Hypermutability in Carcinogenesis

Hypermutability in Carcinogenesis

Bernard S. Strauss^a
^a Department of Molecular Genetics and Cell Biology, The University of Chicago, Chicago, Illinois 60637

Corresponding author: Bernard S. Strauss, Department of Molecular Genetics and Cell Biology, The University of Chicago, 920 E. 58th St., Chicago, IL 60637, bs19{at}midway.uchicago.edu (E-mail).

ABSTRACT

TOP
ABSTRACT
Are tumors hypermutable?
TP53 mutation
Silent mutation
Multiple TP53 mutations
Mutations in other genes
Other examples of...
LITERATURE CITED

The presence of numerous chromosomal changes and point mutationsin tumors is well established. At least some of these changesplay a role in the development of the tumors. It has been suggestedthat the number of these genetic changes requires that tumorigenesisinvolves an increase in mutation rate. However, the presenceof numerous changes can also be accounted for by efficient selection.What is required to settle the issue is some measure of nonselectedmutations in tumors. In order to determine whether the tumorsuppressor TP53 (coding for the protein p53) is hypermutableat some stage of carcinogenesis, the frequency of silent andmultiple mutations in this gene has been examined. Silent mutationsmake up ~3% of the total recorded but constitute 9.5% of themutations found in tumors with multiple mutations. Multipleclosely linked mutations are also observed. Such multiple mutationssuggest the operation of an error-prone replication processin a subclass of cells. The published data indicate that TP53is hypermutable at some stage of tumor development. It is notyet clear whether TP53 is unique or whether other genes displaya similar pattern of silent and multiple mutations.

Are tumors hypermutable?

TOP
ABSTRACT
Are tumors hypermutable?
TP53 mutation
Silent mutation
Multiple TP53 mutations
Mutations in other genes
Other examples of...
LITERATURE CITED

Tumors accumulate genetic alterations as they progress, andit seems very likely that at least a portion of these geneticalterations play a role in the etiology of the disease (VOGELSTEINet al. 1988 ; GOYETTE et al. 1992 ). This accumulation of changesis so striking that many investigators suppose that a conditionof genetic instability is a necessary concomitant of tumorigenesis(LOEB et al. 1974 ; LOEB 1991 ; CHENG and LOEB 1993 ). Thegenetic changes observed are of different kinds and includeboth point mutations and qualitative and quantitative chromosomealterations. Chromosome instability might occur without affectingthe fidelity of the replication process, that is, without changingthe rate of gene mutation. The question to be addressed hereis whether a general increase in the point mutation rate occursat some stage in carcinogenesis.

It has been argued that the normal mutation rate is insufficientto generate the changes required in a single cell and that theremust, therefore, be a special process at work in cells destinedto engender tumors (LOEB 1991 ). Some years ago it would havebeen supposed that exogenous environmental agents acting asmutagens were in large part responsible for this increase (AMES1973), but such arguments are no longer as compelling (AMESet al. 1995 ). Many of the changes observed in tumors are associatedwith G:C $->$ A:T transitions characteristic of spontaneous changerather than the G:C $->$ T:A transversions characteristic of chemicalmutagenesis (HOLLSTEIN et al. 1991 ). Current hypotheses suggestthat the developing tumor cells carry "mutator" genes that diminishnormal cellular surveillance mechanisms and increase the spontaneousmutation rate (LOEB 1994 ). Such surveillance mechanisms doexist (MODRICH 1995 ), and certain types of tumors occur morefrequently in individuals with defects in genes responsiblefor the coding of the necessary surveillance proteins. The mostspectacular recent finding is the association of certain coloncarcinomas with defects in the mismatch repair genes (FISHELet al. 1993 ; MODRICH 1995 ), but the earlier association ofa defect in excision repair with skin carcinomas is equallystriking (CLEAVER 1968 ). These correlations are persuasivearguments for the tumor hypermutability hypothesis.

