frequency and pattern of karyotypic abnormalities in human prostate cancer

The cytogenetic evaluation of 30 cultured primary prostatic cancer specimens obtained during radical prostatectomies of patients with relatively early stage disease is reported. The majority of specimens examined showed a normal male karyotype, 46,XY. Nine samples contained clonally abnormal populations including five specimens which were hyperdiploid (modal range, 65-92 chromosomes), one specimen containing double minute chromosomes, and three containing structural aberrations. Loss of the Y chromosome and a partial trisomy for chromosome 4 was observed in a sample from one patient. Another sample showed a translocation between the long arms of chromosomes 5 and 7. The only tumor obtained from a previously irradiated patient contained no normal cells, a modal chromosome number of 45, loss of chromosomes 2 and Y, and multiple structural rearrangements. The appearance of any clonal cytogenetic abnormality correlated in general with a poorly differentiated state of cancer. A survey of all available previous cytogenetic data on human prostate adenocarcinoma indicated that the loss of chromosomes 1, 2, 5, and Y, the gain of chromosomes 7, 14, 20, and 22, and rearrangements involving chromosome arms 2p, 7q, and 10q are the most common changes observed. This suggests that, although the assignment of a single chromosomal aberration as a marker for early stage prostatic cancer is unlikely, several consistent "hotspots" might be of significance in the etiology of this disease.     

Chromosome 14 translocations in non-Burkitt lymphomas.

Chromosome studies were performed on malignant cells obtained from 27 patients with non-Burkitt lymphomas. A marker chromosome affecting the long arm of No. 14 (14q+) was the single most frequent abnormality and was noted in 17 of these patients. The frequency of the 14q+ marker varied with the type of lymphoma. For patients with malignant lymphoma, histiocytic, the frequency was 5 of 8; for mixed-cell type, 1 of 3; for poorly differentiated lymphocytic, 8 of 8; for well-differentiated lymphocytic, 0 of 3; for lymphoblastic, 0 of 1; for Hodgkin's disease, 2 of 3; and for mycosis fungoides, 1 of 1. The donor chromosome involved in the 14q translocation was identified in 12 cases; certain chromosomes appeared to be affected more frequently than others. Although the break point was band 14q32 in most cases, the exact location of the receptor site on 14q was not always consistent. The distal part of 14q24 was also involved as a receptor site in at least one translocation. These findings suggest that, in some types of lymphoid malignancy, cells with a 14q translocation have a proliferative advantage over cells with other chromosome rearrangments. The presence of the 14q translocation may be important in the future for the distinction among morphologically different, but functionally comparable, subgroups of lymphoid malignancies.     

Allelic loss of a common microsatellite marker MYCL1: a useful prognostic factor of poor outcomes in colorectal cancer.

PURPOSE: Allelic loss involving chromosome arms 5q, 8p, 17p, and 18q is commonly detected in colorectal cancer (CRC). The short arm of chromosome 1 is also frequently affected in a whole range of cancer types, including CRC. Our aim in the present study was to determine whether allelic losses on 1p were likely to be of much value in predicting the prognosis of CRC cases. EXPERIMENTAL DESIGN: Genomic DNA was prepared from tumor and corresponding normal tissue specimens from 90 patients who had undergone curative resection for CRC. Loss of heterozygosity (LOH) on chromosome arms 1p, 2p, 5q, 7q, 8p, 17p, 17q, and 18q was examined using 14 microsatellite markers, and possible correlations between LOH and clinicopathological factors (including tumor recurrence and patient survival) were investigated. LOH at the MYCL1 microsatellite marker at 1p34 was detected in 12 of 74 (16.2%) patients who were informative for this marker. RESULTS: After controlling for tumor stage and gender and excluding findings for patients with remote metastasis, we found that patients who were positive for LOH at MYCL1 were 31 times more likely to experience recurrence than those who were negative for LOH at this locus (95% confidence intervals, 2.27- infinity; P = 0.04). There were indications of a similar tendency for LOH at the 14-3-3-sigma-TG microsatellite marker at 1p35, but we could find no evidence of a significant association between LOH at this site and tumor recurrence or patient survival. We were also unable to detect significant association between LOH at the various sites on 2p, 5q, 7q, 8p, 17p, 17q, and 18q and either tumor recurrence or patient survival. CONCLUSIONS: CRC patients whose tumors exhibited LOH at MYCL1 at chromosome 1p34 were likely to have a poor prognosis, suggesting that this marker may have clinical relevance.     

