Deletion in chromosome bands 11q22-q23 is one of the most common chromosome aberrations in B-cell chronic lymphocytic leukemia (B-CLL). It is associated with extensive lymph node involvement and poor survival. The minimal consensus deletion comprises a segment, which contains the ATM gene presenting an interesting candidate gene, as mutations in ATM predispose A-T patients to lymphoid malignancies. To investigate a potential pathogenic role of ATM in B-cell tumorigenesis, we performed mutation analysis of ATM in 29 malignant lymphomas of B-cell origin (B-CLL = 27; mantle cell lymphoma, [MCL] = 2). Twenty-three of these carried an 11q22-q23 deletion. In five B-CLLs and one MCL with deletion of one ATMallele, a point mutation in the remaining allele was detected, which resulted in aberrant transcript splicing, alteration, or truncation of the protein. In addition, mutation analysis identified point mutations in three cases without 11q deletion: two B-CLLs with one altered allele and one MCL with both alleles mutated. In four cases analyzed, theATM alterations were not present in the germ line indicating a somatic origin of the mutations. Our study demonstrates somatic disruption of both alleles of the ATM gene by deletion or point mutation and thus its pathogenic role in sporadic B-cell lineage tumors.

MUTATIONS IN THE ATM (ataxia telangiectasia mutated) gene are responsible for the autosomal recessive disorder ataxia telangiectasia (A-T). A-T is characterized by neurologic degeneration, immunodeficiency, infertility, radiation sensitivity, and a marked predisposition to cancer (for review, see Sedgewick and Boder,1 Lavin and Shiloh,2 and Jeggo et al3). The cellular phenotype of A-T includes hypersensitivity to ionizing radiation, genome instability, and dysregulation of the cell cycle checkpoints.2,3 The ATM gene is localized in the chromosomal region 11q22.3-q23.1 and consists of 66 exons spanning 146 kb of genomic DNA. The gene encodes a 370-kD nuclear phosphoprotein sharing homology with phosphatidylinositol 3-kinase (PI-3-K). It is known that PI-3-K–related proteins function in DNA repair, in DNA recombination, and in cell cycle control.4-10 

One of the most intriguing features of A-T is the increased predisposition to develop malignancies. The predominant cancers among these are neoplasms of the lymphoid system including both B- and T-cell tumors11 with a risk for leukemia approximately 70 times higher than in the normal population.12 Individuals with heterozygous ATM mutations have also been suggested to be at elevated risk for cancer, particularly for carcinoma of the breast.13 Several studies of breast cancer patients, however, did not find ATM mutations in a frequency higher than expected by chance (eg, Vorechovsky et al,14 FitzGerald et al,15 Bay et al,16 and Chen et al17). Thus, the role of ATM in breast tumors remains unresolved. Recently, biallelic mutations of the ATM gene have been identified in T-prolymphocytic leukemia (T-PLL) of patients without A-T history indicating a tumor-suppressor function of ATM in sporadic T-PLL.18-21 Although loss of heterozygosity in the 11q22-q23 region has been frequently observed in various types of tumors22 (and references therein), to date T-PLL is the only sporadic tumor for which recurrent somatic inactivation of both alleles of the ATM gene has been demonstrated.

In B-cell chronic lymphocytic leukemia (B-CLL), we identified deletion of the chromosomal region 11q22-q23 as a recurrent aberration by using fluorescence in situ hybridization (FISH) in a large series of more than 200 B-CLLs.23,24 Loss of the region was shown to be a prognostic marker predicting poor survival.24 The commonly deleted region was defined as a 2 to 3 megabasepairs (Mbp) segment, which contains the ATM, DDX10, RDX(radixin), and FDX1 (ferredoxin 1) genes.23 24 The frequent monoallelic deletion of the gene in sporadic B-CLL and the association between ATM inactivation and the development of T- and B-cell leukemia in A-T patients had led us to analyze the ATM gene in malignant B-cell lymphoma.

Patient and control material.

The study comprised 29 patients with malignant lymphoma of B-cell type and 50 unrelated healthy probands of central European origin. Samples were collected after informed consent. Based on morphology and immunophenotype, the tumors were classified as B-CLL (n = 27) and mantle cell lymphoma (MCL, n = 2). Dual-color interphase FISH detected deletions of chromosome bands 11q22-q23 in 22 of the B-CLL cases and one of the MCL cases (MCL-A) and translocations affecting 11q23 in two B-CLLs (B-CLL-F and -H). Many of these cases were contained in the study by Stilgenbauer et al.23 Both MCLs were shown to have a t(11;14)(q13;q32). None of the patients had clinical evidence for A-T. From six B-CLL patients and one MCL patient, skin biopsies were available serving as specimen for the analysis of the ATMgermline status.

Mutation analysis of the ATM gene.

Total RNA and genomic DNA from mononuclear cell preparations of malignant B-cell lymphomas and control persons were extracted with the Trizol reagent (Gibco BRL, Eggenstein, Germany). Genomic DNA from skin biopsy cells was isolated with the QIAamp kit (Qiagen, Hilden, Germany) and from normal healthy controls by the standard phenol-chloroform method.