The mutation frequency for point mutations is very significantlyincreased in the cells of individuals deficient in mismatchrepair (BHATTACHARYYA et al. 1995 ; MALKHOSYAN et al. 1996). However, PARSONS et al. 1995 found a subset of patientswhose somatic cells were devoid of mismatch repair activityand were hypermutable, but such individuals did not have thenumber of early tumors that might be expected. In addition,the tumors that do occur in patients with hereditary nonpoyposiscolorectal cancer represent a limited set, that is, certainkinds of tumors occur but not others. It may be that the importanceof mismatch repair deficiency is not primarily its effect onthe generalized mutation rate but rather on the mutation rateof genes containing repeated nucleotide sequences within thecoding region of critical genes, for example, the observed frameshiftin a run of 10 (A's) in the TGF-ßII receptor gene (LUet al. 1995 ; MARKOWITZ et al. 1995 ; AKIYAMA et al. 1996; RAMPINO et al. 1997 ; SOUZA et al. 1996 ). Protection againstsingle base changes that occur at the growing point during DNAsynthesis is provided by both the mismatch repair and proofreadingsystems (FRIEDBERG et al. 1995 ). Frameshifts in long-repeatedsequences are to some extent ignored by the proofreading systembut are efficiently recognized by the mismatch repair system(STRAUSS et al. 1997 ; TRAN et al. 1997 ). Mismatch repairdeficiency may therefore affect genes with such sequences toa disproportionate extent. If this explanation is correct, mismatchrepair deficiency makes certain critical changes more likely,but the general increase in mutation need not result in generalizedtumorigenesis. Demonstration that hypermutability is a generalproperty of cells undergoing neoplastic transformation requiresadditional kinds of evidence.

The example of xeroderma pigmentosum has long been used as anargument for the role of DNA repair in removing tumorigeniclesions (CLEAVER 1968 ) and, indirectly, for generalized mutagenesisas a causative factor in cancer induction. One of the signsof xeroderma pigmentosum is an increased frequency of sunlight-inducedskin carcinoma. Such tumors are associated with dinucleotide"signature" mutations (BRASH et al. 1991 ; DUMAZ et al. 1993; MATSUMURA et al. 1996 ), and the lack of repair activityensures the persistence of sunlight-induced lesions long enoughto result in replication errors. These characteristics of xerodermapatients link mutation and cancer. Some years ago, CAIRNS 1981 proposed that the xeroderma defect resulted only in skin tumors,and his paper provoked the collection of data showing that internaltumors are also increased in xeroderma patients (KRAEMER etal. 1984 ; KRAEMER et al. 1994 ). "Knockout" xeroderma mice(XPA deficient) do develop spontaneous liver tumors and an increasedfrequency of benzpyrene-induced lymphomas as compared to normalmice (DE VRIES et al. 1997 ). Deficiency in repair synthesis,however, is not necessarily the cause of the tumorigenesis becauseindividuals with trichothiodystropy and some cases of Cockaynes'syndrome have excision repair activities as low as some xerodermapatients but do not have an increased frequency of skin tumors,notwithstanding their sensitivity to light. Despite severalattempts, this paradox has not been explained (CHU and MAYNE1996 ; MARIONNET et al. 1996 ; STARY and SARASIN 1996 ; TAKAYAMAet al. 1996 ; WEEDA et al. 1997 ). The genes involved are complex,with both repair and transcription functions. These examplessuggest that heightened mutability is not necessarily accompaniedby a general increase in tumorigenesis and also that increasedmutability can be associated with only specific sorts of tumors.

Arguments against the hypothesis that tumors are necessarilyhypermutable have a long history (ARMITAGE and DOLL 1957 ; FISHER 1958 ). Two recent discussions have been published by TOMLINSON et al. 1996 and by SIMPSON 1997 . The developmentof each tumor is an evolutionary event and, as in macroevolution,mutations are subject to selection, and some mutations are neutraland subject to genetic drift. The presence of any number ofmutations in a tumor is the result of these different forces.Both very early and very recent calculations indicate that,given the power of selection and the biology of tumor development,selection is capable of yielding clones with multiple mutationswithout an increase in the normal mutation rate. Such calculationsdo not settle the issue, but they certainly indicate that thepresence of multiple mutations in tumors is not sufficient toestablish the case for general tumor hypermutability.

