Inactivation of the ATM gene in T-cell prolymphocytic leukemias

T-cell prolymphocytic leukemia (T-PLL) is a rare form of mature leukemia that occurs both in adults as a sporadic disease and in younger patients suffering an hereditary condition, ataxia telangiectasia (AT). The ATM gene, located in the 11q22-23 chromosomal region, is consistently mutated in AT patients. The strong predisposition of AT patients to develop T-PLL and the high frequency of T-cell leukemias/lymphomas observed in atm-deficient mice, together with the known functions of the ATM protein, led us to evaluate the ATM gene as a potential tumor suppressor gene involved in T-PLL. Paired leukemic and nonleukemic cells were obtained from a series of 15 patients suffering sporadic T-PLLs, allowing loss of heterozygosity (LOH) analysis. LOH of the 11q22-23 region was detected in 10 of these 15 cases (67%). The minimal deleted region was defined as an approximately 2.5 Mb interval that contained the ATM gene. No ATM rearrangement or biallelic deletion was detected by Southern blotting in the T-PLL series. However, in five T-PLLs with LOH of the 11q22-23 region, Western blot analysis showed either undetectable (3 cases) or decreased levels (1 case) of ATM protein, whereas ATM was present at high levels in cases without LOH. The protein truncation test (PTT) was then used to search for mutations in the ATM gene. Four mutations (1 nonsense, 2 aberrant splicings, and 1 missense) were detected in patients with LOH and none in patients without LOH of the region. The acquired character of these ATM mutations was demonstrated in three patients. Altogether, allelic ATM inactivations by large deletions or mutations were found in approximately two thirds of T-PLL. ATM is thus a tumor suppressor gene whose inactivation is a key event in the development of T-cell prolymphocytic leukemias.     

The comparative effects of the NOS inhibitor, Nomega-nitro-L-arginine, and the haemoxygenase inhibitor, zinc protoporphyrin IX, on tumour blood flow

The present study was undertaken to analyse the loss of heterozygosity (LOH) of the three genes, BRCA1, BRCA2 and ATM, and their correlation to clinicopathological parameters in sporadic breast cancer. We studied 59 sets of invasive ductal carcinoma, compared to matched normal control DNA. Microsatellite markers intragenic to BRCA1 (D17S1323, D17S1322, D17S855), BRCA2 (D13S1699, D13S1701, D13S1695) and ATM (D11S2179) were simultaneously used. In addition, one marker telomeric to BRCA2 (D13S1694) and four markers flanking ATM were analysed (D11S1816, D11S1819, D11S1294, D11S1818). Thirty-one per cent of the informative cases showed loss of heterozygosity for the BRCA1 gene, 22.8% for BRCA2 gene and 40% for ATM. LOH of BRCA1 correlated with high grade tumors (p=0.0005) and negative hormone receptors (p=0.01). LOH of ATM correlated with higher grade (p=0.03) and a younger age at diagnosis (p=0.03) in our set of tumors. No correlations were detected between BRCA2 LOH and any of the analysed clinicopathological parameters. However, a correlation was detected between allelic loss of the D13S1694 marker, telomeric to BRCA2, and larger tumor sizes and negative estrogen receptors, favoring the hypothesis of the presence of another putative tumor suppressor gene, telomeric to BRCA2, in the 13q12-q14 region. Only 11 tumors had LOH at more than one of the three genes, most of them (6/11) associated LOH of BRCA1 and ATM. One tumor only combined loss of the three genes BRCA1, BRCA2 and ATM.     

