Characterization of N-myc amplification in a human neuroblastoma cell line by clones isolated following the phenol emulsion reassociation technique and by hexagonal field gel electrophoresis

The N-myc amplification of human neuroblastomas was characterized by the amplified DNA cloned from the cell line MC-NB-1 using the phenol emulsion reassociation technique (PERT). A number of PERT clones exhibiting amplification in this cell line were tested for amplification in other neuroblastoma cell lines. In almost all cell lines examined, only a few clones were co-amplified with N-myc and most of the others were exclusively amplified in a subset of the cell lines. The total aggregate size of theHind III fragment identified by the PERT clones was approximately 350 kb. Most of the PERT clones were mapped to human chromosome (chr) 2p23-2pter, where the N-myc gene is located. Four types of amplicons, the 100, 420, 480 and 520 kb fragments, shown to beNot I fragments, were identified by hexagonal field gel electrophoresis. Three fragments are ordered in a head-to-tail array, and the remaining fragment is either ordered in a tail-to-head array or something else. Despite the extremely unusual construction of the amplified sequences in this cell line as compared with others, there was a low degree of sequence heterogeneity among the amplicons within this cell line. These observations lead to the idea that the complex rearrangements that give rise to the heterogeneous organization of the amplified sequences among the different cell lines precede the amplification of these sequences.     

The growth-inhibitory Ndrg1 gene is a Myc negative target in human neuroblastomas and other cell types with overexpressed N- or c-myc

A major prognostic marker for neuroblastoma (Nb) is N-myc gene amplification, which predicts a poor clinical outcome. We sought genes differentially expressed on a consistent basis between multiple human Nb cell lines bearing normal versus amplified N-myc, in hopes of finding target genes that might clarify how N-myc overexpression translates into poor clinical prognosis. Using differential display, we find the previously described growth-inhibitory gene Ndrg1 is strongly repressed in all tested Nb cell lines bearing N-myc amplification, as well as in a neuroepithelioma line with amplified c-myc. Overexpression of N-myc in non-amplified Nb cells leads to repression of Ndrg1, as does activation of an inducible c-myc transgene in fibroblasts. Conversely, N-myc downregulation in N-myc-amplified Nb cells results in re-expression of the Ndrg1, and stimuli known to induce Ndrg1 do so in Nb cells while simultaneously down-regulating N-myc. Relevant to these results, we demonstrate an in vitro interaction of Myc protein with the Ndrg1 core promoter. We also find that Ndrg1 levels increase dramatically during in vitro differentiation of two cell lines modeling neural and glial development, while c- and N-myc levels decline. Our results combined with previous information on the Ndrg1 gene product suggest that downregulation of this gene is an important component of N-Myc effects in neuroblastomas with poor clinical outcome. In support of this notion, we find that re-expression of Ndrg1 in high-Myc Nb cells results in smaller cells with reduced colony size in soft-agar assays, further underscoring the functional significance of this gene in human neuroblastoma cells.     

Detection of amplified genomic sequences in human small-cell lung carcinoma cells by arbitrarily primed-PCR genomic fingerprinting

The arbitrarily primed-PCR (AP-PCR) genomic fingerprinting method was applied to evaluate its effectiveness in detecting and characterizing amplified DNA fragments in two small-cell lung carcinoma (SCLC) cell lines, NCI-H69 and NCI-H82. Of the 2428 DNA fragments detected by AP-PCR using 62 arbitrary primers, 2 (0.08%) DNA fragments were amplified in NCI-H69 and 6 (0.25%) DNA fragments were amplified in NCI-H82. Based on these results, we estimate the total size of the amplified genomic regions in these cell lines to be 3000 megabase pairs (Mb) × 0.0008 = 2.4 Mb in NCI-H69 and 3000 Mb × 0.0025 = 7.5 Mb in NCI-H82. The 2 amplified fragments in NCI-H69 were mapped to chromosome 2, and all 6 amplified fragments in NCI-H82 were mapped to chromosome 8. This strongly suggests that restricted chromosomal regions are specifically amplified in these SCLC cell lines. Since the N-myc gene at 2p24 is amplified in NCI-H69 and the c-myc gene at 8q24 is amplified in NCI-H82, it is possible that these DNA fragments are co-amplified with N-myc or c-myc in these cell lines. However, since the 2 amplified fragments in NCI-H69 were not amplified in 42 other human cancer cell lines including 11 cell lines carrying amplified N-myc genes, it is also possible that there are amplified regions on chromosome 2 other than the N-myc locus at 2p24 in NCI-H69. In contrast, all 6 amplified fragments in NCI-H82 were amplified in several other human cancer cell lines carrying amplified c-myc genes. This result further indicates that these fragments were derived from an amplification unit that includes the c-myc gene. Our results show the ability of the AP-PCR method to analyze the fraction of the genome with amplification in human cancer cells. Received: 10 April 1995 / Revised: 18 December 1995, 15 April 1996     

