Definition of a region of loss of heterozygosity at chromosome 11q23.3-25 in head and neck squamous cell carcinoma using laser capture microdissection technique.

To date, loss of heterozygosity (LOH) studies on HNSCC have had limited success in identifying a confined region of loss on chromosome 11q partially due to the heterogeneous nature of tumor tissue examined. Additionally, little is known about the role of the 11q allelic deletion in HNSCC tumorigenesis and current reports are conflicting. The aim of this study was to better define LOH at distal 11q by using combination of a pure cell population procured by laser capture microdissection (LCM) and subsequent sensitive PCR amplification of polymorphic microsatellites. This study analyzed HNSCC for LOH using a panel of 5 microsatellite markers spanning 11q23-25. Thirty-four paired DNA samples from tumor and autologous normal tissue were harvested by LCM technique to ensure a pure cell population for PCR amplification. Approximately 2000 to 3000 cells were procured from each sample. Twenty-one of 34 cases (62%, P < 0.001) showed LOH on at least one of the loci examined. The highest frequency of LOH was found at the 11q23.3-25 segment, with 44% at marker D11S968 and 35% at marker D11S1316. A distinct novel region of frequent LOH at 11q23.3-25, defined by D11S1316 and D11S968, was identified. No allelic loss was found in any normal squamous tissue samples. To study LOH in HNSCC, combination of pure cell population procurement by LCM and sensitive PCR provides a more accurate approach than the conventional method using a bulk of heterogeneous tissue. A novel region of LOH at 11q23.3-25 was defined. LOH in this region may harbor putative tumor suppressor gene(s) critical for HNSCC. Furthermore, these allelic losses were not found in any non-neoplastic squamous tissue samples, clarifying prior discrepant data.     

Loss of heterozygosity on chromosome 11 q in breast cancer.

AIMS--Chromosome 11q23 seems to be a site of frequent mutation in cancer. It also contains loci such as ataxia telangiectasia with possible importance in the pathogenesis of breast tumours. The short arm of chromosome 11 has been studied extensively in breast cancer, but the long arm, in particular the distal part, has been studied less frequently. Cytogenetic analysis has shown possible involvement of chromosome 11q in breast tumours. Chromosome transfer experiments have also implicated chromosome 11q in breast cancer. A high frequency of mutations might therefore be expected to occur on chromosome 11q in breast cancers. METHODS--Using restriction fragment analysis, the primary tumours of 41 patients with breast cancer were screened for mutations at five loci on chromosome 11q (D11Z1, INT2, (FGF3), DRD2, NCAM, and D11S29). RESULTS--Allelic loss occurred at a high frequency (59%) at D11S29. At NCAM, novel alleles were frequently seen on autoradiographs. Relatively low frequencies of mutation were detected at the other loci. Allelic loss at D11S29 was associated with the presence of lymph node metastases, but this may be a chance association. CONCLUSIONS--The frequency of allelic loss at the DS11S29 locus is high. The significance of novel alleles at NCAM and their relation to allelic loss at D11S29 are unclear. The results presented here do not permit fine mapping of a region of allelic loss, but suggest that the region of greatest loss lies distal to DRD2. The results provide further evidence for the importance of gene(s) near 11q23 in the pathogenesis of breast cancer, and of tumours in general.     

Correlation of loss of heterozygosity at chromosome 9q with histological subtype in medulloblastomas.

Patients with the nevoid basal cell carcinoma syndrome (NBCCS) are at increased risk for medulloblastomas as well as for basal cell carcinomas. The gene for NBCCS has been mapped to chromosome 9q22.3-q31 by linkage analysis, and loss of heterozygosity (LOH) in this region has been demonstrated in approximately one-half of sporadic basal cell carcinomas. In the present study, LOH for chromosome 9q22.3-q31 microsatellite markers was investigated in medulloblastomas occurring among children with NBCCS and in sporadic medulloblastomas. Histologically, all 3 NBCCS medulloblastomas were noted to have a desmoplastic phenotype, and LOH was detected in both of the 2 cases for which microsatellite markers were heterozygous in normal tissues. LOH was also detected in a subset of sporadic medulloblastomas, each of which were found to display the desmoplastic phenotype. In all, 3 of the 6 sporadic desmoplastic tumors showed LOH, whereas LOH was not seen in any of the 11 sporadic, non-desmoplastic medulloblastomas studied. Additionally, desmoplastic tumors lacking detectable LOH each showed histological features of so-called cerebellar neuroblastoma, a subgroup of desmoplastic medulloblastoma with extensive neuroblastomatous differentiation. The data are consistent with a role for inactivation of a tumor suppressor gene at chromosome 9q in the development of medulloblastomas in patients with NBCCS and of sporadic medulloblastomas characterized by a desmoplastic phenotype similar to that found in patients with NBCCS. Restriction of chromosome 9q loss to non-neuroblastomatous desmoplastic tumors suggests that this variant of medulloblastoma maybe pathogenetically distinct from tumors having other histological phenotypes.     

