Minisatellite mutation rate variation associated with a flanking DNA sequence polymorphism.

Human minisatellite mutation in the male germline frequently involves complex interallelic gene conversion events restricted to one end of the tandem repeat array. Some alleles at minisatellite MS32 show reduced variability in human populations and are associated with a G to C transversion upstream of the array. Analysis of single sperm demonstrated a frequently profound reduction in mutation rate at alleles carrying the C variant. This mutation suppression acts in cis, but does not affect the ability of an allele to act as sequence donor during gene conversion. This mutation rate polymorphism provides strong evidence for elements near the minisatellite that regulate tandem repeat instability.

Hypermutable myotonic dystrophy CTG repeats in transgenic mice.

Myotonic dystrophy (DM) is one of a growing number of inherited human disorders associated with the expansion of triplet repeat DNA sequences. Expanded alleles are highly unstable in both the germline and soma, accounting in large part for the unusual genetics of this disorder, its phenotypic variability and probably, the progressive nature of the symptoms. However, the molecular mechanisms and the genetic factors modulating repeat stability in DM and the other human disorders associated with expanded repeats are not well understood. To provide a model system in which the turnover of triplet repeats could be studied throughout mammalian development, we have generated five transgenic mouse lines incorporating expanded CTG/CAG arrays derived from the human DM locus. Transgene analysis has revealed germline hypermutability, including expansions, deletions and parent-of-origin effects, somatic and early embryonic instability and segregation distortion. Mutational differences between lines and sexes demonstrate that stability, as in humans, is modulated by as yet unidentified cis and trans acting genetic elements.

Complex gene conversion events in germline mutation at human minisatellites.

Mutation at the human minisatellites MS32, MS205 and MS31A has been investigated by characterizing mutant alleles in pedigrees and in the case of MS32 by direct analysis of mutant molecules in single sperm. Most mutations at all three loci are polar, involving the preferential gain of a few repeat units at one end of the tandem repeat array. Incoming repeats can be derived from the same allele or the homologous chromosome, through they are frequently rearranged during mutation. Lack of exchange of flanking markers suggests the involvement of complex conversion-like events in the generation of mutant alleles. At MS32, high frequency mutation processes in sperm appear to be largely germline specific and to occur at a constant rate irrespective of allele size. Together with mutational polarity, this implies that germline instability is controlled by elements outside the tandem repeat array.

Encephalopathic attacks in a family co-segregating myotonic dystrophy type 1, an intermediate Charcot-Marie-Tooth neuropathy and early hearing loss.

OBJECTIVE: To report new disease components in a unique myotonic dystrophy type 1 (DM1) family previously described by us in which all affected members also had a sensorimotor neuropathy that co-segregated with markers flanking the DM1 locus. METHODS: Clinical observations, electrophysiology, audiometry, DNA studies. RESULTS: During a follow-up period of over 25 years, the following were observed: (i) co-segregation of a striking new encephalopathic phenotype. In middle age, five patients were admitted on multiple occasions with attacks of impaired consciousness, psychomotor agitation, fever and, in about half of the cases, focal neurological signs, including unilateral weakness, sensory deficits and dysphasia. Reported onset phenomena consisted of confusion, headache, focal neurological symptoms and nausea; (ii) many patients show an early and severe sensorineural hearing loss; (iii) although they have mothers with the adult onset type, the four affected subjects from the youngest generation do not show any signs or symptoms of childhood or congenital myotonic dystrophy; (iv) the neuropathy meets the criteria of an intermediate type Charcot-Marie-Tooth (CMT), and is more severe in males; and (v) patients presented with an expanded fragment at the DM1 CTG repeat but this allele was refractory to PCR amplification and triplet repeat primed PCR at the 3' end of the array, indicating the existence of an additional lesion at the 3' end. CONCLUSIONS: The phenotype in this unique family extends beyond myotonic dystrophy and CMT to include encephalopathic attacks and early hearing loss, and is associated with an atypical mutation at the DM1 locus.