The following oligonucleotides were used for polymerase chain reaction (PCR) and sequence analysis:

1A, 1B, 2A, 2B, 4A, 4A2, 4B, 5A, 5B, 6A, and 6B are listed in Stilgenbauer et al.18 Additionally used primers were 1A1 (exon 38) 5′-TGGATAAAGACACTGACT-3′; 1A2 (exon 39/40) 5′-GGATTCAGAGTCAGAGCAC-3′; 1B1 (exon 41) 5′-CAGCACAAGACTGAGCTACC-3′; 3A (exon 42/43) 5′-CTGGAATAAGTTTACAGGATCTTC-3′; 3B (exon 51) 5′-GATGATTTCATGTAGTTTTCAATTC-3′; 4A1 (exon 59) 5′-GAATGGTGCACAGGAACTG-3′; 4B3 (exon 61) 5′-TCTGTACATGTCTATCACC-3′; 5B1 (exon 52) 5′-TACCCACATATCATGTTC-3′; 39A (intron 38) 5′-CATTTTTACTCAAACTATTG-3′; 39B (intron 39) 5′-TCTTAAATCCATCTTTCTCTA-3′; 59A (intron 58) 5′-AGGTCAACGGATCATCAAAT-3′; 59B (intron 59) 5′-TTAATTTTGGGTGTCACTC-3′; 65A (intron 64) 5′-TTAAACTGTTCACCTCACTGA-3′; 65B (exon 65) 5′-GTTAAAAATAAAGGCTAAAATA-3′.

1A1, 1A2, 1B1, 4A1↑, 4B3, and 5B1 were derived from cDNA sequence data of the ATM gene (GenBank accession no. U33841). PCR amplification of the exons 39, 59, the coding part of exon 65, and the flanking intronic regions from genomic DNA was performed according to Vorechovsky et al14 using primer pairs 39A/B, 59A/B, and 65A/B.

Reverse-transcription PCR (RT-PCR) and single-strand conformation polymorphism (SSCP) analysis were performed as described previously.18 25 Single-strand cDNA was synthesized using random hexamers (GeneAmp RNA PCR System, Perkin-Elmer, Weiterstadt, Germany). Six overlapping fragments covering 6.2 kb of the coding region of the ATM transcript were amplified with primer sets 1A/B, 2A/B, 3A/B, 4A/B, 5A/B, and 6A/B. For SSCP analysis, RT-PCR products were digested with restriction endonucleases and end-labeled with T4 polynucleotide kinase in the presence of γ-33P deoxyadenosine triphosphate. Fragments were separated by electrophoresis through nondenaturing 6% polyacrylamide gels containing 5% glycerol (exclusively for runs at room temperature) in 0.5 × Tris-borate buffer. Electrophoresis was performed at room temperature or at 4°C at 8 W for at least 10 hours. Gels were dried and subjected to autoradiography.

Direct sequencing of PCR and RT-PCR products was performed by cycle sequencing with dye terminator chemistry (ABI PRISM big dye terminator cycle sequencing ready reaction kit, Perkin-Elmer). Sequencing reactions were run on a Perkin-Elmer ABI-377 automated sequencer.

To test whether the two heterozygote mutations identified in MCL-B were localized on the same ATM transcript, RT-PCR products amplified with primer set 5A/B were cloned into pT-Adv (AdvanTAge PCR Cloning Kit, Clontech, Heidelberg, Germany). Insert DNA from individual clones was amplified by colony PCR using the original PCR primers and PCR conditions. Amplified DNA fragments were subsequently sequenced.

Mutations in malignant B-cell lymphomas with 11q deletions.

Based on FISH analysis, 23 malignant lymphomas of B-cell type (22 B-CLL cases; one MCL case) with monoallelic deletions of chromosomal region 11q22-q23 were selected for mutation screening in the ATM gene.ATM transcript was analyzed by RT-PCR amplification of a set of six overlapping fragments representing exons 22-30, 29-36, 36-43, 42-51, 51-57, 56-65.25 This 6.2-kb part of the coding region includes the protein domains, which are responsible for the kinase function (exons 57-65) and the binding of c-Abl (exon 30), as well as a postulated rad 3 homology domain (exons 32-42) and a leucine zipper motif (exon 27).4,5,26 27 After digestion with restriction endonucleases, the RT-PCR products were subjected to SSCP analysis.

Aberrantly migrating DNA fragments were found in five cases. Direct sequencing of the corresponding RT-PCR fragments detected one single-base deletion and four single-base substitutions as detailed in Table 1. The deletion of one nucleotide in B-CLL-A causes a frameshift after codon 2804 resulting in a truncation of the protein at this position and the loss of about 70% of the kinase domain (Fig 1A). In B-CLL-B, a transition creates a new stop codon at position 3047, which leads to the removal of the last 10 amino acids from the translation product (Fig 1B). In three cases, amino acid substitutions were detected. Two of them are predicted to alter the protein structure in the PI-3-K domain (in B-CLL-D and B-CLL-E), the other one affected the so-called rad 3 homology domain (in B-CLL-C). The nonmalignant cells from B-CLL-B (Fig 1B), B-CLL-D, and B-CLL-E, obtained by skin biopsy, did not harbor the same nucleotide changes as the malignant cells, indicating a somatic, but not a germline origin of the mutations in all three cases.

