Defining regions of loss of heterozygosity of 16q in breast cancer cell lines

The loss of heterozygosity (LOH) of chromosome 16 was assessed in 21 breast cancer cell lines and two nontumorigenic breast epithelial cell lines by typing microsatellite markers distributed on this chromosome. In addition, dual-color fluorescence in situ hybridization was used to metaphase spreads of these cell lines using chromosome 16 paint and region specific probes. Eleven of the cell lines had LOH for chromosome 16, two for the entire chromosome, three for the long arm, and six had LOH for restricted regions of the long arm. The results supported evidence that there are two predominant regions of LOH, 16q22.1 and 16q24.3. The cell lines with chromosome 16 LOH can be used for screening candidate tumor suppressor genes at 16q in breast cancer.     

Different mechanisms of chromosome 16 loss of heterozygosity in well- versus poorly differentiated ductal breast cancer

Loss of heterozygosity (LOH) at the long arm of chromosome 16 is a frequent genetic alteration in breast cancer. It can occur by physical loss of part of or the entire chromosomal arm, resulting in a decrease in copy number or loss followed by mitotic recombination. Comparative genomic hybridization (CGH) demonstrated that well-differentiated breast tumors showed significantly more physical loss of 16q than did poorly differentiated ones and that this difference was already discernable in the preinvasive stage. However, polymorphic markers detected no difference in the frequency of 16q LOH between invasive tumors of different histological grade. Here, by combining data on LOH (n=52), fluorescence in situ hybridization (n=18) with chromosome 16-specific probes, and CGH (n=34), we show a preference in well-differentiated grade I tumors for physical loss of chromosome arm 16q, whereas in poorly differentiated grade III tumors LOH is accompanied by mitotic recombination. This clarifies the discrepancies observed between CGH and LOH for 16q in breast cancer. These different somatic genetic mechanisms may reflect the presence of multiple tumor suppressor genes that are the target of LOH at chromosome arm 16q.     

Homozygous deletion at the 9q32-33 candidate tumor suppressor locus in primary human bladder cancer.

Loss of heterozygosity (LOH) on chromosome arm 9q is the most frequent genetic alteration found in superficial and invasive transitional cell carcinoma (TCC) in a previous microsatellite-based deletion mapping study of the bladder and upper urinary tract, indicating the presence of one or more important tumor suppressor genes (TSGs). One of the putative tumor suppressor loci on 9q (DBC1) was mapped to 9q32-33 and the candidate region was localized within a single YAC. We report here a case of superficial papillary TCC, which showed a homozygous deletion encompassing this candidate tumor suppressor region. The region of homozygous deletion spanned the interval between D9S275 and AFMA239XA9 at 9q32-33, and was estimated to be 相似文献   

BCR expression is decreased in meningiomas showing loss of heterozygosity of 22q within a new minimal deletion region

Neurofibromin 2 (NF2), located on chromosome arm 22q, has been established as a tumor suppressor gene involved in meningioma pathogenesis. In our study, we investigated 149 meningiomas to determine whether there are additional tumor suppressor genes localized on chromosome 22q, apart from NF2, that might be involved in meningioma pathogenesis. The LOH analysis on chromosome 22q identified two regions of deletion: the first one, which is limited to the NF2 gene locus, and the second one, which is outside this location. The new minimal deletion region (MDR) included the following genes: BCR (breakpoint cluster region), RAB36 (a member of RAS oncogene family), GNAZ [guanine nucleotide binding protein (G protein), -z polypeptide], and RTDR1 (rhabdoid tumor deletion region gene 1). The expression levels of all these genes, including NF2, were subsequently analyzed by quantitative real-time polymerase chain reaction. We observed a significantly lowered expression level of NF2 in meningiomas with 22q loss of heterozygosity (LOH) within NF2 region compared to the one in meningiomas with 22q retention of heterozygosity (ROH, P<0.05). Similarly, BCR showed a significantly lowered expression in meningiomas with 22q LOH within the new MDR compared to cases with 22q ROH (P<0.05). Our data, together with the already published information considering BCR function suggest that BCR can be considered as a candidate tumor suppressor gene localized on chromosome 22q which may be involved in meningioma pathogenesis.     