Some of the evidence that tumor cells are not necessarily hypermutablehas already been summarized. As an example, HARWOOD et al.1991 reported that two lines derived from a human colorectalcarcinoma had mutation rates of 5 x 10^-8 and 3 x 10^-8 per cellper generation for the apr t gene, rates "as low or lower" thanfor diploid human cell lines. WITTENKELLER et al. 1997 comparedthe mutation rates of hypoxanthine-guanine phosphoribosyltransferasein an immortalized human bronchial epithelial cell line andits tumorigenic derivative and found that the tumor line hadslightly lower rates. Of course, the control "line" had beenimmortalized so that even though not a tumor, it was hardly"normal." BUETTNER et al. 1996 found an increased mutationfrequency (for a transgenic lac gene) in only one of four tumorsarising in p53 knockout mice, and even in that tumor the increasewas only 2.3 fold. The p53 knockout mutation rate in normaltissue was not different from the normal (NISHINO et al. 1995). The rate of point mutation is not permanently higher thanthe normal somatic mutation rate for some genes in (some) tumorcells.

TP53 mutation

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ABSTRACT
Are tumors hypermutable?
TP53 mutation
Silent mutation
Multiple TP53 mutations
Mutations in other genes
Other examples of...
LITERATURE CITED

The TP53 tumor suppressor gene, whose product, the p53 protein,plays an important role in regulation of the cell cycle (LEVINE1997 ), is much studied: numerous mutations have been reported,and there are several data bases available that summarize theinformation (DEVRIES et al. 1996 ; CARRIELLO et al. 1997; HAINUTet al. 1997 ). The analysis below utilizes the data base firstprepared by HOLLSTEIN et al. 1996 which is available as anExcel spreadsheet (HAINUT et al. 1997 ). This data base includesall reported mutations in tumors and attempts to exclude mutationsat known polymorphic sites. Up to the end of 1996 (HAINUT etal. 1997 ), there were 6005 total p53 mutations recorded. Itseemed possible that an analysis of the mutational data base,and in particular the analysis of the frequency with which silentmutations occur, would permit an estimate of the nonselectedmutation frequency for the TP53 gene. Although knowledge ofthe mutation frequency does not permit estimation of the mutationrate, a comparison of the (nonselected) mutation frequenciesof genes in normal and tumor tissue might give some indicationof whether tumors are hypermutable.

Silent mutation

TOP
ABSTRACT
Are tumors hypermutable?
TP53 mutation
Silent mutation
Multiple TP53 mutations
Mutations in other genes
Other examples of...
LITERATURE CITED

Silent mutations are defined as nucleotide substitutions thatdo not result in amino acid changes, owing to the redundancyof the genetic code. There were 202 silent mutations in thetumors (HAINUT et al. 1997 ). However, nine of the silent mutationsrecorded occur at codons reported as polymorphic. Consequently,there are () x 100 = 3.2% silent mutations in the sample. Theirexact positions and the nature of the substitutions are readilyretrieved from the data base (HAINUT et al. 1997 ). The percentageof silent mutations is about the same in tumors and in celllines (STRAUSS 1997 ).

A certain proportion of the recorded mutations are probablydue to PCR errors, a problem that has been discussed previously(STRAUSS 1997 ). Although errors probably do occur, many ofthe papers reporting mutations do amplify several samples independentlyand take other precautions to reduce the possibility of error.The percentage of silent mutations reported in the 1996 update(42/915) is slightly higher than the overall value, making itmore likely that ~3% represents an accurate estimate of thefrequency of silent mutations among all TP53 mutations. Themethodology for the detection of mutations is necessarily becomingmore reliable as the utility of mutational analysis as a diagnostictool becomes evident. The question of whether the changes representpreexisting polymorphisms is harder to address because manyof the investigations utilize paraffin-embedded archival samplesas their source of tissue and do not have normal tissue controls.