Table 1.

Alterations Affecting Both ATM Alleles in Malignant B-Cell Lymphomas of Non–A-T Individuals

B-Cell Lymphoma First AlleleSecond Allele
DNA*,Gene Product DNAGene Product
B-CLL-A  del(11q22-q23) —  8412delA (exon 59)  Frameshift after codon 2804 + truncation of the protein  
B-CLL-B1-153 del(11q22-q23)  —  9139C > T (exon 65)  Arg3047ter 
B-CLL-C  del(11q22-q23)  —  5858C > G (exon 41) Thr1953Arg  
B-CLL-D1-153 del(11q22-q23)  — 9023G > A (exon 65)  Arg3008His  
B-CLL-E1-153 del(11q22-q23)  —  9054A > C (exon 65)  Lys3018Asn 
MCL-A1-153 del(11q22-q23)  —  IVS59 + 1G > T (intron 59)  Skipping of exon 59: Del Val2757-Met2806 
B-CLL-F  Nondeleted Unknown
 
5558A > T (exon 39)  Asp1853Val  
B-CLL-G  Nondeleted  Unknown
 
7258G > C (exon 51)  Ala2420Pro  
MCL-B  7268A > G (exon 51)  Glu2423Gly
 
7250insGAA (exon 51)  Ins Lys2419 
B-Cell Lymphoma First AlleleSecond Allele
DNA*,Gene Product DNAGene Product
B-CLL-A  del(11q22-q23) —  8412delA (exon 59)  Frameshift after codon 2804 + truncation of the protein  
B-CLL-B1-153 del(11q22-q23)  —  9139C > T (exon 65)  Arg3047ter 
B-CLL-C  del(11q22-q23)  —  5858C > G (exon 41) Thr1953Arg  
B-CLL-D1-153 del(11q22-q23)  — 9023G > A (exon 65)  Arg3008His  
B-CLL-E1-153 del(11q22-q23)  —  9054A > C (exon 65)  Lys3018Asn 
MCL-A1-153 del(11q22-q23)  —  IVS59 + 1G > T (intron 59)  Skipping of exon 59: Del Val2757-Met2806 
B-CLL-F  Nondeleted Unknown
 
5558A > T (exon 39)  Asp1853Val  
B-CLL-G  Nondeleted  Unknown
 
7258G > C (exon 51)  Ala2420Pro  
MCL-B  7268A > G (exon 51)  Glu2423Gly
 
7250insGAA (exon 51)  Ins Lys2419 
*

The deletion mapping by interphase FISH is described in Stilgenbauer et al23; del(11q22-q23) indicates loss of one copy of the chromosomal region 11q22-q23 containing ATM.

The exon numbering is according to Uziel et al6 and Platzer et al7 (GenBank no. U82828); nucleotide positions refer to the sequence of the ATM transcript (GenBank no.U33841). The first codon of the open reading frame was designated +1. The nomenclature of the mutations was used as suggested by Beaudet and Tsui (1993).46 

B-CLL-F has a translocation in 11q23, which is localized approximately 2 Mbp distal from the ATM gene.23 

F1-153

For those patients, the analysis of the germline status ofATM was possible.

Fig. 1.

Point mutations in the ATM gene in malignant B-cell lymphomas with (A, B, C) and without (D) monoallelic deletions of ATM. Mutations are indicated by arrowheads or by a bar. A, B-CLL-A: SSCP analysis of a 242-bp restriction fragment derived from the RT-PCR product containing exons 56-65 identified an aberrantly migrating fragment. DNA sequence analysis of the respective fragment showed 8412delA causing frameshift and truncation of the protein. DNA sequences of PCR amplified exon 59 are shown. (B) B-CLL-B: SSCP analysis of a 307-bp restriction fragment of the RT-PCR product encompassing exons 56-65 and DNA sequence analysis of the corresponding RT-PCR products identified the nonsense mutation 9139C>T (Arg3047ter). Note that the amount of cells with an 11q22-q23 deletion was 58% in the tumor sample, and therefore the signal intensity of the normal allele was unusually high. DNA sequence analysis of exon 65 from patient’s germline DNA showed absence of the mutation in the germ line. (C) MCL-A: The splice-donor site mutation in intron 59 (IVS59+1G>T), which causes skipping of exon 59 from the ATMtranscript and loss of 50 amino acids, was detected by DNA sequencing of the RT-PCR fragment containing exons 56-65 and by sequencing of PCR amplified exon 59 and its flanking intronic regions. The patient’s germ line DNA did not contain the mutation. (D) MCL-B: Cloning and subsequent sequencing of RT-PCR fragments harboring exons 51-57 allowed assignment of the two heterozygous mutations 7268A>G and 7250insGAA to two separate ATM transcripts. Thus, both alleles were affected by two independent mutations.

Fig. 1.