Analysis of loss of heterozygosity on chromosome 11q13 in atypical ductal hyperplasia and in situ carcinoma of the breast.

Identical allelic loss in invasive and adjacent in situ ductal breast carcinoma (DCIS) on chromosome 11q13 has been previously reported, providing molecular evidence for the progression of DCIS to invasive tumor. In this study we analyzed loss of heterozygosity (LOH) on 11q13 (PYGM, INT-2) in atypical ductal hyperplasia (ADH) and various histological types of in situ carcinomas of the breast in patients without invasive cancer. Twenty-four cases of in situ carcinoma and twelve cases of ADH were studied. Tissue microdissection of normal, hyperplastic, and tumor cells from fixed, paraffin-embedded sections was performed, and DNA was extracted for polymerase chain reaction. In situ tumors included both high- and low-grade DCIS. LOH was identified in six of twenty-two (27.3%) in situ tumors and in one of eleven (9%) ADH cases. Within in situ carcinomas, LOH was identified in six of seventeen (35%) high-grade DCIS but in none of six low-grade DCIS. The present results show that LOH at 11q13 occurs in an appreciable proportion of high-grade DCIS, although the rate is substantially less than in patients with concomitant DCIS and invasive tumor. LOH was identified less frequently in low-grade in situ tumors and ADH, suggesting that a putative tumor suppressor gene(s) located on chromosome 11q13 may be involved in the transition from early preneoplastic lesions to invasive breast cancer.     

Refined mapping of two regions of loss of heterozygosity on chromosome band 11q23 in lung cancer.

11q23-24 chromosome is a region containing frequent allelic loss (loss of heterozygosity; LOH) in human cancers. To examine cancer-related allelic loss in the region between D11S940 and APOC3, we used 17 polymorphic markers and allotyped 28 lung cancer-derived cell lines and their corresponding matched lymphoblastoid cell lines. LOH was found in 71.4% (20/28) of the lung cancer cell lines and was localized to two distinct minimal regions of loss. One region is bracketed by markers D11S1647 and NCAM2 and contains the gene encoding the beta isoform of the A subunit of the human protein phosphatase 2A (PPP2R1B). Recently, mutations in this gene were described in lung and colon cancers, suggesting that PPP2R1B functions as a tumor-suppressor gene. A second minimal region of loss was defined between markers D11S1792 and D11S1885, a region estimated to be less than I Mb. Thus, chromosome 11 likely harbors two sites of suppressor oncogene activity in lung cancer, one defined by the PPP2R1B gene and the second located telomeric to PPP2R1B. This study facilitates the identification and cloning of a second critical tumor-suppressor gene involved in lung cancer, and possibly a variety of other cancers, on human chromosome band 11q23.     

Loss of heterozygosity on chromosome arm 11q in lung carcinoids

Neuroendocrine lung tumors such as typical carcinoid, atypical carcinoid, small-cell lung carcinoma, and large-cell neuroendocrine carcinoma represent a variable group with different biologic characteristics and unclear genetical relationships. We investigated the pattern of allelic loss on chromosome arm 11q in 20 sporadic carcinoid tumors of the lung using 10 microsatellite markers. Loss of heterozygosity was found in 13 of 20 tumors. In 5 of 9 typical carcinoids, 3 distinct regions of allelic loss were identified: 11q13.1 (D11S1883), 11q14.3-11q21 (D11S906), and 11q25 (D11S910). Atypical carcinoids showed loss of heterozygosity at 4 different regions: the first, most proximal region at 11q13 between markers PYGM and D11S937; the second at 11q14.3-11q21 (D11S906); and the third and fourth defined by markers D11S939 (11q23.2-23.3) and D11S910 (11q25). However, the region 11q13 harboring the MEN1 gene was more frequently affected in atypical carcinoids (7 of 11) than in typical carcinoids (2 of 9). The high rate of allelic losses within chromosomal region 11q13 in atypical carcinoids emphasizes the importance of this region for tumor development. We also recognized that more aggressive atypical carcinoids defined by high mitotic counts, vascular invasion, and/or organ metastasis are combined with increased allelic losses. HUM PATHOL 32:333-338.     