17p13 (p53 locus), 5q21 (APC locus) and 9p21 (p16 locus) allelic deletions are frequently found in oral exfoliative cytology cells from smoker patients with non-small-cell lung cancer

Molecular cytogenetic and LOH analyses of non-small cell lung cancer (NSCLC) have shown frequent allelic deletions in a variety of chromosomes where tumour suppressor genes are located. Allelic loss at 9p21 (p16 locus), 17p13 (p53) and 5q21(APC) has been frequently described in NSCLC and has also been described in premalignant epithelial lesions of the bronchus and normal bronchial cells. These findings suggest that a tissue field of somatic genetic alterations precedes the histopathological phenotypic changes of carcinoma. Similar changes have been described in oral and laryngeal epithelial tumours associated with smoke exposure. We previously reported frequent LOH at 5q21, 9p21 and TP53 in tumor cells and peritumoral normal bronchial cells from surgically resected NSCLC. We now analyze 96 cases of normal oral exfoliative cytology in which normal epithelial cells were obtained: 43 cases from smoker patients with NSCLC diagnosis, 33 smoker patients with no evidence of malignancy and 20 non-smoker patients with no evidence of tumour. All groups had a similar age and sex distribution. PCR amplification was performed utilising the specific markers D5S346, D9S157 and TP53. In normal oral mucosae cells from patients with NSCLC, we found that 21% of the informative cases showed LOH at any of the three analyzed loci distributed as follows: 14.3% of the informative cases showed LOH at 5q21, 7.7% at 9p21 and 22.2% at TP53. Within the smoker risk group only one case (4% of the informative cases) showed LOH at TP53, while no LOH was found at 5q21 or 9p21. No LOH was found in non-smokers. In conclusion, our results show that a significant number of patients with NSCLC have LOH at TP53, 5q21 and 9p21 in normal oral mucosae, while LOH at these loci is unusual in similar cells obtained from patients with no evidence of malignancy. Our study demonstrates that LOH studies can detect smoker patients with a mutated genotype in normal epithelial cells. Further prospective studies may confirm whether LOH studies can detect patients with a higher risk of NSCLC.     

LOH Detected by Microsatellite Markers Reveals the Clonal Origin of Recurrent Laryngeal Squamous Cell Carcinoma

Background

The question of whether “recurrent” laryngeal carcinoma is truly a new tumour with a clonal origin that differs from that of the primary tumour has remained unanswered. The objective of this study was to determine whether recurrent tumours have the same genetic basis as primary tumours, as the answer to this question is important for the development of treatment strategies.

Materials and Methods

Matched samples consisting of primary tumour, recurrent tumour and normal tissue were obtained from the same patient. A total of 37 patients with laryngeal cancer were examined for loss of heterozygosity (LOH) on the 3p, 5p, 7q, 8p, 9p, 13p, 17p and 18q chromosomal arms using PCR to amplify microsatellite markers. All patients were routinely followed up and 5-year survival rates were calculated using directly calculating method and Kaplan-Meier''s method.