Definition and refinement of a region of loss of heterozygosity at 11q23.3-q24.3 in epithelial ovarian cancer associated with poor prognosis

Previous cytogenetic and loss of heterozygosity (LOH) data suggest that disruption of chromosome 11q23-qter occurs frequently in epithelial ovarian cancer and is associated with an adverse clinicopathological phenotype. Ten polymorphic microsatellite repeat loci were analyzed by PCR from the 11q22-q25 region between D11S35 and D11S968 in 40 ovarian tumors (including 31 epithelial ovarian cancers). Two distinct regions of loss were detected, suggesting possible sites for genes involved in epithelial ovarian neoplasia: a large centromeric region between D11S35 and D11S933 (11q22-q23.3) and a telomeric 8.5-Mb region lying between D11S934 and D11S1320 (11q23.3-24.3) not previously defined. LOH of the latter region but not the former one was significantly associated with poor survival, despite all tumors in this study having LOH somewhere on chromosome 11. This analysis provides a starting point for positional cloning.     

Memory-impairing effects of local anesthetics in an elevated plus-maze test in mice

Detailed deletion mapping of chromosome 6q has shown that the highest percentage of loss of heterozygosity (LOH) is located at 6q25-q27 and suggested that an ovarian cancer associated tumor suppressor gene may reside in this region. To further define the smallest region of common loss, we used 12 tandem repeat markers spanning a region no more than 18 cM, located between 6q25.1 and 6q26, to examine allelic loss in 54 fresh and paraffin embedded invasive ovarian epithelial tumor tissues. Loss of heterozygosity was observed more frequently at the loci defined by marker D6S473 (14 of 32 informative cases, 44%) and marker D6S448 (17 of 40 informative cases, 43%). Detailed mapping of chromosome 6q25-q26 in these tumor samples identified a 4 cM minimal region of LOH between markers D6S473 and D6S448 (6q25.1-q25.2). Loss of heterozygosity at D6S473 correlated significantly both with serous versus non-serous ovarian tumors (P=0.040) and with high grade versus low grade specimens (P=0.023). The results suggest that a 4 cM deletion unit located at 6q25.1-q25.2 may contain the putative tumor suppressor gene which may play a role in the development and progression of human invasive epithelial ovarian carcinomas (IEOC).     

Waist to hip ratio and psychosocial factors in adults with insulin-dependent diabetes mellitus: the Pittsburgh Epidemiology of Diabetes Complications study

Loss of heterozygosity (LOH) at several chromosomal loci is a common feature of the malignant progression of human tumors. In the case of chromosome 11, LOH has been well documented in several types of solid neoplasms, including gastric carcinoma, suggesting the presence of suppressor gene(s) at 11p15 and 11q22-23. Little is currently known about the molecular events occurring during the development of gastric cancer. To define the regions of chromosome 11 involved in gastric cancer progression, we used high-density polymorphic markers to screen for LOH in matched normal and tumor tissue DNA from 60 primary gastric carcinomas. We found that 21% of the tumors showed LOH simultaneously at 11p15 and 11q22-23, 41% had LOH at 11p15, and 30% had LOH at 11q22-23. We confirm that the minimal critical area of LOH for 11p15.5 is the approximately 2-Mb region between loci D11S1318 and D11S988. However, when we analyzed the pattern of LOH according to the country of origin of the patient, LOH for 11q22-23 alone was found only in cases from Italy. The minimal critical region of LOH at 11q22-23 is identical to that identified for other solid tumors, suggesting that the same putative tumor suppressor gene(s) contained within this region is involved in the pathogenesis of several common human tumors.     

Leukocyte migration in acute colonic inflammatory bowel disease: comparison of histological assessment and Tc-99m-HMPAO labeled leukocyte scan

