Mutant small heat shock protein B3 causes motor neuropathy: utility of a candidate gene approach

OBJECTIVE

Idiopathic peripheral neuropathy is common and likely due to genetic factors that are not detectable using standard linkage analysis. We initiated a candidate gene approach to study the genetic influence of the small heat shock protein (sHSP) gene family on an axonal motor and motor/sensory neuropathy patient population.

METHODS

The promoter region and all exonic and intronic sequences of the 10 sHSP genes (HSPB1-HSPB10) were screened in a cohort of presumed nonacquired, axonal motor and motor/sensory neuropathy patients seen at the Ohio State University Neuromuscular Clinic.

RESULTS

A missense mutation in the gene encoding small heat shock protein B3 (HSPB3, also called HSP27, protein 3) was discovered in 2 siblings with an asymmetric axonal motor neuropathy. Electrophysiologic studies revealed an axonal, predominantly motor, length-dependent neuropathy. The mutation, HSPB3(R7S), is located in the N-terminal domain and involves the loss of a conserved arginine.

CONCLUSIONS

The discovery of an HSPB3 mutation associated with an axonal motor neuropathy using a candidate gene approach supports the notion that the small heat shock protein gene family coordinately plays an important role in motor neuron viability.

Preclinical validation of a multiplex real-time assay to quantify SMN mRNA in patients with SMA

OBJECTIVE

To determine whether survival motor neuron (SMN) expression was stable over time.

METHODS

We developed a multiplex real-time reverse transcriptase (RT)-PCR assay to quantify SMN transcripts in preclinical blood samples from 42 patients with spinal muscular atrophy (SMA) drawn for three time points per patient; most blood samples were shipped to a centralized laboratory.

RESULTS

We obtained a sufficient amount (9.7 +/- 5.6 microg) of good-quality total RNA, and RNAs were stable for up to a 3-year interval. This allowed RNA samples collected during a 9- to 12-month period to be analyzed in a single run, thus minimizing interexperimental variability. SMN expression was stable over time; intersample variability for baseline measures, collected during a 17-month interval, was less than 15% for 38 of 42 SMA patients analyzed. This variability was well below the 1.95-fold increase in full-length SMN (flSMN) transcripts detected in SMA fibroblasts treated with 10 mM valproic acid.

CONCLUSION

Real-time quantification of SMN messenger RNA expression may be a biomarker that is amenable to multicenter SMA clinical trials.

Diagnostic and prognostic value of glycosyltransferase mRNA in glioblastoma multiforme patients

Glioblastoma multiforme (GBM) is the most common and aggressive primary human brain tumour in adults with an average survival of 11 months. The 2-year survival is less than 10%, and only a small proportion of patients are alive at 3 years. Despite improved treatment strategies and aggressive therapy, the prognosis of GBM has changed little in past decades. Thus, any test that can reliably and rapidly diagnose the tumour and predict patient survival could be a valuable tool. Herein we report the use of quantitative real-time polymerase chain reaction (PCR) to quantify five glycosyltransferase transcripts in gliomas. Our results indicate that measuring GM1 synthase (beta-1,3 galactosyltransferase) mRNA may provide a useful method for segregating GBMs from other types of gliomas. In these studies, 97% of gliomas (36/37 tumours) below a threshold value had a diagnosis of GBM compared with 49% (52/106 tumours) above the threshold. More importantly, the increased expression of GD3 synthase mRNA in combination with decreased GalNAcT message correlated with increased survival in 79 GBM patients (proportional hazards model controlling for age, P = 0.02). These data were further corroborated by a data analysis from one of our previous studies on gangliosides of 80 GBMs, in which increased amounts of GM3 and GD3 (which accumulate in the absence of GalNAcT) correlated with a longer survival (P < 0.01). Thus, measuring GalNAcT and GD3 transcripts may provide a rapid method to assess prognosis in GBM patients. In summary, the data indicate that measuring glycosyltransferase mRNA levels by real-time PCR may be clinically useful for determining both diagnosis and prognosis in GBM patients.