Chromosome 8p alterations in sporadic and BRCA2 999del5 linked breast cancer

Chromosomal losses involving the short arm of chromosome 8 are frequent in a variety of tumour types, including breast cancer, suggesting the presence of one or more tumour suppressor genes in this region. In this study, we have used 11 microsatellite markers to analyse loss of heterozygosity (LOH) at chromosome 8p in 151 sporadic breast tumours and 50 tumours from subjects carrying the BRCA2 999del5 mutation. Fifty percent of sporadic tumours compared to 78% of BRCA2 linked tumours exhibit LOH at one or more markers at 8p showing that chromosome 8p alterations in breast tumours from BRCA2 999del5 carriers are more pronounced than in sporadic breast tumours. The pattern of LOH is different in the two groups and a higher proportion of BRCA2 tumours have LOH in a large region of chromosome 8p. In the total patient material, LOH of 8p is associated with LOH at other chromosome regions, for example, 1p, 3p, 6q, 7q, 9p, 11p, 13q, 17p, and 20q, but no association is found between LOH at 8p and chromosome regions 11q, 16q, 17q, and 18q. Furthermore, an association is detected between LOH at 8p and positive node status, large tumour size, aneuploidy, and high S phase fraction. Breast cancer patients with LOH at chromosome 8p have a worse prognosis than patients without this defect. Multivariate analysis suggests that LOH at 8p is an independent prognostic factor. We conclude that chromosome 8p carries a tumour suppressor gene or genes, the loss of which results in growth advantage of breast tumour cells, especially in carriers of the BRCA2 999del5 mutation.


Keywords: chromosome 8; BRCA2; LOH; breast cancer     

Chromosome 8 genetic analysis and phenotypic characterization of 21 ovarian cancer cell lines

The short arm of chromosome 8 undergoes frequent loss of heterozygosity (LOH) in ovarian adenocarcinomas. Fine mapping has identified several distinct critical regions within 8p which undergo rates of LOH of 50% or greater, suggesting that there may be more than one tumor suppressor gene located on this chromosome arm. In an effort to refine the location of these putative tumor suppressor genes by homozygosity-mapping-of-deletion analysis, we have analyzed 21 ovarian cancer cell lines with 19 polymorphic microsatellite markers from 8p. Eleven of the cell lines (55%) were homozygous at every marker, indicating loss of an entire 8p arm. No smaller extended regions of hemizygosity were identified. Refinement of these 8p target regions was therefore not possible, but this analysis did identify the ovarian cancer cell lines that would be most appropriate for microcell-mediated chromosome transfer to complement the hypothesized mutation in the target tumor suppressor gene(s) on 8p. The 11 cell lines that had undergone 8p LOH were therefore characterized for colony formation in soft agar and tumor formation in nude mice. We identified four cell lines (JAM, OVCA4, OVCA5, and OVCA8) that were hemizygous for 8p and that formed colonies in soft agar and tumors in nude mice, making them ideal cell lines for chromosome 8 or candidate gene transfer.     

Molecular genetic analysis of chromosome 9 candidate tumor-suppressor loci in bladder cancer cell lines

Underrepresentation of chromosome 9 is a common finding in bladder cancer. Frequent loss of the whole chromosome suggests the presence of at least one relevant tumor suppressor gene on each arm. Candidate regions identified by loss of heterozygosity (LOH) analysis include a region at 9p21 containing CDKN2A, which encodes p16 and p14(ARF), a large region at 9q12-31 including PTCH and many other genes, a small region at 9q32-33, which includes the DBCCR1 gene, and a region at 9q34 including the TSC1 gene. Experimental replacement of genes or chromosomes into tumor cells with appropriate deletions or mutations represents an important approach to test the functional significance of candidate tumor suppressor genes. Loss of an entire copy of chromosome 9 in many bladder tumor cell lines provides no indication of which gene or genes are affected, and selection of appropriate recipient cells for gene replacement is difficult. We have investigated three candidate tumor suppressor genes on chromosome 9 (CDKN2A, DBCCR1, and TSC1), at the DNA level and by expression analysis in a panel of bladder tumor cell lines, many of which have probable LOH along the length of the chromosome, as indicated by homozygosity for multiple polymorphic markers. Cytogenetically, we found no reduction in the numbers of chromosomes 9 relative to total chromosome count. Homozygous deletion of the CDKN2A locus was frequent but homozygous deletion of TSC1 was not found. A new cell line, DSH1, derived from a pT1G2 transitional cell carcinoma with known homozygous deletion of DBCCR1, is described. This study identifies suitable cell lines for future functional analysis of both CDKN2A and DBCCR1.     