If mutation were random and neutral, 23.5% of all mutationsin TP53 would be silent. This figure is based on the actualusage of codons in p53 and the probability of a mutation inthat codon being silent. The percentage of observed silent mutationsis much lower. However, inactivation of p53 function plays arole in the etiology of tumors and so frameshifts, missense,and nonsense mutations would be expected to have a selectiveadvantage. If we suppose that a first mutation in p53 inactivatesits function and contributes to tumorigenesis, then it is possiblethat additional mutations can accumulate in a nonselective way.A tabulation of the occurrence of silent mutations in tumorswith multiple p53 mutations might therefore make possible anonbiased estimate of their frequency. In the most recent data,there are 305 tumors with multiple mutations, and these tumorshad a total of 693 mutations. After removal of four possiblypolymorphic silent changes, 66 mutations, or 9.5%, were silent.This figure is still an underestimate of the total percentageof silent mutations because, as indicated above, a nonsilentmutation is (presumably) required for entry into the data set.If one assumes that among the tumors with multiple p53 mutations,silent mutations are only found in tumors with a p53-inactivatingmissense, nonsense, or frameshift mutation, then a correctedsilent mutation frequency can be obtained by dividing the totalnumber of silent mutations (66) among the multiple mutations(693) by the total number of mutations in that sample minusthe total number of tumors with multiple mutations (305) asa correction for the ascertainment bias. The corrected frequencyis 17% ([66/693-305] x 100). Because not all silent mutationsneed be nonselective (see below), the figure for silent mutationsis probably somewhere between 9.5% and 17%. What is criticalis that considerable numbers of silent mutations occur. An essentiallysimilar argument, in which the second mutations in doublets(including the silent mutations) are considered as "hitchhikers,"has been made by RODIN et al. 1998 .

Individual investigations from the published data base in whichsubstantial numbers of p53 mutations have been recorded do giveresults nearer to the expected value for silent mutations. Inone of the cases in which silent mutations were found and inwhich the surrounding tissue was also sequenced, 11 out of 29single nucleotide changes were silent, and of these, only twowere found in the surrounding tissue at a known polymorphicsite (HONGYO et al. 1995 ). In another investigation, a totalof 64 bladder tumors yielded 45 p53 mutations of which 11 (24%)were silent (TAYLOR et al. 1996 ). Two of the tumors had twosilent mutations each, and for these polymorphism was eliminatedby sequencing blood DNA. None of the other silent mutationswere at the sites of known polymorphisms (WESTON and GODBOLD1997 ).

Silent mutations need not be selectively neutral and, in fact,are not in many organisms (SHARP et al. 1995 ). Codon usagediffers, and the availability of tRNAs is different for thedifferent codons. In Drosophila, in yeast, and in E. coli ithas been shown that codons are selected. This does not seemto be true for humans in which codon usage for the same aminoacid in different genes expressed at the same time may differwidely (SHARP et al. 1993 ; see Table 6 in STRAUSS 1997 ).It has also been pointed out that silent mutation might producealternative splice sites (HONGYO et al. 1995 ). The productionof a 5' GT, for example, could result in a new splice site andan altered p53 protein, but no such altered protein has beenisolated. Notwithstanding these caveats, the hypothesis thatmost of the silent mutations are selectively neutral for tumorformation in humans remains a reasonable one.