Results

A total of 28 out of 37 (75.6%) patients showed LOH at a minimum of one locus, and 19 out of 37 (51.3%) patients showed LOH at two loci. Primary and recurrent tumours in each patient showed identical allelic loss patterns and incidence rates. Patients without LOH had a longer average time to recurrence than patients with LOH (P<0.05). Additionally, patients with LOH had a longer average smoking duration prior to surgery than patients without LOH (P<0.05). The 5-year survival rates were 32.14%in patients with LOH versus 44.4% in patients without LOH.

Conclusions

The data indicate that primary and recurrent tumours have the same clonal origin. This result implies that we failed to radically resect the primary tumours and/or micrometastases in these patients. Consequently, some form of adjunctive therapy may be necessary. Additionally, the data indicate that the recurrence of laryngeal squamous cell carcinoma is closely related to chromosomal aberrations (specifically LOH).     

Selection of cells with different chromosomal localizations of the amplified c-myc gene during in vivo and in vitro growth of the breast carcinoma cell line SW 613-S

The c-myc gene is amplified in the human breast carcinoma cell line SW 613-S. At early in vitro passages, the extra copies of the gene were mainly localized in double minute chromosomes (DMs), as shown by in situ hybridization with a biotinylated c-myc probe. However, cells without DMs were also present in which the c-myc genes were found integrated into any of several distinct chromosomes (mainly 7q+, 4 and 4q+, and 1). When this cell line was propagated in vitro, the level of c-myc amplification decreased because cells with DMs and a high amplification level were lost and replaced by cells without DMs and having a low amplification level. On the contrary, when early passage SW 613-S cells were grown in vivo, as subcutaneous tumours in nude mice, cells with numerous DMs and a high level of c-myc amplification were selected for. In one cell line (SW 613-Tu1) established from such a tumour, the DM-containing cells were substituted at late passages for cells with a high number of c-myc copies integrated within an abnormally banded region, at band 17q24 of a 17q+ chromosome. When only cells with integrated genes were present, this cell line was still highly tumorigenic indicating that the localization of the c-myc genes in DMs was not required for these cells to be tumorigenic in nude mice. Furthermore, cells of the secondary tumours induced by SW 613-Tu1 did not contain any DMs showing that in vivo growth did not promote the release of integrated c-myc copies into DMs.     

Molecular genetic investigations of the mechanism of tumourigenesis in von Hippel-Lindau disease: analysis of allele loss in VHL tumours

Von Hippel-Lindau (VHL) disease is a dominantly inherited familial cancer syndrome characterised by the development of retinal and central nervous system haemangioblastomas, renal cell carcinoma (RCC), phaeochromocytoma and pancreatic tumours. The VHL disease gene maps to chromosome 3p25-p26. To investigate the mechanism of tumourigenesis in VHL disease, we analysed 24 paired blood/tumour DNA samples from 20 VHL patients for allele loss on chromosome 3p and in the region of tumour suppressor genes on chromosomes 5, 11, 13, 17 and 22. Nine out of 24 tumours showed loss of heterozygosity (LOH) at at least one locus on chromosome 3p and in each case the LOH included the region to which the VHL gene has been mapped. Chromosome 3p allele loss was found in four tumour types (RCC, haemangioblastoma, phaeochromocytoma and pancreatic tumour) suggesting a common mechanism of tumourigenesis in all types of tumour in VHL disease. The smallest region of overlap was between D3S1038 and D3S18, a region that corresponds to the target region for the VHL gene from genetic linkage studies. The parental origin of the chromosome 3p25-p26 allele loss could be determined in seven tumours from seven familial cases; in each tumour, the allele lost had been inherited from the unaffected parent. Our results suggest that the VHL disease gene functions as a recessive tumour suppressor gene and that inactivation of both alleles of the VHL gene is the critical event in the pathogenesis of VHL neoplasms. Four VHL tumours showed LOH on other chromosomes (5q21, 13q, 17q) indicating that homozygous VHL gene mutations may be required but may not be sufficient for tumourigenesis in VHL disease.     