Detection of loss of heterozygosity on chromosome 9q22.3 in microdissected sporadic basal cell carcinoma

Identification of loss of heterozygosity (LOH) at specific genetic loci in cancer cells suggests the presence of a tumor suppressor gene within the deleted region. A basal cell carcinoma (BCC) susceptibility gene, human homolog of drosophila patched (PTC), has been recently cloned and localized on chromosome 9q22.3. Mutation and deletion of this region has been reported in BCCs using frozen tumor tissue. The objective of this study was to test whether LOH of human PTC on chromosome 9q22 could be detected in archival sporadic BCCs. We studied 20 randomly selected sporadic BCCs by microdissection and polymerase chain reaction using paraffin-embedded, formalin-fixed material on glass slides. In all cases, analysis was performed with the polymorphic markers D9S53, D9S15, D9S287, and D9S303. The LOH frequencies were 30%, 42%, 56%, and 75% with D9S15, D9S287, D9S53, and D9S303, respectively. LOH at 9q22 was identified in 12 of 20 cases (60%) with at least one marker. Seven cases showed LOH with two markers, two cases with three markers, and one case showed LOH with all four markers. The results indicate that BCC LOH can be frequently identified in paraffin-embedded BCC after routine processing.     

Frequent loss of heterozygosity at 6q in pheochromocytoma

Multiple genetic alterations have been associated with pheochromocytoma (PCC). Most PCCs are sporadic, but they also occur in inherited tumor syndromes, including von Hippel-Lindau disease. Although the etiology of most inherited PCCs is well documented, little is known about the etiology of sporadic tumors. Mutations of those genes that harbor germ-line mutations in familial cases cover only 10% to 15% of somatic mutations in sporadic PCCs. A previous cytogenetic analysis indicated frequent loss of 6q in sporadic PCCs. We therefore investigated in detail 18 PCCs using 22 microsatellite markers spanning 6q to search for the presence of allele deletions and identify specific regions likely to contain tumor suppressor genes involved in PCC. Moreover, we sought to compare PCC with capillary hemangioblastoma, another von Hippel-Lindau disease-associated tumor that we previously found to harbor frequent loss of heterozygosity (LOH) at 6q. Our study revealed a high frequency (13/18; 72%) of overall 6q LOH in PCCs. Loss of heterozygosity at 6q was observed in 6 benign (6/9; 67%) and 7 borderline (7/9; 78%) tumors. We identified 2 regions where LOH or allelic imbalance was common (ie, 6q14 [9/18; 50%] and 6q23-24 [6/18; 33%]). We further focused the search using markers specific for the ZAC1 gene region located at 6q24-25. Altogether, for all 6q23-25 markers, including the ZAC1-specific ones, LOH or allelic imbalance was observed in 50% (9/18) of the PCCs. Similar to our findings for capillary hemangioblastomas, our data for the first time suggest that one or several tumor suppressor genes located at 6q, particularly at 6q23-24, may play a role in the tumorigenesis of PCCs.     

Allelic loss of chromosome 6q in gastric carcinoma.

Loss of the long arm of chromosome 6 (6q) has frequently been reported in gastric carcinoma, and most gastric cancer patients have evidence of intestinal metaplasia in the stomach. However, the relationship between loss of chromosome 6q and intestinal metaplasia has not been studied. In the first part of the study, we define the critical deletion region of chromosome 6q using loss of heterozygosity technique (LOH). Seventeen microsatellite markers were used to detect loss of heterozygosity (LOH) in 37 microdissected gastric tumors. We also examined intestinal metaplasia (IM) foci of the stomach in the same cancer patient (17 cases). Losses on chromosome 6q were detected in high frequency (51%) by LOH. Two distinct regions of common allelic loss were identified: one centered on the marker D6S300 (at 6q16.1) and the second on D6S446 (at 6q27), with LOH frequency of 36% and 31.3%, respectively. The deletions fall into 2 discrete regions, suggesting the existence of at least 2 tumor suppressor genes in 6q. The losses at 6q27 were confirmed by fluorescence in situ hybridization study (FISH). In the cases with LOH in the tumor, no LOH were detected in the autologous IM areas, but losses were detected by FISH. In some cases, these genetic changes may be acquired in the transition from normal gastric mucosa to intestinal metaplasia.     