Loss of heterozygosity (LOH) on chromosome 11 is frequently altered in various epithelial cancers. The present study was designed to investigate LOH on chromosome 11 in microdissected samples of normal prostatic epithelium and invasive carcinoma from the same patients. For this purpose, DNA was extracted from the microdissected normal and tumor cells of 38 prostate cancers, amplified by polymerase chain reaction PCR and analyzed for LOH on chromosome 11 using 9 different polymorphic DNA markers (D11S1307, D11S989, D11S1313, D11S898, D11S940, D11S1818, D11S924, D11S1336 and D11S912). LOH on chromosome 11 was identified in 30 of 38 cases (78%) with at least one marker. Four distinct regions of loss detected were: 1) at 11p15, at loci between D11S1307 and D11S989; 2) at 11p12, on locus D11S131 (11p12); 3) at 11q22, on loci D11S898, D11S940 and D11S1818; and 4) at 11q23-24, on loci between D11S1336 and D11S912. We found 25% of the tumors with LOH at 11p15; 39% had LOH at 11p12; 66% had LOH at 11q22; and 47% had LOH at 11q23-24. These deletions at 11p15, 11p12, 11q22 and 11q23-24 loci were not related to the stage or grade of the tumor.     

Rearrangements of the MLL gene in therapy-related acute myeloid leukemia in patients previously treated with agents targeting DNA-topoisomerase II

Chromosome band 11q23 is frequently involved in acute myeloid leukemia (AML) and acute lymphoblastic leukemia (ALL) de novo, as well as in myelodysplastic syndromes (MDS) and lymphoma. Five percent to 15% of patients treated with chemotherapy for a primary neoplasm develop therapy-related AML (t-AML) that may show rearrangements, usually translocations involving band 11q23 or, less often, 21q22. These leukemias develop after a relatively short latent period and often follow the use of drugs that inhibit the activity of DNA-topoisomerase II (topo II). We previously identified a gene, MLL (myeloid-lymphoid leukemia or mixed-lineage leukemia), at 11q23 that is involved in the de novo leukemias. We have studied 17 patients with t-MDS/t-AML, 12 of whom had cytogenetically detectable 11q23 rearrangements. Ten of the 12 t-AML patients had received topo II inhibitors and 9 of these, all with balanced translocations of 11q23, had MLL rearrangements on Southern blot analysis. None of the patients who had not received topo II inhibitors showed an MLL rearrangement. Of the 5 patients lacking 11q23 rearrangements, some of whom had monoblastic features, none had an MLL rearrangement, although 4 had received topo II inhibitors. Our study indicates that the MLL gene rearrangements are similar both in AML that develops de novo and in t-AML. The association of exposure to topo II-reactive chemotherapy with 11q23 rearrangements involving the MLL gene in t-AML suggests that topo II may play a role in the aberrant recombination events that occur in this region both in AML de novo and in t-AML.     

Identification of two distinct deletion targets at 11q23 in cutaneous malignant melanoma

Karyotypic and molecular data indicate that genetic alterations of the long arm of chromosome 11 (11q) are involved in the pathogenesis of malignant melanoma as well as of other malignancies. We have shown previously, by analysis of loss of heterozygosity (LOH), that a tumor-suppressor gene playing an important role in malignant melanoma is likely to be located within a 51-cM region at 11q23. Its loss appeared to be a late event in tumor progression and an indicator of a less favorable clinical outcome. To further test this hypothesis on a larger set of tumors and to refine the region(s) of common allelic loss, we analyzed 21 polymorphic microsatellite repeats on 11q. A PCR-based assay for LOH was used to study normal and tumor tissues from 53 individuals with primary cutaneous malignant melanoma or metastatic disease. Our findings indicate that in cutaneous malignant melanoma there are at least 2 distinct regions of common allelic loss on 11q, one of them centered around marker APOC3 at 11q23.1-q23.2 delineated by markers D11S1347 and D11S4142 and spanning approximately 5 Mb and a second 3-Mb region around marker D11S925 at 11q23.3 delineated by markers D11S528 and D11S1345. Both regions have been described as deletion targets or as being included within larger allelic deletions detected in several other common tumor types. Thus, these 2 putative melanoma-suppressor loci are likely to harbor tumor-suppressor genes relevant to tumorigenesis of melanoma and a number of other common human malignancies.     