Loss of heterozygosity on chromosome 11p13 in primary bladder carcinoma

Although the occurrence of bladder cancer is common, the molecular events underlying the pathogenesis of this cancer remain ill-defined. A loss of heterozygosity (LOH) at specific chromosomal loci may predispose individuals to the development of bladder cancer but this has not been examined in detail. Furthermore, the role that deletion or inactivation of putative tumour suppressor genes might play in the genesis of bladder cancer has not been established. In this study, allelic deletion analysis on the short arm of chromosome 17 of patients with primary bladder tumours failed to show deletion at 17p13 (0/7), a region known to contain the p53 tumour suppressor gene. Chromosome 11p15 showed allelic deletion at the IGF2 locus (2/7: 29%) and the PTH locus (1/11: 9%). However, no deletion was observed at the CALCA locus (0/6). LOH at 11p13, a region containing the Wilm's tumour suppressor gene (WT1), was also studied. Analysis of LOH at 11p13 showed deletion at the CAT locus (13/18: 72%), the J/D11S414 locus (5/15: 33%), the WT1 locus (7/14: 50%) and the FSHB locus (6/16: 38%). The significance of these findings is discussed.     

The amplification of oligonucleotide themes in the evolution of themyc protooncogene family

The evolutionary past of intragenic repeats in protein-coding exons of c-, N-, L-, and s-myc-protooncogene subfamilies was elucidated. Apparently these genes evolved by succession of distinct unit events rather than by a steady flow of random point mutations. An evolutionary event probably involved a duplication of the whole gene, which was followed by amplification of progressively shorter oligonucleotide themes and motifs. The repeats were either joined in tandem or one of the copies was transposed and integrated elsewhere within the same exon. In some instances multiple fragments of an amplified theme were integrated at several sites. Direct repeats were found to prevail over inverted ones. By reconstructing the fate of repeats in the course of evolution of vertebrates, the origins of some functional domains could be traced to the initial amplification event. For example, an N-myc-specific domain was created by tandem duplication of a single-copy theme of L-myc exon; at the time of divergence of the c-myc and N-myc, the tandem duplex underwent a new round of duplication followed by transposition of the new copy, thus accounting for the formation of a new domain specific for c-myc. The model proposed here may be regarded as a molecular-level equivalent of the theory of punctuated equilibria. This is the author's last paper; it was submitted shortly before his death. The proofs were corrected by Michal Dvorak Correspondence to: M. Dvorak     

A pilot study of recurrence of human glial tumours in light of p53 heterozygosity status

Genetic alterations in the p53 tumour suppressor gene of human chromosome 17 have been frequently found to be associated with various tumours. Glial tumours arise from the supporting cells of the brain. They have a poor outcome and often recur. The present study was undertaken to compare the loss of heterozygosity (LOH) of p53 gene in pairs of primary and recurrent gliomas and to try and correlate it to the degree of malignancy and recurrence interval. LOH of p53 was taken as an indicator of the inactivation of p53 due to genetic changes. Ten patients with recurrent gliomas were studied. Three patients had LOH at primary surgery and two of these had LOH at recurrent surgery. One patient had LOH of p53 only at recurrent surgery but not at primary surgery. No indicative correlation was found between p53 heterozygosity status on one hand and grade of malignancy (primary and recurrent) and recurrence interval on the other.     

N-Myc Regulates Expression of Pluripotency Genes in Neuroblastoma Including lif,klf2, klf4, and lin28b