DNA profiling.

Although some concerns still remain in standard DNA profiling technology over the assumptions from population genetics used to calculate expected match frequencies, forensic scientists are preparing for the introduction of the next generation of DNA profiling techniques based on the polymerase chain reaction. These new techniques offer the prospect of dramatically increasing the speed and sensitivity of DNA profiling and have already been applied in some casework studies.

Complex patterns of male germline instability and somatic mosaicism in myotonic dystrophy type 1.

The genetic basis of myotonic dystrophy type 1 (DM1) is the expansion of a CTG repeat in the 3' untranslated region of DM1PK. Once into the disease range, the repeat becomes highly unstable and is biased toward expansion in both somatic and germline tissues. Intergenerational differences usually reveal an increase in allele length, concordant with the clinical anticipation characteristic of DM1, but there have also been cases with intergenerational contractions of the repeat length, accompanied by apparent anticipation. In order to gain a better understanding of this intergenerational behaviour, we have obtained semen samples from six DM males and used single molecule analyses to compare the allele distributions present in their sperm and blood with those of their offspring. We have confirmed that the male germline mutational pathway is distinct from that of the soma, but the extent of variation is highly variable from one individual to another and not obviously correlated with progenitor allele length. Nonetheless, in all cases the alleles present in the father's sperm overlap with those observed in their offspring. These data also provide further indications that the interpretation of intergenerational transmissions by standard analyses is frequently compromised by the masking of germline differences by age-dependent somatic expansion in the parent.

Attempts to detect retrotransposition and de novo deletion of Alus and other dispersed repeats at specific loci in the human genome.

Dispersed repeat elements contribute to genome instability by de novo insertion and unequal recombination between repeats. To study the dynamics of these processes, we have developed single DNA molecule approaches to detect de novo insertions at a single locus and Alu-mediated deletions at two different loci in human genomic DNA. Validation experiments showed these approaches could detect insertions and deletions at frequencies below 10(-6) per cell. However, bulk analysis of germline (sperm) and somatic DNA showed no evidence for genuine mutant molecules, placing an upper limit of insertion and deletion rates of 2 x 10(-7) and 3 x 10(-7), respectively, in the individuals tested. Such re-arrangements at these loci therefore occur at a rate lower than that detectable by the most sensitive methods currently available.

Frequency and stability of the myotonic dystrophy type 1 premutation.

BACKGROUND: Myotonic dystrophy type 1 (DM1) is associated with the expansion of an unstable CTG repeat. Larger alleles are associated with a more severe form of the disease and almost always increase in length from one generation to the next, accounting for the clinical anticipation characteristic of DM1. As such, expanded alleles are rapidly lost from the population. However, the incidence of the disease appears to remain constant. It was the authors' aim to determine the frequency and germline stability of the DM1 premutation alleles that give rise to new DM1 families. METHODS: The authors measured the size of the DM1 CTG repeat in blood DNA derived from a large number of individuals in DM1 families, including distant and unaffected relatives. RESULTS: It was determined that DM1 premutation alleles can be identified both in distant relatives of DM1 probands and more rarely in unaffected spouses. These premutation alleles are not directly associated with a clinical phenotype in the carrier but are highly unstable and liable to expand in succeeding generations, particularly when transmitted by a man. In addition, the authors observed occasional expansion-biased instability of alleles within the high end of the normal size range. CONCLUSIONS: Individuals carrying premutation alleles are at high risk of having affected offspring within a limited number of generations. Such data indicate that premutation alleles cannot be the long-term source of new DM1 families, which must ultimately arise from mutations of alleles within the upper normal size range.

Minisatellite variant repeat mapping: application to DNA typing and mutation analysis.