Point mutations in the ATM gene in malignant B-cell lymphomas with (A, B, C) and without (D) monoallelic deletions of ATM. Mutations are indicated by arrowheads or by a bar. A, B-CLL-A: SSCP analysis of a 242-bp restriction fragment derived from the RT-PCR product containing exons 56-65 identified an aberrantly migrating fragment. DNA sequence analysis of the respective fragment showed 8412delA causing frameshift and truncation of the protein. DNA sequences of PCR amplified exon 59 are shown. (B) B-CLL-B: SSCP analysis of a 307-bp restriction fragment of the RT-PCR product encompassing exons 56-65 and DNA sequence analysis of the corresponding RT-PCR products identified the nonsense mutation 9139C>T (Arg3047ter). Note that the amount of cells with an 11q22-q23 deletion was 58% in the tumor sample, and therefore the signal intensity of the normal allele was unusually high. DNA sequence analysis of exon 65 from patient’s germline DNA showed absence of the mutation in the germ line. (C) MCL-A: The splice-donor site mutation in intron 59 (IVS59+1G>T), which causes skipping of exon 59 from the ATMtranscript and loss of 50 amino acids, was detected by DNA sequencing of the RT-PCR fragment containing exons 56-65 and by sequencing of PCR amplified exon 59 and its flanking intronic regions. The patient’s germ line DNA did not contain the mutation. (D) MCL-B: Cloning and subsequent sequencing of RT-PCR fragments harboring exons 51-57 allowed assignment of the two heterozygous mutations 7268A>G and 7250insGAA to two separate ATM transcripts. Thus, both alleles were affected by two independent mutations.

Close modal

In MCL-A, RT-PCR fragment 4 containing exons 56-65 showed a significantly smaller size on agarose gels and presented a complete loss of exon 59 when sequenced directly (Fig 1C). Further genomic DNA sequencing showed a G>T transversion at the first nucleotide of intron 59, in the donor-splice junction of exon 59/intron 59, at position 8418+1 (Table 1). According to the RT-PCR sequence data, this nucleotide substitution obviously leads to complete skipping of the in-frame exon 59 from the ATM transcript, which removes 50 amino acids from the kinase domain of the ATM protein. Sequence analysis of genomic DNA from skin cells of this patient showed that this splice-site mutation was not present in nonmalignant cells, indicating a somatic mutation origin (Fig 1C).

Mutations in malignant B-cell lymphomas without 11q deletions.

In addition to B-cell lymphomas with monoallelic 11q deletions, five B-CLL cases and one MCL case without microscopically detectable deletions of chromosome bands 11q22-q23 were searched for ATMmutations (by SSCP and sequence analysis). In one of the two B-CLLs with a translocation approximately 2 Mbp distal from the ATM gene locus, a heterozygous missense mutation in the rad 3 homology domain was identified (B-CLL-F; Table 1). In B-CLL-G, a nucleotide substitution in one allele lead to an amino acid replacement at position 2420 (Table 1). In the same protein region, two heterozygous mutations were detected in MCL-B (Fig 1D): a trinucleotide insertion incorporated an additional lysine at position 2419 and a single-base substitution caused an amino acid exchange at position 2423. Cloning and subsequent sequencing of RT-PCR fragments, which covered both mutational sites allowed the assignment of the mutations to separateATM transcripts, thus indicating two independent mutation events affecting both alleles in MCL-B (Fig 1D).

Identification of a common genetic polymorphism.

In contrast to the aforementioned point mutations, in our series one amino acid substitution was observed more than once: Asp1853Asn (5557G>A) was found in six of the 29 tumor samples analyzed (21%; B-CLL-B, B-CLL-E, B-CLL-H, B-CLL-J, B-CLL-K, B-CLL-L). An estimation of the germline status by sequence analysis of genomic DNA from skin cells was possible in four cases (B-CLL-B, B-CLL-E, B-CLL-J, and B-CLL-K). In B-CLL-J, the 5557A allele was absent in the nonmalignant cells indicating its somatic origin, whereas in the other three patients the 5557A allele was already present in the germ line in a heterozygous form. Interestingly, in one of those cases (B-CLL-B), the 5557A allele was apparently lost during tumorigenesis, as it was only detectable in a low amount in the tumor sample corresponding to the amount of cells without 11q deletion in the specimen (concluded from sequence analysis of both genomic DNA and RT-PCR products). The analysis of 50 samples from healthy controls detected the 5557A allele in 11 samples (22%). Nine samples were heterozygous and two samples were found to be homozygous for 5557A, resulting in an allele frequency of 0.13 in the population studied. Because of the similar frequency of Asp1853Asn positive tumor samples and carriers in the control population, this variant has to be considered a common polymorphism, which seems not to be disease associated. In a recent study of breast cancer patients in Britain, 5557A was also identified as polymorphic allele.28 The single-base substitution 5558A>T in B-CLL-F, which affected the same codon, but caused a different amino acid exchange (Asp1853Val), was not found in the 50 controls and is therefore compatible with the definition of a pathogenic mutation.