Identification of a deletion in the mismatch repair gene, MSH2, using mouse-human cell hybrids monosomal for chromosome 2

Hereditary non-polyposis colorectal cancer is characterized by mutations in one of the DNA mismatch repair genes, primarily MLH1, MSH2, or MSH6. We report here the identification of a genomic deletion of approximately 11.4 kb encompassing the first two exons of the MSH2 gene in two generations of an Ohio family. By Southern blot analysis, using a cDNA probe spanning the first seven exons of MSH2, an alteration in each of three different enzyme digests (including a unique 13-kb band on HindIII digests) was observed, which suggested the presence of a large alteration in the 5' region of this gene. Mouse-human cell hybrids from a mutation carrier were then generated which contained a single copy each of human chromosome 2 on which the MSH2 gene resides. Southern blots on DNA from the cell hybrids demonstrated the same, unique 13-kb band from one MSH2 allele, as seen in the diploid DNA. DNA from this same monosomal cell hybrid failed to amplify in polymerase chain reactions (PCRs) using primers to exons 1 and 2, demonstrating the deletion of these sequences in one MSH2 allele, and the breakpoints involving Alu repeats were identified by PCR amplification and sequence analysis.

A placebo-controlled trial of gabapentin in spinal muscular atrophy

OBJECTIVE

To evaluate the efficacy of gabapentin in increasing muscle strength of patients with spinal muscular atrophy (SMA).

BACKGROUND

Preclinical data in experimental models of motor neuron disease suggest a neuroprotective effect of gabapentin.

METHODS

Gabapentin (1200 mg), or placebo, was administered three times daily in a randomized, double-blind trial for 12 months. The primary outcome measure was the average percent change from baseline, based on the measurement of strength in four muscles (elbow flexion and hand grip bilaterally) for each patient. Drug efficacy was examined by comparing the percent change in strength for patients on drug vs. placebo. Secondary efficacy variables included: forced vital capacity (FVC), SMA functional rating scale (SMAFRS), and mini-Sickness Impact Profile (SIP).

RESULTS

Eighty-four patients, with type II or III SMA, were enrolled at eight sites across the United States. There were no differences in baseline features. There was no difference between the placebo and drug groups in any outcome measure.

CONCLUSIONS

This study demonstrates the feasibility of this trial design and provides data for the design of future clinical trials in SMA.

Diagnosis of Duchenne dystrophy by enhanced detection of small mutations

OBJECTIVE

To determine whether detection of small mutations of the dystrophin gene can be increased using an enhanced method of single-strand conformation polymorphism analysis.

BACKGROUND

Usual methods of DNA analysis for Duchenne dystrophy cannot identify mutations in one-third of cases. Muscle biopsy, with its inherent risks and added liability for patients with Duchenne dystrophy, becomes the sole method of diagnosis. Even with a tissue diagnosis of dystrophin deficiency, many families are excluded from carrier detection and prenatal diagnosis.

METHODS

Genomic DNA from a cohort of 93 patients with Duchenne dystrophy without identifiable gene mutations was screened for mutations. In each case, 22 kilobases of genomic DNA were scanned, including all 79 exons of the dystrophin gene, adjacent intronic regions, and six alternative exons 1.

RESULTS

Sixty-eight (73%) had small mutations, including 34 nonsense mutations, 27 microdeletions and insertions, and 7 splice site mutations. No missense mutations were found. One nonsense mutation in exon 59 was detected in four patients. Most mutations were new; 54 of 62 different small mutations have not been reported. Mutations were found throughout the gene: 24% in the first quartile, 31% in the second, 16% in the third, and 29% in the fourth.

CONCLUSIONS

A highly sensitive single-strand conformation polymorphism method substantially increased detection of small dystrophin gene mutations and made it possible to diagnose approximately 90% of patients with Duchenne dystrophy by DNA analysis. These findings, combined with cost savings and safety issues, provide compelling reasons to consider DNA analysis as the initial diagnostic test for the suspected dystrophin-deficient patient.