Increased chromosome 20 copy number detected by fluorescence in situ hybridization (FISH) in malignant melanoma

DNA amplification is an important mechanism of tumor progression that allows cancer cells to up-regulate the expression of critical genes such as oncogenes and genes conferring drug resistance. Recent studies using comparative genomic hybridization (CGH) revealed increased DNA copies of 20q sequences in 7 melanoma cell lines and 8 archival metastatic melanoma lesions. To evaluate chromosome 20 abnormalities in more detail and to resolve discrepancies between karyotype and CGH findings, we performed FISH analysis of metaphase cells in 13 melanoma cell lines (including the 7 lines used for CGH) and 9 primary melanoma specimens by using a whole chromosome paint specific for chromosome 20. All 13 cell lines (100%) and 8/9 primary tumors (89%) showed extra copies of chromosome 20 relative to tumor ploidy. Additionally, 6/14 cell lines (43%) and 2/8 primary tumors (25%) showed translocated chromosome 20 material previously undetected by standard cytogenetics. Cytologic evidence for gene amplification was also found in one cell line, which contained an add(20)(p13), with additional DNA being derived from 20q sequences. These data suggest that overrepresentation of a gene or genes important for melanoma pathogenesis resides on the long arm of chromosome 20. Genes Chromosom. Cancer 19:278–285, 1997. © 1997 Wiley-Liss, Inc.     

Multipoint interphase FISH in childhood T-acute lymphoblastic leukemia detects subpopulations that carry different chromosome 3 aberrations

We examined chromosome 3 in 32 childhood acute lymphoblastic leukemia (ALL) bone marrow samples. Using interphase multipoint FISH (mp-FISH), which was developed by our group, with 42 chromosome 3-specific probes, we detected clonal chromosome 3 aberrations in 4 T-cell ALL (T-ALL) cases. Four out of seven T-ALL cases carried 3q trisomies. One T-ALL case carried either trisomy 3 (in 15% of the cells) or a 23-megabase (Mb) 3p13 approximately p12 deletion in a different subpopulation of cells of 32%. Another T-ALL case had either 3q trisomy in 11% or a 12-Mb 3p12 approximately p13 deletion in 19% of the cells. The deletions were overlapping. In both cases, the majority of the bone marrow cells (47 and 70%, respectively) were normal chromosome 3 disomics. The interstitial deletions detected harbor a known homozygous deletion region between 72.6 and 78.8 Mb, which has been described in lung and breast tumors and contains the DUTT1/ROBO1 tumor suppressor gene. These deletions detected by mp-FISH would have remained unnoticed by conventional cytogenetics and multiplex FISH, as well as by current methods based on total tumor DNA analysis such as comparative genomic hybridization (CGH), array CGH, and loss of heterozygosity (LOH).     

High-resolution analysis of allelic imbalance in neuroblastoma cell lines by single nucleotide polymorphism arrays

Genomic copy number changes are detectable in many malignancies, including neuroblastoma, using techniques such as comparative genomic hybridization (CGH), microsatellite analysis, conventional karyotyping, and fluorescence in situ hybridization (FISH). We report the use of 10K single nucleotide polymorphism (SNP) microarrays to detect copy number changes and allelic imbalance in six neuroblastoma cell lines (IMR32, SHEP, NBL-S, SJNB-1, LS, and SKNBE2c). SNP data were generated using the GeneChip DNA Analysis and GeneChip chromosome copy number software (Affymetrix). SNP arrays confirmed the presence of all previously reported cytogenetic abnormalities in the cell lines, including chromosome 1p deletion, MYCN amplification, gain of 17q and 11q, and 14q deletions. In addition, the SNP arrays revealed several chromosome gains and losses not detected by CGH or karyotyping; these included gain of 8q21.1 approximately 24.3 and gain of chromosome 12 in IMR-32 cells; loss at 4p15.3 approximately 16.1 and loss at 16p12.3 approximately 13.2, 11q loss with loss of heterozygosity (LOH) at 11q14.3 approximately 23.3 in SJNB-1 cells; and loss at 8p21.2 approximately 23.3 and 9p21.3 approximately 22.1 with corresponding LOH in SHEP cells. The SNP arrays refined the mapping of the 2p amplicons in LS, BE2c, and IMR-32 cell lines, the 12q amplicon in LS cells, and also identified an 11q13 amplicon in LS cells. There was good concordance among SNP arrays, CGH, and karyotyping. SNP array analysis is a powerful tool for the detection of allelic imbalance in neuroblastoma and also allows identification of LOH without changes in copy number (uniparental disomy).     