Two lines of evidence emphasize the pivotal role of a tumor suppressor gene localized in 11q22-q23 for the leukemogenesis of B-CLL: (1) deletion of this chromosomal region is one of the most frequent chromosome aberrations in this disease.24 (2) The 11q22-q23 deletions have a strong clinical impact, as they define a subset of B-CLL characterized by extensive lymph node involvement, rapid disease progression, and poor survival.24 In the current study, a series of malignant B-cell lymphomas, mostly B-CLLs, with deletions of one copy of chromosome bands 11q22-q23 were analyzed. In six of the 23 analyzed cases, the ATM gene was found affected by a point mutation in the nondeleted allele. Besides those, there was one B-cell lymphoma without 11q deletion, but with mutations in both ATM alleles. The inactivation of both gene copies indicates a pathogenic role ofATM in sporadic B-cell tumors. The identified mutations resulted in aberrant transcript splicing, premature truncation of the protein, or alteration of amino acids. Fifty percent of the mutations affected the PI-3-K domain, which is highly conserved among ATM-related proteins4,5 and crucial for the protein kinase activity of ATM.29,30 Interestingly, three of those mutations correspond to disease-causing mutations in A-T patients and/or mutations associated with T-PLL underlining the pathogenic character of the mutations: (1) the truncation mutation Arg3047ter has been described as an A-T allele9,31-33 and as a mutation in T-PLL19 causing considerable impairment of the protein phosphorylation function of ATM29; (2) the splicing defect caused by IVS59+1G>T resembles A-T mutations, which cause skipping of the affected exon 5925,32,34;(3) the missense mutation Arg3008His replaced the same conserved amino acid as Arg3008Cys in two independent T-PLL cases.18 21 

The PI-3-K domain was recently shown to mediate phosphorylation of p53 in response to DNA damage.29,30 Therefore, mutational inactivation of the kinase domain likely affects the p53 mediated control of the cell cycle and response to DNA damage. Constitutional ATM deficiency in cells of A-T patients (for review, see Lavin and Shiloh2 and Jeggo et al3) andatm−/- mice35-37 was found to lead to dysregulation of apoptosis and cell-cycle check point control, as well as to defects in DNA recombination. These cellular defects are considered to be causative for the development of T-cell lymphomas inatm−/- mice36,38 and lymphoid tumors of both the T- and B-cell lineage in A-T patients.11It is conceivable that somatic ATM inactivation in lymphocytes may result in similar cellular defects, which may contribute to T- and B-cell leukemogenesis in non–A-T patients.

Here, we demonstrate that somatic disruption of the ATM gene occurs not only in sporadic T-PLL,18-21 but is also common for B-cells of malignant B-cell lymphomas, in particular, B-CLLs. Two very recent studies analyzing ATM gene mutation and ATM protein levels reported similar evidence for the role of ATM in B-CLL.39-41However, Stankovic et al40 could not observe loss of heterozygosity of the respective genomic region in a subset of tumors with impaired ATM expression, a fact that could be explained by the existence of a second B-CLL associated gene in the critical genomic segment in 11q.

The mutation frequency observed in our study exceeds by far the expected value of random mutations taking the A-T heterozygote frequency of about 1% in the general population42,43 into account. Therefore, ATM is probably the tumor-suppressor gene in 11q22-q23, whose inactivation is responsible for an aggressive course of B-CLL. There are several reasons why we did not observeATM point mutations in a higher proportion of the cases analyzed: (1) mutation analysis focused on a 6.2-kb part of the coding region encompassing the kinase domain, the c-Abl binding site, the rad3 homology region, and a leucine zipper motif. Mutations could also reside, however, in the N-terminal region of ATM, which was recently shown to interact with β-adaptin,44 or in the nontranslated regions or the promoter region impairing gene expression. (2) While we used a modified SSCP method, also known as restriction endonuclease fingerprinting (REF), which is of considerably enhanced efficiency,45 it is still possible that we missed mutations. (3) The commonly deleted region in 11q22-q23 is 2 to 3 Mbp in size and contains besides ATM several other genes.23 At this point, it cannot be excluded that a second gene with pathogenic function for B-CLL exists in this region (see also above).

For four patients with ATM point mutations in the tumor cells, an assessment of the ATM germline status was possible. Absence of the mutations in the nonmalignant cells in all four cases indicated a somatic origin of the mutations. However, others reported ATMgermline mutations in some of the B-CLL patients carrying ATMmutation40 41 showing the existence of genetic predisposition to B-CLL.

The authors gratefully acknowledge Ralf Klären, Irina Idler, and Markus Scheuermann for their technical assistance.

Supported by the Wilhelm-Sander-Stiftung (97.003.1), the Deutsche Krebshilfe (10-1289-StI), and the Tumorzentrum Heidelberg/Mannheim (I/I.1).

The publication costs of this article were defrayed in part by page charge payment. This article must therefore be hereby marked “advertisement” in accordance with 18 U.S.C. section 1734 solely to indicate this fact.