If silent mutations are effectively neutral, then their frequencyin tumors, as compared to the frequency of newly occurring (i.e.,nonpolymorphic) mutations in normal tissue, should provide aclue to the question of the mutation rate in tumors. There isonly the most limited data that would permit an estimate ofwhat the expected frequency of a newly arising mutation in atumor might be, considering that a sufficient number of generationswould have had to occur between the mutation and the assay toresult in a clone of cells, most of which contained the mutation,so that it would be detected by current PCR methodology. AGUILARet al. 1994 estimated the frequency for mutation at one nucleotideof the frequently mutated p53 codon 249 in nonmalignant samplesof liver from hepatocellularcarcinoma patients. The detectionmethodology depends on the resistance of mutated sites to restriction-enzymedigestion. Values of <2 to 13 x 10^-7 per base were obtainedfor mutation at the third position of codon 249 in three nonmalignantliver samples. Assuming that all positions in the TP53 genehave the same mutability, but that only one-fourth of the changeswould give silent mutations, the highest frequency of silentmutations would be x 1179 coding bases x 1.3 x 10^-6 = 3.8 x10^-4, or 0.04%. This is about 1/100 of the overall frequencyof silent mutations in the p53 set and 1/400 of the correctedfrequency in multiple mutants. Another estimate can be obtainedfrom values for transgenic lacI mutations in the mouse, where NISHINO et al. 1995 report a frequency of 3.7 x 10^-5 mutationsper gene. The effective mutational size of the lacI gene is~210 bp, or ~one-fifth the p53 size. If this frequency appliedto humans, one might expect 3.7 x 10^-5 x 5 x 1/4 (to correctfor silent mutations), or 4.6 x 10^-5 = 0.005%. Once again, themeasured p53 silent mutation frequency in human tumors is muchhigher.

Values for mutation frequencies in blood cells of normal youngadults are available for four genes (ALBERTINI et al. 1993 ):hemoglobin (4 x 10^-8; red blood cells), hprt (5 x 10^-6; T cells), glycophorin A (10 x 10^-6; red blood cells), and HLA (3 x10^-5; T cells). The hprt frequency has been described in humankidney epithelium as age-dependent, ranging from 5 x 10^-5 (children)to 2.5 x 10^-4 (>80 yr) (MARTIN et al. 1996 ). Measurement ofthe somatic mutation frequency of a gene involved in O-acetylationof sialic acid in normal colonic mucosa from patients with eitherCrohn's disease, hereditary nonpolyposis colorectal cancer,or sporadic colorectal cancer gave values of 4.2 x 10^-4, 4.3x 10^-4, and 6.6 x 10^-4, respectively, with no significant differencesbetween the sets, although there was a significant age dependenceseen (WILLIAMS et al. 1995 ). These frequencies are about twoorders of magnitude lower than the frequency of silent mutations(even the uncorrected frequency) observed in TP53. The dataon silent mutations in TP53 show that this gene is hypermutablein tumors.

Multiple TP53 mutations

TOP
ABSTRACT
Are tumors hypermutable?
TP53 mutation
Silent mutation
Multiple TP53 mutations
Mutations in other genes
Other examples of...
LITERATURE CITED

Are there any other indications of a special nature for p53mutations in tumors? To answer this question, it is useful tolook at the distribution of mutations in tumors with multiplep53 mutations (Table 1). A problem with the tabulated data (HOLLSTEINet al. 1996 ; HAINUT et al. 1997 ) is that it is not easy tofind the number of tumors scored with no mutations, but it canbe estimated (M. HOLLSTEIN, personal communication) as ~24,000or 48,000 TP53 genes. There were 6005 mutations recorded. Thisgives a P(0) of 0.87 and a value of 0.13 mutations per p53 genebased on the Poisson expectation, P(0) = e^-m.

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Table 1. Reported mutations in the TP53 gene

