MUC1 is activated in a B-cell lymphoma by the t(1;14)(q21;q32) translocation and is rearranged and amplified in B-cell lymphoma subsets.

The band 1q21 is among the most common sites affected by chromosomal translocations in lymphoid, myeloid, epithelial, and sarcomatous lesions. In non-Hodgkin's lymphoma (NHL), translocations and duplications affecting this chromosomal site are frequently, but not exclusively, seen in association with primary abnormalities such as the t(14;18)(q32;q21) and t(8;14)(q24;q32) translocations, suggesting a role for 1q21 rearrangements in tumor progression. We report here the characterization and cloning of breakpoints in a case of extranodal ascitic B-cell lymphoma with a t(1;14)(q21;q32) translocation. The breakpoints on the der(1) and der(14) chromosomes were mapped by fluorescence in situ hybridization and Southern blot analysis and cloned using an IGHG (Cgamma) probe. The translocation linked the IGHG4 switch (Sgamma4) sequences of the productively rearranged allele to chromosome 1 sequences downstream of MUC1, leaving the MUC1 transcriptional unit intact. MUC1 was markedly overexpressed in the tumor at the mRNA and protein levels relative to lymphoma cell lines lacking a 1q21 rearrangement. Presumably, MUC1 transcription is aberrantly regulated by the IGHA (Calpha) 3' enhancer element retained on the same chromosome. Screening of a panel of B-cell lymphomas by Southern blot analysis identified a subset with a 3' MUC1 breakpoint and another with low-level amplification of MUC1. MUC-1 mucin has previously been shown to be frequently overexpressed in human epithelial cancers and to be associated with tumor progression and poor clinical outcome. Thus, MUC1 activation by chromosomal translocation, rearrangement, and amplification, identified here for the first time in NHL, is consistent with its suggested role in tumorigenesis. (Blood. 2000;95:2666-2671)

Chromosomal and gene amplification in diffuse large B-cell lymphoma.

Chromosomal translocations leading to deregulation of specific oncogenes characterize approximately 50% of cases of diffuse large B-cell lymphomas (DLBL). To characterize additional genetic features that may be of value in delineating the clinical characteristics of DLBL, we studied a panel of 96 cases at diagnosis consecutively ascertained at the Memorial Sloan-Kettering Cancer Center (MSKCC) for incidence of gene amplification, a genetic abnormality previously shown to be associated with tumor progression and clinical outcome. A subset of 20 cases was subjected to comparative genomic hybridization (CGH) analysis, which identified nine sites of chromosomal amplification (1q21-23, 2p12-16, 8q24, 9q34, 12q12-14, 13q32, 16p12, 18q21-22, and 22q12). Candidate amplified genes mapped to these sites were selected for further analysis based on their known roles in lymphoid cell and lymphoma development, and/or history of amplification in tumors. Probes for six genes, which fulfilled these criteria, REL (2p12-16), MYC (8q24), BCL2 (18q21), GLI, CDK4, and MDM2 (12q13-14), were used in a quantitative Southern blotting analysis of the 96 DLBL DNAs. Each of these genes was amplified (four or more copies) with incidence ranging from 11% to 23%. This analysis is consistent with our previous finding that REL amplification is associated with extranodal presentation. In addition, BCL2 rearrangement and/or REL, MYC, BCL2, GLI, CDK4, and MDM2 amplification was associated with advanced stage disease. These data show, for the first time, that amplification of chromosomal regions and genes is a frequent phenomenon in DLBL and demonstrates their potential significance in lymphomagenesis.

REL proto-oncogene is frequently amplified in extranodal diffuse large cell lymphoma.

Comparative genomic hybridization (CGH) analysis of DNA extracted from a diffuse lymphoma with a large cell component (DLLC) that displayed double minute chromosomes upon conventional karyotypic analysis indicated overt amplification of DNA sequences derived from the 2p13-15 region. Southern blot analysis of this tumor DNA with a cDNA probe for the proto-oncogene REL, previously mapped to 2p14-15, indicated a greater than 35-fold amplification of REL. To determine the incidence of REL amplification and possible clinical or histologic association with DLLC, a panel of 111 tumor DNAs from DLLC specimens was screened for REL amplification by Southern blot analysis. A copy number of > or = 4 was noted in 26 cases (23%). Southern blot analysis of these 26 tumor DNAs with a cDNA probe for TGFA, mapped to 2p13, indicated lack of coamplification except in one case. Another member of the Rel/NF-kappa B family of transcriptional activators, RELA/p65 mapped to 11q13, was amplified in five cases as determined by Southern blot analysis using a cDNA probe. Nineteen of the 26 DLLC (73%) with REL amplification were primary extranodal lymphomas. As a group, the tumors with REL amplification demonstrated an increased frequency of chromosomal aberrations previously associated with tumor progression, suggesting an oncogenic effect of amplified REL in B-lymphoid cells that already contained a transforming genetic lesion. Thus, REL amplification is a frequent event in DLLC, and probably constitutes a progression-associated marker of primary extranodal lymphomas. This study shows the usefulness of the CGH technique in identifying chromosomal regions overrepresented in tumors that can point to amplified genes and may be correlated with clinical features of the disease.

Homozygous deletions and loss of expression of the CDKN2 gene occur frequently in head and neck squamous cell carcinoma cell lines but infrequently in primary tumors.

Deletion of 9p21-22 is a common genetic alteration in dysplastic, in situ, and invasive head and neck squamous cell carcinoma (HNSCC). However, a candidate tumor suppressor gene (TSG) at this site has thus far not been identified in HNSCC. We report homozygous deletion of the recently identified multiple tumor suppressor I (MTSI)/cyclin-dependent kinase-4-inhibitor (CDKN2) gene mapped to 9p21, which encodes the p16 protein, a regulator of cyclin-dependent kinase 4, in six of 16 HNSCC cell lines. We also show absence of the CDKN2 mRNA in all cell lines with CDKN2 deletion as well as in an additional two cell lines without deletion. Overall, we have identified 9p abnormalities in 12 of 16 (75%) cell lines, at least nine of which involved CDKN2. We further demonstrate that the CDKN2 deletion in HNSCC is located within a previously described region of allelic loss between D9S171 and IFNW, which spans a 4 cM region of 9p. However, examination of 36 primary tumors revealed genetic alterations in only seven of 36 (19%) tumors. These results suggest that genetic alterations at CDKN2 are frequent in HNSCC cell lines, but the role of this gene in primary tumors is less compelling. CDKN2 does not appear to be the only TSG on 9p21 in HNSCC, and our results suggest that another region of deletion exists proximal to the IFNW locus.