Most DNA typing systems assay allele length variation at tandemly repeated loci such as minisatellites and microsatellites. Allele length measurements are approximate, which impedes the use of such loci in forensic analysis and in studies of allelic variability at hypervariable loci. We now review progress in the development of alternative DNA typing systems based on allelic variation in the interspersion patterns of variant repeat units along minisatellite alleles. Minisatellite variant repeat mapping by PCR (MVR-PCR) not only provides a powerful new digital approach to DNA typing, but also for the first time allows investigation of the true level of allelic variability at minisatellite loci and of the mutational mechanisms that generate ultravariability.

Frequency of minisatellite repeat number changes at the MS205 locus in human sperm before and after cancer chemotherapy.

To determine whether the measurement of repeat number mutations at a minisatellite locus could detect human germline mutations induced by chemotherapy, we performed a longitudinal study of the mutation frequencies in sperm from 10 patients treated for Hodgkin's disease. Polymerase chain reaction on small pools of DNA equivalent to 100 sperm and Southern blotting were used to screen at least 7900 sperm in each sample to quantify the mutation frequency at the minisatellite MS205 locus. Pretreatment and posttreatment semen samples were obtained at least 2 months after completion of therapy from 4 patients treated with a regimen (Novantrone, Oncovin, vinblastine and prednisone [NOVP]) that lacks alkylating agents and from three patients treated with regimens (Cytoxan, vinblastine, procarbazine and prednisone/Adriamycin, bleomycin, dacarbazine, lomustine, and prednisone [CVPP/ABDIC] or mechlorethamine, Oncovin, procarbazine and prednisone [MOPP]) containing alkylating agents. There were no effects of NOVP or CVPP/ABDIC on the mutation frequencies. In the 1 patient treated with MOPP, the treatment with the highest dose of gonadotoxic alkylating agents, there was a statistically significant increase in mutation frequency from 0.79% pretreatment to 1.14% posttreatment, indicating induction of mutations in stem spermatogonia. During-treatment semen samples obtained from 2 patients treated with ABVD, which does not contain gonadotoxic alkylating agents, and 1 with NOVP also did not show any increases above the baseline mutation frequencies, indicating no increase in the minisatellite mutation frequency in spermatocytes. Thus, measurement of repeat number changes at minisatellite MS205 appears to be able to detect induced germline mutations in human sperm. However, most chemotherapy regimens do not significantly increase this class of mutations.

Unstable triplet repeat diseases.

Seven inherited human disorders are now associated with the intragenic expansion of triplet repeat DNA sequences. These repeats demonstrate extreme instability in both germline and somatic tissue, accounting for the unusual genetic inheritance patterns and symptom variability associated with these diseases.

Minisatellite isoalleles can be distinguished by single-stranded conformational polymorphism analysis in agarose gels.

Minisatellite isoallelism, i.e. the occurrence of minisatellite alleles with different internal sequence composition but indistinguishable length, is a common limitation of minisatellite allele length analysis. Internal sequence variation can be used to distinguish such isoalleles, provided that detailed sequence knowledge of its basis is available. We now show that minisatellite isoalleles can also be simply resolved by single-stranded conformational polymorphisms (SSCP) arising during agarose gel electrophoresis. SSCP on agarose gels can be used to distinguish minisatellite isoalleles either after PCR amplification, or by standard Southern blot analysis of genomic DNA.

Minisatellite "isoallele" discrimination in pseudohomozygotes by single molecule PCR and variant repeat mapping.

The D1S8 hypervariable minisatellite MS32 has a heterozygosity of 97.5% based on detectable differences in allele length using standard Southern blot analysis. It has previously been shown that the basic repeat unit is in itself variable and that this may be used to map the internal structure of an allele. This method has already been used to establish that alleles of the same length may have differing internal structures between nonrelated individuals. We now extend this approach to demonstrate that two apparently homozygous individuals are in fact heterozygotes. For each individual the two comigratory alleles were separated, without cloning, using single molecule dilution (SMD) of genomic DNA and recovery with PCR. Mapping of the variant repeat units revealed highly diverged internal structures and, for one individual, a size difference of one repeat unit (29 bp). SMD and PCR recovery provide an efficient system for separating comigratory alleles without prerequirement for knowledge of sequence differences.