Opposite association of two PPARG variants with cancer: overrepresentation of H449H in endometrial carcinoma cases and underrepresentation of P12A in renal cell carcinoma cases

Peroxisome proliferator activated receptor gamma (PPARgamma) is a nuclear hormone receptor that has been shown to regulate differentiation and cell growth. Studies of the differentiative effects of PPARgamma agonists on several cancer cell lines led to the hypothesis that dysfunction of PPARgamma contributes to tumorigenesis. These functional observations were strengthened by genetic evidence: somatic loss-of-function mutations in PPARG, encoding PPARgamma, in sporadic colorectal carcinomas and somatic translocation of PAX8 and PPARG in follicular thyroid carcinoma. Recently overrepresentation of the H449H variant was found in a cohort of American patients with glioblastoma multiforme. The glioblastoma multiforme data suggest that PPARG contributes common, low-penetrance alleles for cancer susceptibility. To test this hypothesis in a broader range of cancers we examined a series of carcinomas of the cervix, endometrium, ovary, prostate, and kidney for germline sequence variation in PPARG. In addition to the two common sequence variants, P12A and H449H, there were five other sequence variants. P12A alleles were underrepresented in renal cell carcinoma patients compared to country-of-origin race-matched controls (3.75% vs. 12.1%, P<0.04). In contrast, the H449H variant was overrepresented in individuals with endometrial carcinoma compared to controls (14.4% vs. 6.25%, P<0.02). These observations lend genetic evidence consistent with our hypothesis that PPARG serves as a common, low-penetrance susceptibility gene for cancers of several types, especially those epidemiologically associated with obesity and fat intake.

Increased D allele frequency of the angiotensin-converting enzyme gene in pulmonary fibrosis

An insertion/deletion (I/D) polymorphism of the angiotensin-converting enzyme has previously been studied extensively in relationship to cardiovascular and renal disease. The deletion/deletion (D/D) genotype is associated with a poor outcome in immunoglobulin (Ig) A nephropathy. However, the association of this genetic marker in cardiovascular and renal disease has generated controversy, with the exception of the rate of progression and therapeutic responsiveness in IgA nephropathy. Many of the same cytokines and polypeptide mediators involved in fibrosis of the cardiovascular and renal systems have been shown to be involved in pulmonary fibrosis. We examined the I/D polymorphism of the angiotensin-converting enzyme in a group of 24 patents with interstitial pneumonia and moderate to severe pulmonary fibrosis defined by radiographic studies, pulmonary function tests, and histologic findings. The incidence of the D allele in this study population was 69.0%, which is approximately 15.0% higher than the incidence in the general population of 54.0%. The incidence of the D/D genotype was 42.0%, which is approximately 11.0% greater than that in the general population (31.0%). The distribution of the D/D, I/D, and insertion/insertion genotypes of these 24 patients was not significantly different from that of historical controls (P =.1; chi(2) test); there were marginally significantly more D alleles among the 48 observed alleles than would be expected (P =.04).

Comparison of cytogenetic and molecular genetic detection of t(8;21) and inv(16) in a prospective series of adults with de novo acute myeloid leukemia: a Cancer and Leukemia Group B Study

PURPOSE

To prospectively compare cytogenetics and reverse transcriptase-polymerase chain reaction (RT-PCR) for detection of t(8;21)(q22;q22) and inv(16)(p13q22)/t(16;16)(p13;q22), aberrations characteristic of core-binding factor (CBF) acute myeloid leukemia (AML), in 284 adults newly diagnosed with primary AML.

PATIENTS AND METHODS

Cytogenetic analyses were performed at local laboratories, with results reviewed centrally. RT-PCR for AML1/ETO and CBFbeta/MYH11 was performed centrally.