1
Sedgewick
 
RP
Boder
 
E
Ataxia-telangiactasia
Handbook of Clinical Neurology, vol 16.
Vinken
 
GBP
Klawans
 
H
1991
347
Elsevier
New York, NY
2
Lavin
 
MF
Shiloh
 
Y
The genetic defect in ataxia-telangiectasia.
Annu Rev Immunol
15
1997
177
3
Jeggo
 
PA
Carr
 
AM
Lehmann
 
AR
Splitting the ATM: Distinct repair and checkpoint defects in ataxia-telangiectasia.
Trends Genet
14
1998
312
4
Savitsky
 
K
Sfez
 
S
Tagle
 
DA
Ziv
 
Y
Sartiel
 
A
Collins
 
FS
Shiloh
 
Y
Rotman
 
G
The complete sequence of the coding region of the ATM gene reveals similarity to cell cycle regulators in different species.
Hum Mol Genet
4
1995
2025
5
Savitsky
 
K
Bar-Shira
 
A
Gilad
 
S
Rotman
 
G
Ziv
 
Y
Vanagaite
 
L
Tagle
 
DA
Smith
 
S
Uziel
 
T
Sfez
 
S
Ashkenazi
 
M
Pecker
 
I
Frydman
 
M
Harnik
 
R
Sankhavaram
 
RP
Simmons
 
A
Clines
 
GA
Sartiel
 
A
Gatti
 
RA
Chessa
 
L
Sanal
 
O
Lavin
 
MF
Jaspers
 
NGJ
Taylor
 
MAR
Arlett
 
CF
Miki
 
T
Weissman
 
SM
Lovett
 
M
Collins
 
FS
Shiloh
 
Y
A single ataxia telangiectasia gene with a product similar to PI-3 kinase.
Science
268
1995
1749
6
Uziel
 
T
Savitsky
 
K
Platzer
 
M
Ziv
 
Y
Helbitz
 
T
Nehls
 
M
Boehm
 
T
Rosenthal
 
A
Shiloh
 
Y
Rotman
 
G
Genomic organization of the ATM gene.
Genomics
33
1996
317
7
Platzer
 
M
Rotman
 
G
Bauer
 
D
Uziel
 
T
Savitsky
 
K
Bar-Shira
 
A
Gilad
 
S
Rosenthal
 
A
Ataxia-telangiectasia locus: Sequence analysis of 184 kb of human genomic DNA containing the entire ATM gene.
Genome Res
7
1997
592
8
Chen
 
G
Lee
 
EY-HP
The product of the ATM gene is a 370-kDa nuclear phospohoprotein.
J Biol Chem
271
1996
33693
9
Lakin
 
ND
Weber
 
P
Stankovic
 
T
Rottinghaus
 
ST
Taylor
 
AMR
Jackson
 
SP
Analysis of the ATM protein in wild-type and ataxia telangiectasia cells.
Oncogene
13
1996
2707
10
Brown
 
KD
Ziv
 
Y
Sadanandan
 
SN
Chessa
 
L
Collins
 
FS
Shiloh
 
Y
Tagle
 
DA
The ataxia telangiectasia gene product, a constitutively expressed nuclear protein that is not up-regulated following genome damage.
Proc Natl Acad Sci USA
94
1997
1840
11
Taylor
 
AMR
Metcalfe
 
JA
Thick
 
J
Mak
 
YF
Leukemia and lymphoma in ataxia telangiactasia.
Blood
87
1996
423
12
Morrell
 
D
Cromartie
 
E
Swift
 
M
Mortality and cancer incidence in 263 patients with ataxia telangiectasia.
J Natl Cancer Inst
77
1986
89
13
Athma
 
P
Rappaport
 
R
Swift
 
M
Molecular genotyping shows that ataxia-telangiactasia heterozygotes are predisposed to breast cancer.
Cancer Genet Cytogenet
92
1996
130
14
Vorechovsky
 
I
Rasio
 
D
Luo
 
L
Monaco
 
C
Hammarström
 
L
Webster
 
ADB
Zaloudik
 
J
Barbanti-Brodano
 
G
James
 
M
Russo
 
G
Croce
 
CM
Negrini
 
M
The ATM gene and susceptibility to breast cancer: Combined mutation analysis of 38 consecutive breast tumors reveals no evidence for somatic mutations and constitutional AT heterozygosity.
Cancer Res
56
1996
2726
15
FitzGerald
 
MG
Bean
 
JM
Hegde
 
SR
Unsal
 
H
MacDonald
 
DJ
Harkin
 
DP
Finkelstein
 
DM
Isselbacher
 
KJ
Haber
 
DA
Heterozygous ATM mutations do not contribute to early onset of breast cancer.
Nat Genet
15
1997
307
16
Bay
 
JO
Grancho
 
M
Pernin
 
D
Presneau
 
N
Rio
 
P
Tchirkov
 
A
Uhrhammer
 
N
Verrelle
 
P
Gatti
 
RA
Bignon
 
YJ
No evidence for constitutional ATM mutation in breast/gastric cancer families.
Int J Oncol
12
1998
1385
17
Chen
 
J
Birkholtz
 
GG
Lindblom
 
P
Rubio
 
C
Lindblom
 
A
The role of ataxia-telangiactasia heterozygotes in familial breast cancer.
Cancer Res
58
1998
1376
18
Stilgenbauer
 