Myotonic dystrophy: an unstable CTG repeat in a protein kinase gene.

Myotonic dystrophy (DM) is caused by the amplification of CTG repeats in the 3' untranslated region of a gene encoding a protein homologous to serine/threonine protein kinases. In DM patients the CTG repeats are extremely unstable, varying in length from patient to patient and generally increasing in length in successive generations. There is a strong correlation between the size of the repeats and the age of onset and severity of the disease. The molecular basis of the effect of the CTG expansion on the development of the DM phenotype continues to be investigated. The first working hypothesis of the molecular mechanism of DM was a reduction in steady-state myotonin-protein kinase (Mt-PK) mRNA and protein levels. However, although the consensus finding is that the Mt PK mRNA and protein levels are decreased in DM patients, it is still not clear if this reduction leads directly to the DM phenotype. In this short review we discuss the molecular aspects of CTG instability and the expression of the myotonin-protein kinase gene in normal and DM populations.

Cis-acting modifiers of expanded CAG/CTG triplet repeat expandability: associations with flanking GC content and proximity to CpG islands.

An increasing number of human genetic disorders are associated with the expansion of trinucleotide repeats. The majority of these diseases are associated with CAG/CTG expansions, including Huntington's disease, myotonic dystrophy and many of the spinocerebellar ataxias. Recently, two new expanded CAG/CTG repeats have been identified that are not associated with a phenotype. Expanded alleles at all of these loci are unstable, with frequent length changes during intergenerational transmission. However, variation in the relative levels of instability, and the size and direction of the length change mutations observed, between the CAG/CTG loci is apparent. We have quantified these differences, taking into account effects of progenitor allele length, by calculating the relative expandability of each repeat. Since the repeat motifs are the same, these differences must be a result of flanking sequence modifiers. We present data that indicate a strong correlation between the relative expandability of these repeats and the flanking GC content. Moreover, we demonstrate that the most expandable loci are all located within CpG islands. These data provide the first insights into the molecular bases of cis -acting flanking sequences modifying the relative mutability of dispersed expanded human triplet repeats.

Mouse tissue culture models of unstable triplet repeats: in vitro selection for larger alleles, mutational expansion bias and tissue specificity, but no association with cell division rates.

The expansion of CAG.CTG trinucleotide repeats has been associated with an increasing number of human diseases. Once into the expanded disease-associated range, the repeats become dramatically unstable in the germline and also throughout the soma. Instability is expansion-biased, contributing towards the unusual genetics, and most likely the tissue-specificity and progressive nature of the symptoms. Such expansions constitute a unique form of dynamic mutation whose mechanism is poorly understood. It is generally assumed that repeat length changes arise via replication slippage, yet no direct evidence exists to support this hypothesis in a mammalian system. We have previously generated transgenic mouse models of unstable CAG.CTG repeats that reconstitute the dynamic nature of somatic mosaicism observed in humans. We have now used tissues from these mice to establish in vitro cell cultures. Monitoring of repeat stability in these cells has revealed the progressive accumulation of larger alleles as a result of repeat length changes in vitro, as confirmed by single cell cloning. We also observed the selection of cells carrying longer repeats during the first few passages of the cultures and frequent additional selective sweeps at later stages. The highest levels of instability were observed in cultured kidney cells, whereas the transgene remained relatively stable in eye cells and very stable in lung cells, paralleling the previous in vivo observations. No correlation between repeat instability and the cell proliferation rate was found, rejecting a simple association between length change mutations and cell division, and confirming a role for additional cell-type specific factors.

Allele-specific MVR-PCR analysis at minisatellite D1S8.