RESULTS

CBF AML was ultimately identified in 48 patients: 21 had t(8;21) or its variant and AML1/ETO, and 27 had inv(16)/t(16;16), CBFbeta/MYH11, or both. Initial cytogenetic and RT-PCR analyses correctly classified 95.7% and 96.1% of patients, respectively (P =.83). Initial cytogenetic results were considered to be false-negative in three AML1/ETO-positive patients with unique variants of t(8;21), and in three CBFbeta/MYH11-positive patients with, respectively, an isolated +22; del(16)(q22),+22; and a normal karyotype. The latter three patients were later confirmed to have inv(16)/t(16;16) cytogenetically. Only one of 124 patients reported initially as cytogenetically normal was ultimately RT-PCR-positive. There was no false-positive cytogenetic result. Initial RT-PCR was falsely negative in two patients with inv(16) and falsely positive for AML1/ETO in two and for CBFbeta/MYH11 in another two patients. Two patients with del(16)(q22) were found to be CBFbeta/MYH11-negative. M4Eo marrow morphology was a good predictor of the presence of inv(16)/t(16;16).

CONCLUSION

Patients with t(8;21) or inv(16) can be successfully identified in prospective multi-institutional clinical trials. Both cytogenetics and RT-PCR detect most such patients, although each method has limitations. RT-PCR is required when the cytogenetic study fails; it is also required to determine whether patients with suspected variants of t(8;21), del(16)(q22), or +22 represent CBF AML. RT-PCR should not replace cytogenetics and should not be used as the only diagnostic test for detection of CBF AML because of the possibility of obtaining false-positive or false-negative results.

Hybrids monosomal for human chromosome 5 reveal the presence of a spinal muscular atrophy (SMA) carrier with two SMN1 copies on one chromosome

We have analyzed the survival motor neuron gene (SMN1) dosage in 100 parents of children with homozygous SMN1 deletions. Of these parents, 96 (96%) demonstrated the expected one-copy SMN1 carrier genotype. However, four parents (4%) were observed to have a normal two-copy SMN1 dosage. The presence of two intact SMN1 genes in the parent of an affected child indicates either the occurrence of a de novo mutation event or a situation in which one chromosome has two copies of SMN1, whereas the other is null. We have separated individual chromosomes from two of these parents with two-copy SMN1 dosage by somatic cell hybridization and have employed a modified quantitative dosage assay to provide direct evidence that one parent is a two-copy/ zero-copy SMN1 carrier, whereas the other parent had an affected child as the result of a de novo mutation. These findings are important for assessing the recurrence risk of parents of children with spinal muscular atrophy and for providing accurate family counseling.

Polymorphisms in a pseudogene highly homologous to PMS2

PMS2 is one of a complex of genes encoding DNA repair proteins that includes MSH2, MLH1, MSH6 and MSH3. Mutation of any of these DNA mismatch repair genes leads to impairment of DNA repair and can lead to tumorigenesis. Germline mutation of PMS2 has been reported as a rare cause of hereditary nonpolyposis colorectal cancer (HNPCC) and Turcot's syndrome. The PMS2 gene is located on chromosome 7p22 and consists of 15 exons. Within exon 11 of PMS2 is a coding repeat of eight adenosines. This study reports on the finding of a nonexpressed pseudogene that is highly homologous to the PMS2 gene in this region. The pseudogene is polymorphic for two alterations in the repeat region: a 3 bp delAAA at a site corresponding to nucleotide 1231 in PMS2; and an AA-->GG change at nucleotide 1238. Due to the high homology in both intronic and exonic sequences, polymorphisms in this pseudogene could be mistaken for mutations in the PMS2 gene and erroneously thought to be a cause of HNPCC and/or Turcot's syndrome.

Diffuse leiomyomatosis of the uterus: a case report with clonality analysis

Diffuse uterine leiomyomatosis is a rare condition distinguished from the common uterine leiomyomata by involvement of the entire myometrium by innumerable, ill-defined, often small and confluent, histologically benign smooth-muscle nodules. Fourteen cases have been previously described in the literature. We report a case of diffuse leiomyomatosis in a 39-year-old woman. Several microscopic foci of the process were microdissected for clonality analysis. All samples showed a non-random X-chromosome inactivation pattern, and thus were consistent with a monoclonal neoplastic population of cells. However, in different foci of tumor, different X chromosomes were inactivated, supporting the independent origin of neoplastic clones and rejecting the possibility of a single clonal origin of all tumor cells. The results of the molecular analysis suggest that diffuse uterine leiomyomatosis may be an exuberant example of diffuse and uniform involvement of the entire myometrium by multiple leiomyomata. HUM PATHOL 31:1429-1432.