There is a deficiency of double mutations but an excess of singleand multiple (>2) mutations (Table 1). There are several interpretationspossible for the deviations of the observed from expected value.A trivial explanation is that because only ~16% of the publicationsreport sequencing all exons, many second mutations were justnot observed. A second possibility (suggested by J. CAIRNS ina personal communication) is that there is a fraction of hypermutabletumors. Yet a third, not necessarily exclusive, possibilityis suggested by an examination of the position of the mutations,some of which are closely linked. A tabulation of tumors withtwo closely linked mutations, and including six tumors withthree mutations located no more than 10 codons from each other,has recently been presented (STRAUSS 1997 ). The current dataset provides additional cases. A particularly interesting exampleis provided by SHIPMAN et al. 1996 who carefully examinedTP53 mutations in 24 paired samples of normal and non-small-celllung carcinomas from the same individuals. Three of these tumorshad multiple TP53 mutations, including one with four mutations,shown by cloning to be the result of three mutations in oneallele and one in the other. SHIPMAN et al. 1996 eliminatedgerminal polymorphism as an explanation for the findings. Countingthe site of the first change, a deletion at position (1), asecond deletion occurred at base 36 followed by a base substitutionat position 46. The authors suggest that it is the first changethat creates a stop codon 23 bp downstream, and the followingmutations are presumably of no physiological importance. TAYLORet al. 1996 studied 64 bladder tumors. Thirty-two had p53 mutations,and of these, nine had multiple p53 mutations. One of thesetumors had five mutations at four codons (nos. 89, 101, 132and 214). Although this tumor came from an individual exposedto arylamines, multiple mutations occurred about equally inexposed and control groups, and there were no differences betweenexposed and control groups in the codons mutated or in the patternof changes—most were transitions. There is no evidencethat such multiple changes occur as part of a single (replicative)event, but the proximity of such changes and their frequencycertainly suggests that hypothesis. This possibility was firstraised by SEIDMAN et al. 1987 and by HARWOOD et al. 1991. SEIDMAN et al. 1987 found multiple point mutations in ashuttle vector introduced into repair-proficient lymphoblastoidcells, especially after introduction of a nick. The tumor celllines studied by HARWOOD et al. 1991 were peculiar in thatalthough the spontaneous mutation rate was low, those cellsthat did have mutations tended to have multiple mutations.

Mutations in other genes

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ABSTRACT
Are tumors hypermutable?
TP53 mutation
Silent mutation
Multiple TP53 mutations
Mutations in other genes
Other examples of...
LITERATURE CITED

The frequency of silent mutations and the observation of closelylinked multiple mutations are arguments for the hypothesis thatat least at some stage of tumorigenesis, the TP53 gene is hypermutableand/or mutates by a special mechanism. The question is thenwhether genes other than TP53 are hypermutable at some stageof tumorigenesis. Useful data are available for only a few genes.These include the APC gene (SMITH et al. 1994 ; BEROUD andSOUSSI 1996 , BEROUD and SOUSSI 1997 ; DEVRIES et al. 1996), the BRCA1 (FUTREAL et al. 1994 ; MERAJVER et al. 1995 )and BRCA2 cancer susceptibility genes (LANCASTER et al. 1996; MIKI et al. 1996 ; TENG et al. 1996 ), CDKN2 (cyclin-dependentkinase inhibitor, p16) (POLLOCK et al. 1996 ; SMITH-SORENSENand HOVIG 1996 ), WAF1 (SHIOHARA et al. 1994 ; KOOPMAN et al.1995 ), and HPRT (CARIELLO et al. 1997 ). Although numerousgerminal mutations have been reported in BRCA1 and BRCA2, thereis a paucity of somatic point mutations, probably because ofthe presence of numerous deletions that occur at a high-enoughfrequency to mask the point mutations (SMITH et al. 1996 ). POLLOCK et al. 1996 have compiled a list of 124 somatic mutationsin the CDKN2 (p16) tumor suppressor. Of these, four were silentbut one silent mutation occurred at the site of a dipyrimidinechange and a second at the site of a known polymorphism. Thissmall sample therefore gives a frequency of 2/124, or ~1.6%.Data bases are available for the APC gene in tumors (BEROUDand SOUSSI 1996 , BEROUD and SOUSSI 1997 ) and for HPRT incell cultures. The APC data base includes 339 germ line mutationsand 486 from tumors. Most of the mutations are either frameshiftor stop mutations. Only 6 of 339 germ line mutations and 20of 486 mutations in tumors were missense. (The difference isbarely significant; P < 0.05.) No silent mutations have beenrecorded. Double or triple mutations were reported in 18 ofthe tumors. In one report (ODA et al. 1996 ), eight of 13 sporadichepatoblastomas were reported to have APC point mutations, andof these, two cases had double mutations. One of these had aCCT to ACT change at codon 1319 and a AGC to AAC change at codon1321! The other double had mutations in codon 1395 and 1534.Tests for loss of heterozygosity were inconclusive.