Minisatellite variant repeat mapping by the polymerase chain reaction (MVR-PCR) provides a digital approach to DNA typing of great potential use both in forensic medicine and, by mapping single alleles, for exploring allelic variability and mutation processes at minisatellites. The MVR haplotypes of single alleles can be determined either from physically separated alleles or by pedigree analysis of digital diploid codes generated from both alleles simultaneously. We now show that single alleles can be rapidly mapped from total genomic DNA using allele-specific PCR primers directed to polymorphic sites in the DNA flanking the minisatellite. This approach can also be used to dissect mixed DNA samples such as those often encountered in forensic DNA analysis.

Somatic heterogeneity of the CTG repeat in myotonic dystrophy is age and size dependent.

The most common form of adult muscular dystrophy, myotonic dystrophy (DM), is caused by the abnormal expansion of the CTG repeat, located in the 3' UTR of the DM gene. The expanded-CTG allele often presents as a diffused band on Southern blot analysis, suggesting somatic mosaicism. In order to study the somatic instability of the CTG repeat, we have investigated the dynamics of the size heterogeneity of the CTG expansion. Size heterogeneity is shown as a smear on Southern blot and is measured by the midpeak-width ratio of the expanded allele to the normal sized allele. The ratio is also corrected for compression in the higher-molecular-weight region. It is found that the size heterogeneity of the expanded-CTG repeats, of 173 DM patients, correlates well with the age of the patient (r = .81, P << .001). The older patients show larger size variation. This correlation is independent of the sex of either the patient or the transmitting parent. The size heterogeneity of the expansion, based on age groups, is also dependent on the size of the expanded trinucleotide repeat. However, obvious size heterogeneity is not observed in congenital cases, regardless of the size of expansion. Comparison of individual patient samples collected at two different times has confirmed that the degree of size heterogeneity increases with age and has revealed a subtle but definite upward shift in the size of the expanded-CTG allele. The progression of the CTG repeat toward larger expansion with age is further confirmed by small-pool PCR assay that resolved the heterogeneous fragments into discrete bands.(ABSTRACT TRUNCATED AT 250 WORDS)

Somatic mosaicism, germline expansions, germline reversions and intergenerational reductions in myotonic dystrophy males: small pool PCR analyses.

In order to characterize the dynamics of CTG repeat instability in somatic and germline tissue from myotonic dystrophy (DM) males we have used small pool polymerase chain reaction (PCR) in a detailed quantitative analysis of repeat length variation. We demonstrate that the heterogeneous smear of CTG repeats observed in DM patients using standard analyses is comprised of multiple unresolved bands that may be dissected into discrete length alleles derived from single cells using single molecule PCR techniques. Analysis of somatic tissues demonstrates a bias toward increasing allele length and a lower boundary below which variant alleles are rare, consistent with a highly directional expansion pathway in the soma. Two sperm samples show extensive variation and a size increase bias, concordant with the phenomenon of anticipation. In addition, sperm analysis shows that large contractions, including reversions into the normal size range, are restricted to the germline. Detailed analysis of intergenerational 'reductions' paternally transmitted to two offspring suggests that some apparent reductions may be artifacts of somatic expansion in the parent. Our data indicate that in addition to germline variation, substantial somatic expansion can also contribute to the intergenerational differences usually observed in DM.

Four-state MVR-PCR: increased discrimination of digital DNA typing by simultaneous analysis of two polymorphic sites within minisatellite variant repeats at D1S8.

Minisatellite variant repeat mapping by PCR (MVR-PCR) provides a digital approach to DNA typing that can reveal huge levels of variation at minisatellite loci. MVR-PCR has so far been applied to three human minisatellites, including the hypervariable locus D1S8. Previous analysis at D1S8 was based on the discrimination of repeat unit types that differ by a single base substitution. We now show that a second polymorphic site within D1S8 repeats may be assayed simultaneously with the first to define four classes of repeat units ('four-state MVR-PCR'). This approach can also be applied to the other end of D1S8 alleles in 'reverse four-state MVR-PCR'. Both of these procedures substantially increase the informativeness of MVR analysis at D1S8 and should prove useful in studies of minisatellite biology and potentially in forensic DNA typing.