Are there any more ovarian tumor suppressor genes? A new perspective using ultra high‐resolution copy number and loss of heterozygosity analysis

Ovarian cancer is characterized by complex genetic alterations, including copy number loss and copy number‐neutral loss of heterozygosity (LOH). These alterations are assumed to represent the “second hit” of the underlying tumor suppressor gene (TSG), however, relative to the number of LOH hotspots reported, few ovarian TSGs have been identified. We conducted a high‐resolution LOH analysis using SNP arrays (500K and SNP6.0) of 106 primary ovarian tumors of various histological subtypes together with matching normal DNA. LOH was detected in at least 35% of samples on chromosomes 17, 19p, 22q, Xp, 13q, 8p, 6q, 4q, 5q, 1p, 16q, and 9q with a median minimal region of overlap of only 300 kb. Subtype‐specific differences in LOH frequency were noted, particularly for mucinous cases. We also identified 192 somatic homozygous deletions (HDs). Recurrent HDs targeted known TSGs such as CDKN2A (eight samples), RB1 (five samples), and PTEN (three samples). Additional recurrent HDs targeted 16 candidate TSGs near minimal regions of LOH on chromosomes 17, 13, 8p, 5q, and X. Given the importance of HDs in inactivating known genes, these candidates are highly likely to be ovarian TSGs. Our data suggest that the poor success of previous LOH studies was due to the inability of previous technology to resolve complex genomic alterations and distinguish true LOH from allelic imbalance. This study shows that recurrent regions of LOH and HD frequently align with known TSGs suggesting that LOH analysis remains a valid approach to discovering new candidates. © 2009 Wiley‐Liss, Inc.     

At least two different regions are involved in allelic imbalance on chromosome arm 16q in breast cancer

Loss of heterozygosity (LOH) or allelic imbalance, the latter term referring to both loss and gain of an allele, on the long arm of chromosome 16 has been repeatedly found in cancers of, e.g., the breast and prostate. This indicates the presence of one or more tumor suppressor genes on 16q. To locate the gene(s) more precisely, a detailed allelic imbalance map of 20 polymorphic markers on this chromosome arm was made for 79 sporadic breast carcinomas. LOH of one or more markers was found in 63% of the tumors. Some had allelic imbalance on a region of 16q which failed to overlap with the LOH in other tumors. We therefore assigned two separate “smallest regions of overlap” to 16q and suggest that this chromosome arm contains at least two different tumor suppressor genes. Genes Chrom Cancer 9:101-107 (1994).© 1994 Wiley-Liss, Inc.     

Frequent genetic alterations in flat urothelial hyperplasias and concomitant papillary bladder cancer as detected by CGH,LOH, and FISH analyses

Flat urothelial hyperplasia, defined as markedly thickened urothelium without cytological atypia, is regarded in the new WHO classification as a urothelial lesion without malignant potential. Frequent deletions of chromosome 9 detected by fluorescence in situ hybridization (FISH) have been previously reported in flat urothelial hyperplasias found in patients with papillary bladder cancer. Using comparative genomic hybridization (CGH) and microsatellite analysis, these hyperplasias and concomitant papillary tumours of the same patients were screened for other genetic alterations to validate and extend the previous findings. Eleven flat hyperplasias detected by 5-ALA-induced fluorescence endoscopy and ten papillary urothelial carcinomas (pTaG1-G2) from ten patients were investigated. After microdissection, the DNA of the lesions was pre-amplified using whole genome amplification (I-PEP-PCR). Loss of heterozygosity (LOH) analyses were performed with five microsatellite markers at chromosomes 9p, 9q, and 17p. CGH was performed using standard protocols. In 6 of 11 hyperplasias and 7 of 10 papillary tumours, deletions at chromosome 9 were simultaneously shown by FISH, LOH, and CGH analyses. There was a good correlation between FISH, LOH, and CGH analyses, with identical results in 6 of 10 patients. In addition to deletions at chromosome 9, further genetic alterations were detected by CGH in 9 of 10 investigated hyperplasias, including changes frequently found in invasive papillary bladder cancer (loss of chromosomes 2q, 4, 8p, and 11p; gain of chromosome 17; and amplification at 11q12q13). There was considerable genetic heterogeneity between hyperplasias and papillary tumours, but a clonal relationship was suggested by LOH and/or CGH analyses in 5 of 10 cases. These data support the hypothesis that flat urothelial hyperplasias can display many genetic alterations commonly found in bladder cancer and could therefore be an early neoplastic lesion in the multistep development of invasive urothelial carcinoma.     