肺癌染色体遗传记2q^—在癌变和发展中的意义

研究肺癌发生过程中的细胞遗传学改变,探讨肺癌发生的遗传学机理。应用荧光原位杂交技术,对１例已永生化并趋于恶性的人支气管上皮细胞系Ｍ,以及１２例临床原发非小细胞肺癌标本中２号和３号染色体改变进行了研究。     

Chromosome changes in desmoid tumors developed in patients with familial adenomatous polyposis.

Chromosome analyses were performed on benign desmoid tumors obtained from two female patients with familial adenomatous polyposis (FAP), one of whom was diagnosed as having Gardner syndrome (GS). The modal chromosome number was 46 in both specimens, and detailed Q-banding analysis in Case 1 (GS) revealed a clonal abnormality of an interstitial deletion of the long arm of chromosome 5, del(5)(q21q31). The deleted region included an assigned locus for an FAP major gene (5q21-q22). All of the metaphases analyzed in this case showed an extra segment of bright fluorescence on the short arm of chromosome 15, but this unusual chromosome (15p+) was observed in both peripheral lymphocyte and skin fibroblast cultures from the patient, indicating that the 15p+ was constitutional in nature. In Case 2, no clonal rearrangements were identified and most cells had a normal karyotype. However, two cells showed rearrangements involving a 17q with non-identical breakpoints, one of which was observed as a solitary chromosome change. Based on the present findings in Case 1 and those reported so far, the chromosomal defect on 5q might be one of the causal genetic events primarily associated with the development of both benign desmoid tumors and colorectal adenomas and carcinomas in FAP patients.     

High frequency of allelic imbalance at chromosome region 16q22-23 in human breast cancer: Correlation with high pgr and low s phase

The loss of genetic material from a specific chromosome region in tumors suggests the presence of tumor-suppressor genes. Loss of heterozygosity (LOH) or allelic imbalance (AI) on the long arm of chromosome 16 is a known event in sporadic breast cancer. To locate the commonly deleted regions, and therefore (a) candidate tumor-suppressor gene(s), a deletion map of chromosome 16 was made, using 10 microsatellite markers on 150 sporadic breast tumors. The 3 smallest regions of overlap (SRO) were detected on the long arm of chromosome 16. Allelic imbalance was observed with at least one marker in 67% of the tumors. One marker, D16S421, at the 16q22-23 region, showed the highest allelic imbalance, 58%. Tumors with and without AI on 16q were tested for correlation with clinico-pathological features of the tumors such as estrogen- and progesterone-receptor content (ER and PgR), age at diagnosis, tumor size, node status, histological type, S-phase fraction, AI on chromosome 3p, and ploidy. A correlation was found between AI on 16q and high PgR content, also low S-phase fraction (99% confidence limits). A comparison of tumors with and without AI at the D16S421 marker locus revealed a slight correlation with high PgR content. The survival data showed no difference between patients with AI on 16q and those with a normal allele pattern on the long arm of chromosome 16. © 1995 Wiley-Liss, Inc.     

Loss of heterozygosity at selective sites on chromosomes 13 and 17 in human breast carcinoma.

Four chromosomal regions were tested for loss of constitutional heterozygosity in primary tumours from 85 Icelandic breast cancer patients. Loss of heterozygosity and other types of gene rearrangements were observed in 37% of informative cases at the retinoblastoma locus, RB1, on chromosome 13q. Allele losses on chromosome 17 were tested with two polymorphic probes on 17p and two on 17q. Loss of heterozygosity or other types of genetic rearrangement were detected in 43.5% of cases on 17p near the p53 gene and 40.5% on 17q. In our study abnormalities at the RB1 locus and on chromosome 17 frequently occurred together, indicating that the coincident inactivation of more than one tumour suppressor gene may, in some cases, play a part in tumour formation. No significant correlation was found between these losses and clinico-histological parameters. Family history of breast cancer was found to be more common among patients with RB1 deletions and this trend was strengthened in cases where there were deletions at both the RB1 locus and on chromosome 17.