myc genes are best known for causing tumors when overexpressed, but recent studies suggest endogenous myc regulates pluripotency and self-renewal of stem cells. For example, N-myc is associated with a number of tumors including neuroblastoma, but also plays a central role in the function of normal neural stem and precursor cells (NSC). Both c- and N-myc also enhance the production of induced pluripotent stem cells (iPSC) and are linked to neural tumor stem cells. The mechanisms by which myc regulates normal and neoplastic stem-related functions remain largely open questions. Here from a global, unbiased search for N-Myc bound genes using ChIP-chip assays in neuroblastoma, we found lif as a putative N-Myc bound gene with a number of strong N-Myc binding peaks in the promoter region enriched for E-boxes. Amongst putative N-Myc target genes in expression microarray studies in neuroblastoma we also found lif and three additional important embryonic stem cell (ESC)-related factors that are linked to production of iPSC: klf2, klf4, and lin28b. To examine the regulation of these genes by N-Myc, we measured their expression using neuroblastoma cells that contain a Tet-regulatable N-myc transgene (TET21N) as well as NSC with a nestin-cre driven N-myc knockout. N-myc levels closely correlated with the expression of all of these genes in neuroblastoma and all but lif in NSC. Direct ChIP assays also indicate that N-Myc directly binds the lif promoter. N-Myc regulates trimethylation of lysine 4 of histone H3 in the promoter of lif and possibly in the promoters of several other stem-related genes. Together these findings indicate that N-Myc regulates overlapping stem-related gene expression programs in neuroblastoma and NSC, supporting a novel model by which amplification of the N-myc gene may drive formation of neuroblastoma. They also suggest mechanisms by which Myc proteins more generally contribute to maintenance of pluripotency and self-renewal of ESC as well as to iPSC formation.     

Applied Sciences: Absence of CD44-standard in human neuroblastoma correlates with histological dedifferentiation, N-myc amplification and reduced survival probability

Expression of CD44 was examined by immunohistochemistry in 205 primary neuroblastomas together with histological grading according to the Shimada classification at the time of diagnosis. In addition, Southern blot analysis to determine N-myc gene amplification was carried out in the same tissue. When compared with clinical data such as stage, age and event-free survival probability it was found that CD44 expression characterizes well differentiated tumours and thus correlates with prognosis (event-free survival probability in CD44 positive patients 0.6 (n = 129) vs. 0.0 (n = 21) in CD44 negative patients). In tumours with N-myc = 1, CD44 positivity was found in 91% of patients as compared to 57% of patients with N-myc > 1 in tumours. All tumours of 13 patients with metastatic stage 4s (with good prognosis) showed CD44s expression. Thus, detection of CD44s expression might serve as a prognostic indicator which can be rapidly detected at diagnosis.     

Analysis of p16 expression and allelic imbalance / loss of heterozygosity of 9p21 in cutaneous squamous cell carcinomas

Deletions of the short arm of chromosome 9 have been reported in different types of malignancies. This chromosomal region contains a number of known tumour suppressor genes, including the p16INK4A (CDKN2A), p15INK4B and MTAP tumour suppressor genes located at 9p21. In this study twenty-two paraffin embedded invasive cutaneous SCC were examined for allelic imbalance/ loss of heterozygosity (AI/LOH) of the 9p region (in particular 9p21), and for p16 protein expression. DNA was isolated from microdissected sections of normal and tumour cells and analysed for AI/LOH by using six fluorescently labelled microsatellite markers that map to the 9p region. P16 protein expression was examined by immunohistochemistry. At each of the six microsatellite markers the majority of SCC analysed showed AI/LOH. Overall both AI/LOH within the CDKN2A locus and absence of p16 protein expression were frequent among the cutaneous SCC analysed, suggesting that p16 inactivation may play a role in cutaneous SCC development. The majority of the SCC analysed also had AI/LOH of the marker within the MTAP gene, and at markers flanking the CDKN2A gene; thus further investigation as to a possible role for these genes in the development of cutaneous SCC is warranted.     

Detecting and investigating the significance of high-frequency LOH chromosome regions for endometriosis-related candidate genes