Molecular genetic alterations in carcinoma ex-pleomorphic adenoma: a putative progression model?

To determine the genetic changes associated with the development of carcinoma ex-pleomorphic adenoma (Ca Ex-PA), we analyzed 15 microsatellite loci at chromosome arms 8q, 12q, and 17p on DNA from 26 neoplasms (including 8 microdissected benign and malignant components), and 13 pleomorphic adenomas for comparison. Pleomorphic adenomas and the adenoma component of Ca Ex-PAs showed a higher incidence of loss of heterozygosity (LOH) at chromosome arms 8q (52%) and 12q (28%) than at 17p (14%) loci. In the carcinoma component, the combined LOH at chromosome arm 8q, 12q, and 17p regions was 69%, 50%, and 69%, respectively; within these chromosomal regions, 8q11.23-q12 (42%), 12q23-qter (39%), 17p13 (41%), and 17p11 (45%) loci manifested the highest incidence of LOH. Eight carcinomas (30.7%) showed loss at all three chromosomal arms tested. Of the eight microdissected Ca Ex-PAs analyzed, four adenoma and corresponding carcinoma components (50%) had the same LOH at 12q loci and additional LOH at 17p loci only in carcinomas. Chromosome arm 17p alterations correlated significantly with high disease stage and an increased proliferative rate in these tumors. Our results indicate that alterations at regions on chromosome arms 8q and/or 12q may constitute early events associated with pleomorphic adenomas; that LOH at 12q loci may identify a subset of adenoma with potential progression to carcinoma; that acquisition of additional alterations at chromosome arm 17p loci might represent an event preceding malignant transformation and progression; and that 8q, 12q, and 17p regions may harbor tumor suppressor genes involved in the genesis of PA and Ca Ex-PA. Genes Chromosomes Cancer 27:162-168, 2000.     

Hemizygous deletions of chromosome band 16q24 in Wilms tumor: detection by fluorescence in situ hybridization

Loss of heterozygosity (LOH) for markers on chromosome arm 16q in Wilms tumor has been linked to an increased risk of treatment failure. We therefore postulated that fluorescence in situ hybridization (FISH) with probes from this region might enhance current strategies for identifying high-risk patients at diagnosis. In a blinded comparative pilot study of 19 Wilms tumor samples from 18 patients with favorable histology, FISH and DNA polymorphism analysis yielded concordant results in 14 cases, either retention (n = 6) or loss (n = 8) of chromosome arm 16q markers. Discordant findings in 4 of the 5 remaining cases resulted from detection of LOH, but no loss by FISH. Two of these cases, directly comparable at marker D16S422, appeared to have tumor-specific uniparental disomy, in that 2 copies of D16S422 and the 16 centromere were evident, despite LOH. In 2 other cases, the discrepancies could be explained by LOH confined to loci distal to the D16S422 locus. In the fifth case, FISH detected 2 distinct populations of tumor cells, one characterized by normal diploidy and the other by monosomy 16, whereas DNA polymorphism analysis failed to indicate LOH altogether. Thus, FISH confirmed the presence of allelic loss (hence, the possible location of biologically important tumor suppressor genes) on the distal long arm of chromosome 16 in cases of favorable-histology Wilms tumor, with the advantages of technical simplicity, successful analysis of samples that were otherwise uninformative by analysis of DNA polymorphisms, and the addition of internal controls for chromosomal aneusomy. We suggest that combined analysis of the chromosome 16q region in Wilms tumor by FISH and DNA polymorphism analysis would improve evaluations to identify high-risk patients who might benefit from alternative therapy.     

Chromosome arm 20q gains and other genomic alterations in colorectal cancer metastatic to liver, as analyzed by comparative genomic hybridization and fluorescence in situ hybridization.