Allelotype analysis of oesophageal adenocarcinoma: loss of heterozygosity occurs at multiple sites

Deletions of tumour-suppressor genes can be detected by loss of heterozygosity (LOH) studies, which were performed on 23 cases of adenocarcinoma of the oesophagus, using 120 microsatellite primers covering all non-acrocentric autosomal chromosome arms. The chromosomal arms most frequently demonstrating LOH were 3p (64% of tumours), 5q (45%), 9p (52%), 11p (61%), 13q (50%), 17p (96%), 17q (55%) and 18q (70%). LOH on 3p, 9p, 13q, 17p and 18q occurred mainly within the loci of the VHL, CDKN2, Rb, TP53 and DCC tumour-suppressor genes respectively. LOH on 5q occurred at the sites of the MSH3 mismatch repair gene and the APC tumour-suppressor gene. 11p15.5 and 17q25-qter represented areas of greatest LOH on chromosomes 11p and 17q, and are putative sites of novel tumour-suppressor genes. LOH on 9p was significantly associated with LOH on 5q, and tumours demonstrating LOH at both the CDKN2 (9p21) and MSH3 (5q11-q12) genes had a significantly higher fractional allele loss than those retaining heterozygosity at these sites. Six of nine carcinomas displaying microsatellite alterations also demonstrated LOH at CDKN2, which may be associated with widespread genomic instability. Overall, there are nine sites of LOH associated with oesophageal adenocarcinoma.     

MLL gene rearrangement, cytogenetic 11q23 abnormalities, and expression of the NG2 molecule in infant acute myeloid leukemia

To study prognostic factors in infant acute myeloid leukemia (AML), we analyzed 44 children treated on Childrens Cancer Group protocols for MLL gene rearrangement by Southern blot, cytogenetic 11q23 abnormalities, and reactivity with monoclonal antibody 7.1. This antibody detects the human homologue of the rat NG2 chondroitin sulfate proteoglycan molecule, which has previously been reported to be expressed on human melanoma. NG2 has been found to be expressed on human leukemic blasts but not on other hematopoietic cells. In childhood AML, NG2 cell surface expression correlated with poor outcome and with some but not all 11q23 rearrangements. In childhood acute lymphoblastic leukemia, NG2 expression correlated with poor outcome and with balanced 11q23 translocations. In this study, 29 of 44 (66%) of infants with AML showed MLL rearrangement and, as expected, this group had a high incidence of French-American-British M4/M5 morphology (22/29). Of the cases tested, 35.1% (13/37) were NG2 positive. All (13/13) NG2-positive cases were rearranged at MLL, whereas only 46% (11/24) of NG2-negative cases had MLL rearrangement. NG2 expression did not correlate with poor outcome (P = .31); there was a trend towards a worse outcome with MLL rearrangement (P = .13). Thus monoclonal antibody 7.1 does not detect all cases of MLL rearrangement in infant AML.     

Confirming false memories: social construction of "useful" meanings

Ataxia-telangiectasia (A-T) is a multisystem recessive disease characterized by cerebellar ataxia, oculocutaneous telangiectasias, immunodeficiency and increased risk of cancer. The ATM gene, responsible for A-T, was recently cloned at human chromosome band 11q22-23, a region of frequent alterations in childhood acute lymphoblastic leukaemia (ALL). Children with A-T frequently develop T-ALL. We investigated 18 T-ALL samples for ATM mutations and loss of heterozygosity (LOH) at the ATM locus. No mutations of ATM were found within the coding region in the 18 T-ALL samples, and LOH at the ATM locus was detected in three. The ATM gene appears to be an infrequently altered tumour suppressor gene in childhood T-ALL.     