WAF1 mutations were not found in a study of 315 samples from14 different malignancies, although two polymorphisms were detected,validating the sensitivity of the methodology (SHIOHARA et al.1994 ). A second study of WAF1 in a different set of tumorsalso found several polymorphisms in 158 brain tumors but nomutations, although p53 mutations were found in 22 of the tumors(KOOPMAN et al. 1995 ). If hypermutability was widespread, andmutation to silent alleles was at least as frequent as in TP53,~13 silent mutations might have been expected.

The data are inconclusive, but it certainly remains possiblethat mutations in TP53 are particularly easy to detect or thatthe gene is uniquely mutable and/or that hypermutation of p53is a likely (but not necessary) part of tumorigenesis. The particularstructure of a functional p53 protein might make dominant negativeeffects common so that the first mutation inactivates functionand that many second mutations would have no effect (this suggestionis from M. HOLLSTEIN). As has been suggested by several authors,inactivation of p53 might be important in inactivating the celldeath mechanisms, thereby permitting the accumulation of deleteriouschanges. However, in contrast to the APC gene (POWELL et al.1992 ), mutation in p53 is often a late event in carcinogenesis(BAKER et al. 1990 ; NERI et al. 1993 ; OHGAKI et al. 1993; BERCHUCK and BOYD 1995 ; CRAANEN et al. 1995 ; ILYAS etal. 1996 ; KAHLENBERG et al. 1996 ). For that reason, it isunlikely that inhibition of cell death due to p53 mutation permitsp53 mutations to accumulate. It is also unlikely that TP53 mutationis the initiating event in carcinogenesis.

Other examples of hypermutability

TOP
ABSTRACT
Are tumors hypermutable?
TP53 mutation
Silent mutation
Multiple TP53 mutations
Mutations in other genes
Other examples of...
LITERATURE CITED

The data indicate that the mutation process in (some) tumorcells and in (some) genes is different from mutation in normalcells. What occurs in tumorigenesis is reminiscent of the eventsinvolved in the generation of antibodies in which a limitedportion of the genome becomes hypermutable for a limited time(NEUBERGER and MILSTEIN 1995 ). Antibody production is an exampleof microevolution in much the same way as tumor formation isbecause a large number of random mutations are generated, andthose mutations that produce a more efficient antibody moleculeare selected. The mutations occur at random. Silent mutationsare found in 17% of nonproductively rearranged V_H chains andin 29% of productively rearranged chains (DORNER et al. 1997), close to the expected value. Antibody molecules may containmultiple changes, some possibly occurring in the same replicationcycle (STORB 1996 ). This special mutational process occursexclusively in a sequence defined by precise boundaries (LEBECQUEand GEARHART 1990 ) and is limited to a particular time in development.The nature of the error-generating mechanism in that processremains a mystery, although it appears to be linked to transcription(PETERS and STORB 1996 ).

The hypermutability that occurs in TP53 during tumorigenesisis reminiscent of the hypermutability of starving bacterialcells (STRAUSS 1992 ), a comparison that has not eluded theattention of workers in that field (SNIEGOWSKI et al. 1997 ; TADDEI et al. 1997 ; TORKELSON et al. 1997 ). A subpopulationof E. coli cells kept under starvation conditions become hypermutable.Although hypermutability is attained by modulation of the mismatchrepair system, a special mode of DNA replication may also berequired, possibly set off by double-strand breaks in the DNA(TORKELSON et al. 1997 ). The mutational process affects manygenes, and selection gives the appearance of adaptation (FOSTER1997 ). The factors that result in a hypermutable state remainto be determined.