To detect the high-frequency loss of heterozygosity (LOH) chromosome regions for ectopic endometrium of ovarian endometriosis (EMs) and to investigate the significance of high-frequency LOH chromosome regions in EMs, we obtained ectopic endometrium by laser capture microdissection (LCM (22 samples)), manual capture microdissection (MCM (18 samples)), and routine dissection (14 samples), respectively. After restriction and circularization-aided rolling circle amplification (RCA-RCA), LOH was detected at 12 microsatellite (MS) loci. The frequency of LOH was 59.09% (13/22) in LCM group, 61.11% (11/18) in the MCM group and 21.43% (3/14) in the routine dissection group. The latter was significantly lower when compared with the former two (p < 0.05). In the LCM group, candidate chromosome regions 17q21.31 and 9p21.3 had LOH frequencies of 23.8 and 13.6%, respectively. The highest LOH frequency was detected at the locus AAAT2 on chromosome 17q21.31 (40%). The chromosome region with the highest frequency of LOH for ectopic endometrium was 17q21.31, especially at the AAAT2 locus, which prompted that down regulation of the candidate genes nearby the locus might be one of the mechanisms of EMs pathogenesis. LCM combined with RCA-RCA is a reliable technique for analyzing endometrial LOH at multiple MS loci. MCM combined with RCA-RCA, which provided similar results, was more cost-effective.     

Allelic loss at the neurofibromatosis type 1 (NF1) gene locus is frequent in desmoplastic neurotropic melanoma

Mutations of the tumour-suppressor gene NF1 (neurofibromatosis 1) have been observed in neurofibromas and neurofibrosarcomas of patients with von Recklinghausen's disease and in sporadic nerve sheath tumours. In contrast, melanoma, another tumour type of neuroectodermal origin, rarely shows NF1 alterations. Desmoplastic neurotropic melanoma (DNM) is an uncommon melanoma subtype that shares morphological characteristics with nerve sheath tumours. Therefore, we analysed 15 DNM and 20 melanomas without morphological features of desmoplasia or neuroid differentiation (common melanomas) for loss of heterozygosity (LOH) at the NF1 locus and flanking regions. Allelic loss was detected in 10/15 (67%) DNM but only in 1/20 (5%) common melanomas. LOH was most frequently observed at marker IVS38, located in intron 38 of NF1. These data suggest a role for NF1 in the pathogenesis of DNM and support an earlier hypothesis that exon 37 might encode a functional domain. DNM may represent an interesting tumour model tor the further elucidation of the cellular functions and tumour-suppressive potential of neurofibromin.     

Influence of myc overexpression on the phenotypic properties of Chinese hamster lung cells resistant to antitumor agents

In the Chinese hamster lung fibroblast cell line DC-3F, the development of resistance to different drugs, through several mechanisms like MDR expression or alteration of the DNA topoisomerase II activity, has been shown to be associated with a decreased tumorigenicity. Multiple studies have shown that the myc oncogene, in cooperation with ras, plays a major role in the oncogenic transformation of fibroblasts. As an approach to a better understanding of the relationship between the different phenotypic traits, we analyzed the expression of myc and ras oncogenes in the drug-sensitive DC-3F cells and in variants resistant to 9-hydroxy-ellipticine (9-OH-E) (DNA topoisomerase II alteration) or to actinomycin D (AD) (multidrug (MDR) expression). Southern and Northern blot analyses revealed about a 10-fold amplification and a 20-fold overexpression of the c-myc gene in the DC-3F cells as compared to the normal lung fibroblasts. Both amplification and overexpression are markedly decreased in the two resistant variants. ras gene copy number and expression were found to be identical in all cell types. In order to analyze the contribution of the decreased myc expression on the different phenotypic traits, the DC-3F/9-OH-E cells were transfected with the plasmid pSV-c-myc, and six clones expressing high amounts of the transfected myc were isolated and characterized. Morphological and caryological alterations, as well as an increased cloning efficiency in soft agar, indicated that the myc gene product was made in these cells. However, the tumorigenicity of the sensitive parental cells was not restored, thus showing that the decreased myc expression alone does not account for the loss of tumorigenicity in the resistant cells. 9-OH-E resistance was not modified in the transfected cells, while the cross-resistance of these cells to MDR-sensitive drugs, such as vincristine, actinomycin D, and taxol, was reversed roughly in proportion of the expression of the transfected myc.     