ALL-1 gene rearrangements in DNA topoisomerase II inhibitor-related leukemia in children

We examined clinical, morphologic, and cytogenetic features and ALL-1 (MLL, Htrxl, HRX) gene rearrangements in 17 cases of secondary leukemia that occurred 11 months to 9 years from diagnoses of primary cancers in children who received topoisomerase II inhibitors or developed secondary leukemias typical of those associated with this therapy. Primary diagnoses included nine solid tumors and eight leukemias. Ten secondary leukemias were acute myeloid leukemia (AML), one was of mixed lineage, two were acute lymphoblastic leukemia (ALL), and four presented as myelodysplasia. Of 15 cases with 11q23 involvement, 11 (73%) were cytogenetically identifiable; four cases had molecular rearrangement only. By Southern blot, rearrangements within the ALL-1 gene were similar to sporadic cases. The results of this analysis suggest the following: (1) In most pediatric cases of topoisomerase II inhibitor-associated leukemia, there is disruption of the breakpoint cluster region of the ALL-1 gene at chromosomal band 11q23. (2) Exposure histories vary in secondary 11q23 leukemia, as the only topoisomerase II inhibitor was dactinomycin in one case, and, in another case, no topoisomerase II inhibitor was administered. (3) There is clinical, morphologic, cytogenetic, and molecular heterogeneity in pediatric secondary 11q23 leukemia. (4) There are some survivors of pediatric secondary 11q23 leukemia, but the outcome is most often fatal.     

Molecular analysis of infant acute leukemia

Infant acute leukemia, known to have a poor outcome with conventional therapy, usually has a molecular rearrangement at chromosome band 11q23. The 11q23 translocation partner is typically at 4q21 in infant ALL, but other 11q23 translocation partners occur in infant ALL and AML. The MLL gene at 11q23, and the AF4 gene at 4q21, have been extensively studied to identify heterogeneity of structural rearrangement and prognostic indicators, to look for clues as to etiology, and to improve therapy.     

Allelic loss on chromosome 7q in ovarian adenocarcinomas: two critical regions and a rearrangement of the PLANH1 locus

The presence of a tumour suppressor gene on chromosome 7q is indicated by cytogenetic, loss of heterozygosity (LOH) and chromosome transfer studies. One candidate gene in this region is Plasminogen Activator Inhibitor-1 (PAI-1). The PAI-1 gene product is involved in proteolysis and may therefore influence tumour spread and invasion. We have analysed a series of 139 ovarian epithelial tumours at four loci in the region 7q21-q31 which includes the PAI-1 gene. The highest rates of loss were found in malignant tumours (FIGO stages I-IV) at markers D7S471 (38%, 20/52 informative cases) and D7S522 (34%, 15/44). No loss was seen in benign tumours and only one out of 27 (4%) informative LMP tumours demonstrated LOH. The smallest region of overlap (SRO) lies between D7S471 and PAI-1. We also identified a rearrangement in one tumour in the PAI-1 gene, suggesting that this may be the inactivated gene in this region. In addition LOH at the more distal marker, D7S522, which lies outside the SRO, shows significant association with stage (P=0.0343) and with LOH on chromosome 13 (P=0.0024). This is in contrast to all other markers examined. These data suggest the presence of two critical regions on 7q which may be important in subsets of epithelial ovarian tumours.     

The structure and organization of the human NPAT gene

Ataxia telangiectasia (AT) is an autosomal recessive gene disorder, and ATM, a housekeeping gene, has been identified as the gene responsible for AT. Recently we found that another housekeeping gene, NPAT, is located upstream of ATM on human chromosome 11. The two housekeeping genes are transcribed in opposite directions and share a 0.5-kb 5' flanking sequence. The structure and organization of NPAT were determined by direct sequencing of cosmid clones carrying the gene and by application of the long and accurate (LA)-PCR method to amplify regions encompassing the exon/intron boundaries and all of the exons. The gene spans at least 44 kb and consists of 18 exons and 17 introns. It has been suggested that AT heterozygotes have an increased risk of developing cancer, especially breast cancer in women. Frequently, loss of heterozygosity at loci on 11q22-q24 has been observed in DNA isolated from tumors of the breast, uterine cervix, and colon, perhaps suggesting the location of a tumor suppressor gene in 11q22-q24. For investigation of the role of NPAT in AT and these tumors with allelic loss of 11q22-q24, appropriate primer sequences and PCR conditions for amplification of all the NPAT exons from genomic DNA were determined. We previously reported that no recombinations are found among Atm, Npat, and Acat1 (acetoacetyl-CoA thiolase) loci as determined by fine genetic linkage mapping of the mouse AT region. The results of the LA-PCR analysis using NPAT- and ACAT-specific primers and human genomic DNA allowed us to map ACAT 12 kb centromeric to NPAT.     