Frequent loss of heterozygosity on chromosome 12q in non-small-cell lung carcinomas

Chromosomal aberrations in non-small-cell lung carcinomas (NSCLCs) are common events. In our study, the lung cancer cell lines (NCI-H446 and SPC-A-1) displayed numerous numerical and structural alterations in their chromosomes by G-banded karyotypic analysis, and abnormalities of chromosome 12 by fluorescence in situ hybridization. Sequentially, we used 14 microsatellite markers within 12q to analyze loss of heterozygosity (LOH) in lung cancer cell lines and NSCLCs. Possible LOH on 12q were statistically inferred to occur in five lung cell lines. Importantly, 17 out of 25 NSCLCs (68%) showed LOH at chromosome 12q. Frequencies of LOH for individual markers ranged from 18% to 44%. Several deletions which were marked with D12S1301, D12S2196, D12S398, D12S90, D12S1056, D12S1713, D12S375, D12S1040, D12S326, and D12S106 were newly detected. Allelic loss on 12q15–q21 detected with D12S1040 occurred at the later stages of NSCLC progression (p < 0.05, Fisher’s exact test). LOH on 12q marked with D12S2196, D12S398, D12S326, and D12S106 were frequently found in NSCLCs from the patients without smoking history (p < 0.05, Fisher’s exact test). These findings indicated that allelic loss on 12q is commonly involved in NSCLCs, and new tumor suppressor genes may occur within 12q.     

Allelic loss on chromosome bands 13q11-q13 in esophageal squamous cell carcinoma.

Allelic loss on chromosome 13 occurs frequently in esophageal squamous cell carcinoma. However, studies of the two known tumor suppressor genes located on 13q, RB1 and BRCA2, have shown few mutations, suggesting that other genes are likely to be involved in the development of this tumor type. To identify a minimal deletion interval, we first analyzed 42 microsatellite markers spanning chromosome bands 13q11-q13 in 56 esophageal squamous cell carcinoma patients, including 34 with a family history of upper gastrointestinal cancer and 22 without a family history of cancer. Lifestyle risk factors and clinical/pathologic characteristics were also collected. Two commonly deleted regions were identified: one was located on band 13q12.11, between markers D13S787 and D13S221; the other was located on bands 13q12.3-q13.1 from markers D13S267 to D13S219. We observed higher allelic loss frequencies for eight of the microsatellite markers in those patients with a family history of upper gastrointestinal cancer compared to patients without such a history. This study suggests that one or more unidentified tumor suppressor genes are located on chromosome arm 13q that play a role in the development of esophageal squamous cell carcinoma.     

人宫颈癌组织染色体部分位点杂合性丢失

了解人宫颈癌组织中3，6，11和18号染色体部分位点杂合性丢失的分布状况，为宫颈部相关基因的定位以及临床诊断分子标志的筛选提供依据。采用宫颈癌基因组中3，6，11和18号染色体上的8个微卫星标志，对源自宫颈癌等高发区的宫颈癌活检标本，以PCR－变性电泳－银染的方法检测上述位点的杂合性丢失。其中在染色体3p14,18q21等位点存在较高频率的杂合性丢失。结果表明杂合性丢失是宫颈癌癌变过程中常见的遗传性改变，宫颈癌中存在杂合性丢失的高频区，提示相应位点存在潜在的抑癌基因。     

Frequent loss of heterozygosity on chromosome 5 in non-small cell lung carcinoma.