S
Schaffner
 
C
Litterst
 
A
Liebisch
 
P
Gilad
 
S
Bar-Shira
 
A
James
 
MR
Lichter
 
P
Döhner
 
H
Biallelic mutations in the ATM gene in T-prolymphocytic leukemia.
Nat Med
3
1997
1155
19
Vorechovsky
 
I
Luo
 
L
Dyer
 
MJS
Catovsky
 
D
Amlot
 
PL
Yaxley
 
JC
Foroni
 
L
Hammarström
 
L
Webster
 
ADB
Yuille
 
MAR
Clustering of missense mutations in the ataxia-telangiectasia gene in a sporadic T-cell leukemia.
Nat Genet
17
1997
96
20
Stoppa-Lyonnet
 
D
Soulier
 
J
Lauge
 
A
Dastot
 
H
Garand
 
R
Sigaux
 
F
Stern
 
M-H
Inactivation of the ATM gene in T-cell prolymphocytic leukemias.
Blood
91
1998
3920
21
Yuille
 
MAR
Coignet
 
LJA
Abraham
 
SM
Yaqub
 
F
Luo
 
L
Matutes
 
E
Brito-Babapulle
 
Vorechovsky
 
I
Dyer
 
MJS
Catovsky
 
D
ATM is usually rearranged in T-cell prolymphocytic leukemia.
Oncogene
16
1998
789
22
Kerangueven
 
F
Eisinger
 
F
Noguchi
 
T
Allione
 
F
Wargniez
 
V
Eng
 
C
Padberg
 
G
Theillet
 
C
Jacquemier
 
J
Longy
 
M
Sobol
 
H
Birnbaum
 
D
Loss of heterozygosity in human breast carcinomas in the ataxia telangiectasia, Cowden disease and BRCA1 gene regions.
Oncogene
14
1997
339
23
Stilgenbauer
 
S
Liebisch
 
P
James
 
MR
Schröder
 
M
Schlegelberger
 
B
Fischer
 
K
Bentz
 
M
Lichter
 
P
Döhner
 
H
Molecular cytogenetic delineation of a noval critical genomic region in chromosome bands 11q22.3-q23.1 in lymphoproliferative disorders.
Proc Natl Acad Sci USA
93
1996
11837
24
Döhner
 
H
Stilgenbauer
 
S
James
 
MR
Benner
 
A
Weilguni
 
T
Bentz
 
M
Fischer
 
K
Hunstein
 
W
Lichter
 
P
11q deletions identify a new subset of B-cell chronic lymphocytic leukemia characterized by extensive nodal involvement and inferior prognosis.
Blood
89
1997
2516
25
Gilad
 
S
Khosravi
 
R
Shkedy
 
D
Uziel
 
T
Ziv
 
Y
Savitsky
 
K
Rotman
 
G
Smith
 
S
Chessa
 
L
Jorgensen
 
TJ
Harnik
 
R
Frydman
 
M
Sanal
 
O
Portnoi
 
S
Doldwicz
 
Z
Jaspers
 
NGJ
Gatti
 
RA
Lenoir
 
G
Lavin
 
MF
Tatsumi
 
K
Wegner
 
RD
Shiloh
 
Y
Bar-Shira
 
A
Predominance of null mutations in ataxia-telangiactasia.
Hum Mol Genet
5
1996
433
26
Shafman
 
T
Khanna
 
KK
Kedar
 
P
Spring
 
K
Kozlov
 
S
Yen
 
T
Hobson
 
K
Gatei
 
M
Zhang
 
N
Watters
 
D
Egerton
 
M
Shiloh
 
Y
Kharbanda
 
S
Kufe
 
D
Lavin
 
MF
Interaction between ATM protein and c-Abl in response to DNA damage.
Nature
387
1997
520
27
Baskaran
 
R
Wood
 
LD
Whitaker
 
LL
Canman
 
CE
Morgan
 
SE
Xu
 
Y
Barlow
 
C
Baltimore
 
D
Wynshaw-Boris
 
A
Kastan
 
MB
Wang
 
JY
Ataxia telangiactasia mutant protein activates c-Abl tyrosine kinase in response to ionizing radiation.
Nature
387
1997
516
28
Appleby
 
JM
Barber
 
JB
Levine
 
E
Varley
 
JM
Taylor
 
AM
Stankovic
 
T
Heighway
 
J
Warren
 
C
Scott
 
D
Absence of mutations in the ATM gene in breast cancer patients with severe responses to radiotherapy.
Br J Cancer
76
1997
1546
29
Banin
 
S
Moyal
 
L
Shieh
 
S-Y
Taya
 
Y
Anderson
 
CW
Chessa
 
L
Smorodinsky
 
NI
Prives
 
C
Reiss
 
Y
Shiloh
 
Y
Ziv
 
Y
Enhanced phosphorylation of p53 by ATM in response to DNA damage.
Science
281
1998
1674
30
Canman
 
CE
Lim
 
D-S
Cimprich
 
KA
Taya
 
Y
Tamai
 
K
Sakaguchi
 
K
Appella
 
E
Kastan
 
MB
Siliciano
 
JD
Activation of the ATM kinase by ionizing radiation and phosphorylation of p53.
Science
281
1998
1677
31
Gilad
 