Appetitive motivational states differ in their ability to augment aversive fear conditioning in rats (Rattus norvegicus)

An expression map containing 48 ESTs was constructed to identify a tumor-suppressor gene involved in B-cell chronic lymphocytic leukemia (B-CLL), which was previously assigned to chromosome band 13q14.3 close to genetic markers D13S25 and D13S319. Thirty-nine of these 48 ESTs, together with 11 additional ones listed in databases, were initially assigned to chromosome 13q14 between markers D13S168 and D13S176. Nine others have recently been located in the D13S319 region. Our results indicate that 48 of the 59 ESTs analyzed belong to a YAC contig of chromosome 13 band q14, and 22 are contained on YAC 933e9, which encompasses the B-CLL critical region. Ten of these 22 ESTs were accurately assigned on a PAC, BAC, and cosmid contig encompassing the smallest minimal deletion area described so far in B-CLL, and 20 were tested for their expression on 27 normal or tumor tissues. One EST appears to be a likely candidate for the tumor-suppressor gene involved in B-CLL.     

Loss of heterozygosity at 11q23 in squamous cell carcinoma of the head and neck is associated with recurrent disease

Loss of heterozygosity (LOH) at chromosome 11q23 has been found in a variety of epithelial human neoplasms, suggesting that this region contains a tumor suppressor gene(s) important to tumorigenesis. We investigated whether LOH at 11q23 could be detected in squamous cell carcinoma of the head and neck (SCCHN), and whether loss at this site was associated with specific clinical parameters. Fifty-six matched blood and SCCHN tumor samples taken at the time of diagnosis were evaluated for LOH at three microsatellite markers at 11q23. Multiplex PCRs with [alpha-32P]dCTP labeling of the amplified DNA strands were performed. Clinical data were obtained from medical record review. LOH at 11q23 was found in 13 of 52 (25%) evaluable tumors. There was no association between LOH at 11q23 and amplification of the CCND1 (cyclin D1) oncogene or inactivation of the p53 gene, which had been determined previously. With a mean follow-up of 24 months, an association independent of tumor size or stage was found between LOH at 11q23 and recurrent disease (P = 0.04). Among subjects who received radiotherapy (RT) as a component of their treatment, LOH at 11q23 was associated with persistent or recurrent locoregional disease (P = 0.05). LOH at 11q23 occurs in a subset of SCCHN. It is associated with a higher likelihood of recurrent disease, perhaps related to resistance to RT. The specific gene(s) and mechanism(s) responsible remain to be identified. Until then, LOH at 11q23 might become a marker identifying patients likely to do poorly with conventional therapy.     

A histometrical study on the long bones of raccoon dogs, Nyctereutes procyonoides and badgers, Meles meles

In June 1994, a 39 year-old male with adult T-cell leukemia was admitted to our hospital and received combination chemotherapy including epipodophyllotoxin for approximately 1 year. The monocyte count increased gradually beginning in April 1995, accelerating to 100 x 10(9)/l in January 1996, when he was diagnosed with acute monocytic leukemia. Inv(11)(q21;q23) x 2 was recognized at that time by chromosome analysis, and rearrangement of the MLL gene was shown by Southern blot analysis. From the clinical course and subsequent examinations, the case was regarded as epipodophyllotoxin-related secondary leukemia. Recently, epipodophyllotoxin has frequently been used as a treatment agent for adult T-cell leukemia. It is valuable to note that secondary leukemia may follow even such an aggressive leukemia as adult T-cell leukemia.