Both experimental and modeling studies suggest that clonal populationsmay increase their rate of evolution by transient changes intheir mutation rates (SNIEGOWSKI et al. 1997 ; TADDEI et al.1997 ). In bacterial populations, it would appear that selectionis not the unique determinant of adaptation, as has been generallyaccepted (DRAKE 1991 , DRAKE 1992 ). The demonstration of asurprisingly high frequency of mutator strains among bacterialpathogens appears to illustrate this paradigm (LECLERC et al.1996 ), an example of the advantage of high mutability in populationsthemselves subject to selection (MAO et al. 1997 ). Recent experimentswith certain of the mismatch repair-deficient tumor cells indicatethat mutations accumulate only when the cells are maintainedat high density, rather than under conditions of rapid growth(RICHARDS et al. 1997 ). The data suggest that in tumors, asin starved bacteria, mutation rates are transiently increasedunder conditions of stress and that mutation rates in generalmay be influenced by the conditions of growth (BOESEN et al.1994 ). It may be that the initial events in carcinogenesisresult in a condition of transient hypermutability, perhapsas a result of a peculiar form of DNA synthesis related to thefunctional mismatch repair deficiency (RICHARDS et al. 1997). The processivity factor for DNA synthesis, proliferatingcell nuclear antigen has been reported to form a physical complexwith the mismatch repair proteins, and mutations in proliferatingcell nuclear antigen have a mutator effect ( JOHNSON et al.1996 ; UMAR et al. 1996 ). Some of the genes mutated as a resultof this hypermutable state may then play a role in the rapidprogression/evolution of the tumor.

FOOTNOTES

This paper is dedicated to DR. JOHN DRAKE on the occasionofhis retirement as Editor of GENETICS, in the hope that hemayfind it amusing.

ACKNOWLEDGMENTS

I am grateful to DR. MONICA HOLLSTEIN for her help in providingaccess to the updated p53 data base and for suggesting thatlooking at multiple mutations would be instructive. The suggestionthat p53 might be hypermutable comes in the first instance froman e-mail conversation with DR. JOHN CAIRNS. DR. CAIRNS alsopointed out the advantages of using the Poisson distributionfor the analysis of the mutation data. I am grateful to DR.BRIAN CHARLESWORTH for emphasizing the possible occurrence ofpolymorphisms among the silent mutations. Financial supportfor this work was provided by grant CA-32436 from the NationalCancer Institute, National Institutes of Health.

LITERATURE CITED

TOP
ABSTRACT
Are tumors hypermutable?
TP53 mutation
Silent mutation
Multiple TP53 mutations
Mutations in other genes
Other examples of...
LITERATURE CITED

AGUILAR, F., C. C. HARRIS, T. SUN, M. HOLLSTEIN, and P. CERUTTI, 1994 Geographic variation of p53 mutational profile in nonmalignant human liver. Science 264:1317-1319[Abstract/Free Full Text].

AKIYAMA, Y., R. IWANAGA, T. ISHIKAWA, K. SAKAMOTO, and N. NISHI et al., 1996 Mutations of the transforming growth factor-beta type II receptor gene are strongly related to sporadic proximal colon carcinomas with microsatellite instability. Cancer 78:2478-2484[Medline].

ALBERTINI, R. J., J. A. NICKLAS, J. C. FUSCOE, T. R. SKOPEK, and R. F. BRANDA et al., 1993 In vivo mutations in human blood cells: biomarkers for molecular epidemiology. Env. Health Perspectives 99:135-141.

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BAKER, S. J., A. C. PREISINGER, J. M. JESSUP, C. PARASKEVA, and S. MARKOWITZ et al., 1990 53 gene mutations occur in combination with 17p allelic deletions as late events in colorectal tumorigenesis. Cancer Res. 50:7717-7722[Abstract/Free Full Text].

BERCHUCK, A. and J. BOYD, 1995 Molecular basis of endometrial cancer. Cancer 76(10 Suppl.):2034-2040[Medline].

BEROUD, C. and T. SOUSSI, 1996 APC gene: database of germline and somatic mutations in human tumors and cell lines. Nucleic Acid Res. 24:121-124[Abstract/Free Full Text].

BEROUD, C. and T. SOUSSI, 1997 53 and APC gene mutations: software and databases. Nucleic Acids Res. 25:138[Abstract/Free Full Text].

BHATTACHARYYA, N. P., A. GANESH, R. G. PHEA, B. RICHARDS, and A. SKANDALIS et al., 1995 Molecular analysis of mutations in mutator colorectal carcinoma cell lines. Human Molecular Genetics 4:2057-2064[Abstract/Free Full Text].

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