AIMS: Loss of heterozygosity (LOH) at specific chromosomal regions strongly suggests the existence of tumour suppressor genes at the relevant segment. Frequent LOH on chromosome 5q has been reported in a wide variety of human tumours, including those of the lung. The aim of this study was to screen for LOH and to clarify the location of putative tumour suppressor genes on chromosome 5 implicated in the genesis and/or development of non-small cell lung carcinoma. METHODS: Thirty three patients with advanced non-small cell lung carcinoma were screened for LOH with a panel of 21 microsatellite DNA markers spanning the entire chromosome 5, using semi-automated fluorochrome based methodology. RESULTS: Twenty of the non-small cell lung carcinoma samples displayed LOH for one or more informative locus. LOH involving only 5q was found in 10 of 14 of the informative samples. Deletions involving 5p only were not present in the samples under study. There was no evidence of microsatellite instability in any of the analysed loci. These results indicate the presence of five distinct segments displaying high frequencies of deletion on chromosome 5, namely: 5q11.2-q12.2, 5q15 (D5S644 locus), 5q22.3-q23.1, 5q31.1, and 5q35.3. Eight of 14 samples had simultaneous interstitial deletions in at least two different regions. Moreover, concomitant deletion of three and four distinct regions was displayed in three of 14 and two of 14, respectively, of the informative samples. CONCLUSION: Allelic deletion on chromosome 5 is a frequent event in patients with non-small cell lung carcinoma. These results suggest the involvement of these five regions, either independently or simultaneously, in both lung squamous cell carcinoma and lung adenocarcinoma.     

The absence of CCL2 expression in cervical carcinoma is associated with increased survival and loss of heterozygosity at 17q11.2

To determine whether CCL2 mRNA expression is beneficial or detrimental for cervical cancer patients, the association between the expression of this molecule by cervical tumour cells, the number of tumour-associated macrophages, and clinicopathological parameters such as recurrence, relapse-free survival, and overall patient survival was investigated. In cervical cancer samples from 93 untreated cervical cancer patients, the CCL2 mRNA expression level was quantified using RNA in situ hybridization and verified using real-time quantitative RT-PCR. The number of tumour-associated macrophages was determined using immunohistochemistry. Furthermore, the study investigated whether lack of CCL2 expression was due to genetic alterations near the 17q11.2 (CCL2 genomic) region. CCL2 mRNA expression by cervical tumour cells was associated with the number of tumour-associated macrophages (p < 0.001). Lack of CCL2 mRNA expression (15 samples; 16%) was associated with increased cumulative relapse-free survival (log rank test, p = 0.030), increased cumulative overall survival (log rank test, p = 0.024), less post-operative surgery, reduced local and distant recurrence, reduced vascular invasion, and smaller tumour size (<40 mm). The absence of CCL2 mRNA expression corresponded with loss of heterozygosity (LOH) at 17q11.2 in five of six samples. The increased cumulative relapse-free survival and cumulative overall survival of cervical cancer patients lacking tumour cell-associated CCL2 mRNA suggest that the tumour-associated macrophages support tumour progression, presumably by promoting angiogenesis and production of growth factors.     

Loss of heterozygosity at chromosome regions 22q11–12 and 11p15.5 in renal rhabdoid tumors

Rhabdoid tumors of the kidney are highly malignant neoplasms that occur primarily within the first 3 years of life. Although they are regarded as distinct from Wilms' tumors, their pathogenesis remains unclear. Whereas most cytogenetic studies of these tumors have revealed normal karyotypes, a few reports have indicated abnormalities at chromosome regions 22q and 11p15.5. We analyzed 30 primary renal rhabdoid tumors for loss of heterozygosity (LOH) at both regions and found that 24 of 30 tumors (80%) had LOH at chromosome arm 22q and that 5 of 30 (17%) had LOH at chromosome band 11p15.5. All of the five tumors with LOH at chromosome arm 11p also had LOH at chromosome arm 22q. The data suggest that there is a gene in chromosome 22, probably a tumor suppressor, inactivation of which may be involved in the genesis of renal rhabdoid tumors. A second gene in chromosome segment 11p15.5, in the region of the putative WT2 gene, may also be involved, in at least a subset of rhabdoid tumors. In addition, five tumors were characterized by microsatellite instability at three or more of 21 loci examined, suggesting a possible role for a replicative error in tumorigenesis or progression in some cases of renal rhabdoid tumors. Genes Chromosom Cancer 15:10–17 (1996). © 1996 Wiley-Liss, Inc.     