Comprehensive information about the molecular cytogenetic changes in metastases of colorectal cancer is not yet available. To define such changes in metastases, we measured relative DNA sequence copy numbers by comparative genomic hybridization (CGH). Samples from 27 liver metastases and 6 synchronous primary tumors were analyzed. An average of 9.9 aberrations per tumor was found in the metastases. Gains of chromosome arms 20q (85%), 13q (48%), 7p (44%), and 8q (44%) and losses of chromosome arms 18q (89%), 8p (59%), 1p (56%), and 18p (48%) were detected most frequently. Chromosomes 14 and 15 were lost in 26% and 30% of the metastases, respectively. No consistent differences were observed between primary tumors and synchronous metastases. Fluorescence in situ hybridization (FISH) was used for further characterization of gains of chromosome arm 20q. Touch preparations of 13 tumors that had demonstrated 20q gain with CGH were examined with FISH by use of a set of probes mapping to different parts of 20q. A probe for 20p was used as a reference. FISH showed relative gain of at least one 20q locus in 12 of the tumors. High-level gains were detected in 38% of the tumors, preferentially for probes mapping to band 20q13. Our CGH data indicate that colorectal metastases show chromosomal changes similar to those that have been reported for primary tumors. Chromosomal losses were seen at higher frequency, particularly for chromosomes 14 and 15. By FISH, we identified subregions on chromosome arm 20q that are frequently involved in DNA amplifications in colorectal cancer and that may harbor candidate proto-oncogenes.     

Region-specific loss of heterozygosity on chromosome 19 is related to the morphologic type of human glioma

Allelic mutation on chromosome 19 has previously been reported as a frequent genetic event in human glial tumors. In an effort to localize specific regions of importance on this chromosome better, 13 highly polymorphic genetic markers distributed along the length of chromosome 19 were used for evaluation of loss of heterozygosity (LOH) and microsatellite instability in a total of 100 brain tumors, including 75 astrocytomas (55 grade 4; 7 grade 3; 5 grade 2; 6 grade 1; and 2 other), 17 oligodendrogliomas (1 grade 4; 5 grade 3; 10 grade 2; and 1 grade 1), and 8 mixed oligoastrocytomas (MOA) (3 grade 4; 2 grade 3; and 3 grade 2). No microsatellite expansion was observed in these glial tumors for any of the chromosome 19 loci examined. LOH for loci on chromosome 19 was detected in 23/74 informative astrocytomas (31%), 11/17 oligodendrogliomas (65%), and 3/8 MOA (38%). Partial deletion of chromosome 19 occurred more frequently (31/37 cases) than did loss of one whole copy of the chromosome, and a morphology-specific pattern of LOH was observed. In 12/14 (86%) instances of chromosome 19 deletion in oligodendrogliomas and MOA, the 19q arm showed LOH, whereas the 19p arm showed no loss for all informative loci. Conversely, in 17/23 (74%) instances of chromosome 19 deletion in astrocytomas, the 19p arm showed LOH, whereas the 19q arm showed no loss for one or more loci. Thus, loss of 19q and retention of 19p are strongly associated with oligodendroglioma and MOA, whereas loss of 19p and retention of distal 19q is associated with astrocytoma. These data indicate that two or more tumor suppressor genes may reside on chromosome 19, one on 19p important in the development of astrocytomas, and one on 19q important in oligodendrogliomas and MOA.     

Allelic imbalance study of 16q in human primary breast carcinomas using microsatellite markers

The high incidence of allelic imbalance on the long arm of chromosome 16 in breast cancer suggests its involvement in the development and progression of the tumor. Several loss of heterozygosity (LOH) studies have led to the assignment of commonly deleted regions on 16q where tumor suppressor genes may be located. The most recurrent LOH regions have been 16q22.1 and 16q22.4-qter. The aim of this study was to gain further insight into the occurrence of one or multiple “smallest regions of overlap” on 16q in a new series of breast carcinomas. Hence, a detailed allelic imbalance map was constructed for 46 sporadic breast carcinomas, using 11 polymorphic microsatellite markers located on chromosome 16. Allelic imbalance of one or more markers on 16q was shown by 30 of the 46 tumors (65%). Among these 30 carcinomas, LOH on the long arm of chromosome 16 was detected at all informative loci in 19 (41%); 13 of them showed allelic imbalance on the long but not on the short arm, with the occurrence of variable “breakpoints” in the pericentromeric region. The partial allelic imbalance in 11 tumors involved either the 16q22.1-qter LOH region or interstitial LOH regions. A commonly deleted region was found between D16S421 and D16S289 on 16q22.1 in 29 of the 30 tumors. The present data argue in favor of an important involvement of a tumor suppressor gene mapping to 16q22.1 in the genesis or progression of breast cancer.