S
Chessa
 
L
Khosravi
 
R
Russell
 
P
Galanty
 
Y
Piane
 
M
Gatti
 
RA
Jorgensen
 
TJ
Shiloh
 
Y
Bar-Shira
 
A
Genotype-phenotype relationships in ataxia-telangiectasia and variants.
Am J Hum Genet
62
1998
551
32
Stankovic
 
T
Kidd
 
AM
Sutcliff
 
A
McGuire
 
GM
Robinson
 
P
Weber
 
P
Bedenham
 
T
Bradwell
 
AR
Easton
 
DF
Lennox
 
GG
Haites
 
N
Byrd
 
PJ
Taylor
 
AM
ATM mutations and phenotypes in ataxia-telangiactasia families in the British Isles: Expression of mutant ATM and the risk of leukemia, lymphoma, and breast cancer.
Am J Hum Genet
62
1998
334
33
Toyoshima
 
M
Hara
 
T
Zhang
 
H
Yamamoto
 
T
Akaboshi
 
S
Nanba
 
E
Ohno
 
K
Hori
 
N
Sato
 
K
Takeshita
 
K
Ataxia-telangiectasia without immunodeficiency: Novel point mutations within and adjacent to the phosphatidylinositol 3-kinase-like domain.
Am J Med Genet
75
1998
141
34
Wright
 
J
Teraoka
 
S
Onengut
 
S
Tolun
 
A
Gatti
 
RA
Ochs
 
HD
Concannon
 
P
A high frequency of distinkt ATM gene mutations in ataxia-telangiactasia.
Am J Hum Genet
59
1996
839
35
Xu
 
Y
Baltimore
 
D
Dual roles of ATM in the cellular response to radiation and in cell groth control.
Genes Dev
10
1996
2401
36
Barlow
 
C
Hirotsune
 
S
Paylor
 
R
Liyanage
 
M
Eckhaus
 
M
Collins
 
F
Shiloh
 
Y
Crawley
 
JN
Ried
 
T
Tagle
 
D
Wynshaw-Boris
 
A
Atm-deficient mice: A paradigm of ataxia telangiectasia.
Cell
86
1996
159
37
Elson
 
A
Wang
 
Y
Daugherty
 
CJ
Morton
 
CC
Zhou
 
F
Campos-Torres
 
J
Leder
 
P
Pleiotropic defects in ataxia-telangiectasia protein-deficient mice.
Proc Natl Acad Sci USA
93
1996
13084
38
Xu
 
Y
Ashley
 
T
Brainerd
 
EE
Bronson
 
RT
Meyn
 
MS
Baltimore
 
D
Targeted disruption of ATM leads to growth retardation, chromosomal fragmentation during meiosis, immune defects, and thymic lymphoma.
Genes Dev
10
1996
2411
39
Starostik
 
P
Manshouri
 
T
O’Brien
 
S
Freireich
 
E
Kantarjian
 
H
Haidar
 
M
Lerner
 
S
Keating
 
M
Albitar
 
M
Deficiency of the ATM protein expression defines an aggressive subgroup of B-cell chronic lymphocytic leukemia.
Cancer Res
58
1998
4552
40
Stankovic
 
T
Weber
 
P
Stewart
 
G
Bedenham
 
T
Murray
 
J
Byrd
 
PJ
Moss
 
PAH
Taylor
 
AMR
Inactivation of ataxia telangiectasia mutated gene in B-cell chronic lymphocytic leukaemia.
Lancet
353
1999
26
41
Bullrich
 
F
Rasio
 
D
Kitada
 
S
Starostik
 
P
Kipps
 
T
Keating
 
M
Albitar
 
M
Reed
 
JC
Croce
 
CM
ATM mutations in B-cell chronic lymphocytic leukemia.
Cancer Res
59
1999
24
42
Swift
 
M
Morrell
 
D
Massey
 
RB
Chase
 
CL
Incidence of cancer in 161 families affected by ataxia-telangiectasia.
N Engl J Med
325
1991
1831
43
Easton
 
D
Cancer risks in A-T heterozygots.
Int J Radiat Biol
66
1994
5177
44
Lim
 
DS
Kirsch
 
DG
Canman
 
CE
Ahn
 
JH
Ziv
 
Y
Newman
 
LS
Darnell
 
RB
Shiloh
 
Y
Kastan
 
MB
ATM binds to β-adaptin in cytoplasmic vesicles.
Proc Natl Acad Sci USA
95
1998
10146
45
Liu
 
Q
Sommer
 
SS
Restriction endonuclease fingerprinting (REF): A sensitive method for screening mutations in long, contiguous segments of DNA.
Biotechniques
18
1995
470
46
Beaudet
 
AL
Tsui
 
L-C
A suggested nomenclature for designating mutations.
Hum Mutat
2
1993
245

Author notes

Address reprint requests to Peter Lichter, PhD, Abteilung “Organisation komplexer Genome” (H0700), Deutsches Krebsforschungszentrum, Im Neuenheimer Feld 280, D-69120 Heidelberg, Germany; e-mail: p.lichter@dkfz-heidelberg.de.

Sign in via your Institution