Detection of N-myc amplification in neuroblastomas using Southern blotting on fine needle aspirates

OBJECTIVE: To verify the possibility of detecting N-myc amplification in fine needle aspiration (FNA) cytology from neuroblastomas by the Southern blotting technique. STUDY DESIGN: Fifteen neuroblastomas diagnosed by FNA in the Department of Pathology, Hospital de S. Jo?o, between 1990 and 1998, were studied for N-myc amplification using the Southern blotting technique in cytologic and histologic material. RESULTS: DNA extraction from the cytologic material was performed in all cases (N = 15). In two cases the quality/quantity of the DNA did not allow the study of N-myc status by the Southern blotting technique. We detected N-myc amplification in 1 of 13 patients (7.6%) from whom material was available for genetic study. CONCLUSION: It is possible to use the Southern blotting technique to demonstrate N-myc amplification in material obtained from FNA of neuroblastomas.     

Adenomatous polyposis coli truncation mutations in 2-amino-1-methyl-6-phenylimidazo[4,5-b]pyridine (PhIP)-induced intestinal tumours of multiple intestinal neoplasia mice

The heterocyclic amine 2-amino-1-methyl-6-phenylimidazo[4,5-b]pyridine (PhIP) induces intestinal tumours in C57BL/6J-multiple intestinal neoplasia (Min)/+ mice. The main mechanism for PhIP-induced tumour induction in Min/+ mice is loss of the wild-type adenomatous polyposis coli (Apc) allele, i.e. loss of heterozygosity (LOH). In this study, single injections of either 10, 17.5 or 25 mg/kg PhIP on days 3-6 after birth all increased the mean number of small intestinal tumours two to three-fold, from 37.7 in controls to 124.8 in the PhIP-treated Min/+ mice. In total, we analysed 292 small intestinal tumours and 253 of these had LOH. The frequency of LOH in the Apc gene was 88, 93, 83 and 84% in tumours of 0, 10, 17.5 and 25 mg/kg PhIP-treated mice, respectively. Therefore, these lower doses of PhIP did not reduce the frequency of LOH, as found in our previous study with a single injection of 50 mg/kg PhIP (Mutat. Res. 1-2 (2002) 157). In the second part of this study, we wanted to characterise Apc truncation mutations from tumour samples apparently retaining the Apc wild-type allele from this and two previous experiments with PhIP-exposed Min/+ mice. In the first half of exon 15 in Apc, we verified 25 mutations from 804 tumour samples of PhIP-treated mice. Of these were 60% G-->T transversions, and 16% G deletions, indicating that these are the predominant types of PhIP-induced truncation mutations in the Apc gene in Min/+ mice. Most of the mutations were located between codon 989 and 1156 corresponding to the first part of the beta-catenin binding region. We also identified two Apc truncation mutations from 606 spontaneously formed intestinal tumours from untreated Min/+ mice, one C-->T transition and one T insertion, which were different from those induced by PhIP.     

Intervention of somatic mutational events in vivo by a germline defect at the adenine phosphoribosyltransferase locus

Both germline and somatic mutations are known to affect phenotypes of human cells in vivo. In previous studies, we cloned mutant peripheral blood T cells from germline heterozygous humans for adenine phosphoribosyltransferase (APRT) (EC 2.4.2.7) deficiency and found that approximately 1.3 × 10^–4 peripheral T cells had undergone in vivo somatic mutations. Loss of heterozygosity (LOH) was the major cause of the mutations at the APRT locus since approximately 80% of the mutant T cell clones exhibited loss of normal alleles. In the present study, we identified three heterozygous individuals for APRT deficiency (representing two separate families), in whom none of the somatic mutant cells exhibited LOH at the APRT locus. The germline mutant APRT alleles of these heterozygotes from two unrelated families had the same gross DNA abnormalities detectable by Southern blotting. None of the germline mutant APRT alleles so far reported had such gross DNA abnormalities. The data suggest that the germline mutation unique to these heterozygous individuals is associated with the abrogation of LOH in somatic cells. The absence of LOH at a different locus has already been reported in vitro in an established cell line but the present study describes the first such event in vivo in human individuals. Received: 10 May 1996