Clinical significance of allelic loss of chromosome region 5q22.3 approximately q23.2 in nonpapillary renal cell carcinoma

To analyze the clinical significance of copy number gain and loss at chromosome region 5q21 approximately q23, 105 nonpapillary renal cell carcinomas (RCC) were examined by interphase cytogenetic analysis using the dual-color fluorescence in situ hybridization (FISH) technique. DNA probes for D5S23 (5p15.2), cCI5-243 (5q21.2 approximately q21.3), and cCI5-215 (5q22.3 approximately q23.2) were used, and the signals for cCI5-243 and cCI5-215 were compared with those for D5S23 as the numerical control. Aneusomy (three or more copies) of chromosome 5 was found in 22 tumors (21.0%). Aneusomy was significantly correlated with loss at 5q21 approximately q23, while disomy with gain at 5q21 approximately q23 (P<0.05). Aneusomy was also significantly related to poor disease-specific survival (P<0.01). Gain and loss at cCI5-243 were seen in 34 (32.4%) and 59 (56.2%) tumors, respectively, while gain and loss at cCI5-215 occurred in 55 (52.4%) and 45 (42.9%) cases, respectively. The frequency of gain at cCI5-215 was significantly correlated with a smaller tumor diameter (7 cm or less, P<0.05), while loss with a larger one (>7 cm, P<0.05). Both loss at cCI5-215 and aneusomy of chromosome 5 were significantly related to poor disease-specific survival (P<0.05). In conclusion, alterations of chromosome 5 (including allelic loss of 5q22.3 approximately q23.2) could be a useful genetic marker for predicting the patient prognosis of RCC.     

Mapping of nasopharyngeal carcinoma tumor-suppressive activity to a 1.8-megabase region of chromosome band 11q13

Nasopharyngeal carcinoma (NPC) is a malignancy that is particularly prevalent among populations from Southern China and Southeast Asian countries. Evidence for a genetic contribution to the disease has been documented, although the genetic basis for NPC development is not yet fully understood. Previous functional evidence of tumor-suppressive activity on chromosome band 11q13 in NPC was obtained using a microcell-mediated chromosome-transfer approach with HONE1 NPC cells. In the present study, this region was subjected to a detailed investigation of microcell hybrids and their tumor segregants using microsatellite analysis to narrow down the region of tumor-suppressive activity. Fluorescence in situ hybridization was also performed with BAC and cosmid probes to confirm the microsatellite data. The critical region responsible for tumor suppression was narrowed down to a 1.8-Mb interval, which does not tolerate an additional normal allele by chromosome transfer. One or two alleles from either endogenous or exogenous chromosomes at 11q13 were consistently eliminated during tumor growth. Results of this study suggest that a candidate tumor-suppressor gene, not the MEN1 gene, maps between D11S4907 and GSTP1 in NPC.     

Loss of heterozygosity at 11q23.3 in vasculoinvasive and metastatic squamous cell carcinoma of the cervix

We have previously demonstrated a strong relationship between loss of heterozygosity (LOH) at chromosome 11q23.3 and the presence of extensive tumor plugs in lymphvascular spaces (LVS) in stage 1B cervical carcinoma, suggesting that genes at this locus may regulate vasculoinvasion. This study examined LOH at 11q23.3 in microdissected tumor plugs within LVS and in metastatic foci in lymph nodes (MFLN), as well as corresponding invasive tumor and adjacent cervical intraepithelial neoplasia (CIN) 3 in stage 1B squamous cell carcinoma. Of 49 invasive carcinomas, 38.8% had LOH at 11q23.3. Of 36 tumor plugs in LVS, 39% had LOH at 11q23.3. Twenty percent of 15 MFLN demonstrated LOH at 11q23.3. Patients with LOH at 11q23.3 are significantly more likely to have disease recurrence than patients without LOH at 11q23.3 (P =.02). Of 10 foci of CIN 3, none showed LOH at 11q23.3. Although unlikely to have an impact early in carcinogenesis, tumor-suppressor genes located in the region of 11q23.3 appear to be important in tumor progression, facilitating lymphvascular space invasion and, by inference, spread to lymph nodes in squamous cell carcinoma of the cervix.     

Deletion in chromosome region 22q11 in a child with CHARGE association

We present a female child with features of the CHARGE association including iris coloboma, large ventricular septum defect (VSD), external ear abnormalities, severe growth retardation and moderate mental delay. A submicroscopic deletion in chromsome 22q11 was detected by means of fluorescence in situ hybridization (FISH) using probe D0832. The clinical features in this child compromise characteristics of both the velo-cardio-facial syndrome (VCFS) and the cat-eye syndrome. This may suggest the presence of a more complex rearrangement of 22q, with a deletion-duplication.