Over-representation of PPARgamma sequence variants in sporadic cases of glioblastoma multiforme: preliminary evidence for common low penetrance modifiers for brain tumour risk in the general population

PPARgamma, the gamma isoform of a family of peroxisome proliferator activated receptors, plays a key role in adipocyte differentiation. Recently, its broad expression in multiple tissues and several epithelial cancers has been shown. Further, somatic loss of function mutations in PPARgamma have been found in primary colorectal carcinomas. We sought to determine if somatic high penetrance mutations in this gene might also play a role in glioblastoma multiforme (GBM). We also examined this gene to determine if common low penetrance polymorphic alleles might lend low level susceptibility to GBM in the general population. No somatic high penetrance mutations were detected in 96 sporadic GBMs. However, polymorphic alleles at codons 12 and 449 were significantly over-represented among the 27 unrelated American patients with sporadic GBM compared to 80 race matched controls. While nine (33%) were heterozygous for the P12A variant, c.34C/G (cytosine to guanine change at nucleotide 34), 12 (15%) controls were heterozygous for P12A (p<0.05). Similarly, 13 of 26 (50%) glioblastoma patients compared to 10 of 80 (12%) normal controls were found to have the heterozygous H449H polymorphism (p<0.001). The over-representation of H449H in glioblastoma patients was confirmed with a second validation set of American patients. When both American series were combined, polymorphic H449H was over-represented among cases versus controls (p<0.001) and there was a similar trend (p=0.07) for P12A. The precise mechanism for this association is unknown but these PPARgamma polymorphisms may be acting in a low penetrance predisposing manner. However, these associations were not found in a German population, possibly arguing that if these variants are in linkage disequilibrium with a third locus, then this effect is relatively new, after the settlement of the American colonies.

Transfusion-associated graft-vs-host disease. A fatal case caused by blood from an unrelated HLA homozygous donor

Transfusion-associated graft-vs-host disease (TA-GVHD) is a rare complication of transfusion. We report fatal TA-GVHD in a 63-year-old coronary artery bypass patient of European descent after an RBC transfusion from an unrelated donor. The patient had mild lymphocytopenia and received 2 80-mg doses of methylprednisolone and 7 units of RBCs. On day 14 after the transfusion, he had fever, elevated liver enzyme levels, and a macular rash. Pancytopenia and bone marrow aplasia developed. On day 26, he had a massive gastrointestinal hemorrhage and died. At autopsy, histopathologic findings of the skin, liver, bone marrow, and gastrointestinal tract were consistent with TA-GVHD. One donor of the transfused RBCs (3 days old at transfusion) had a 1-way HLA match with the patient. A method using multiplex polymerase chain reaction is presented. This patient with TA-GVHD and mild immune suppression suggests that blood component irradiation guidelines may need to be reevaluated.

Case report on hereditary non-polyposis colon cancer (HNPCC) in Nigeria

The role of genetic factors in the etiology of colorectal cancers (CRCs) has recently been elucidated with the discovery of the mismatch repair. These genes are responsible for less than 5% of all cases of CRCs in Caucasian series. In this pilot study, tumors from 5 randomly ascertained CRC patients were subjected to microsatellite analysis, and two were microsatellite unstable. Both of these two patients had germline mutations in MSH2. If this finding can be confirmed in a larger series of patients, it suggests that MMR genes play an important role in the etiology of CRCs in Africa.

The human centromeric survival motor neuron gene (SMN2) rescues embryonic lethality in Smn(-/-) mice and results in a mouse with spinal muscular atrophy

Proximal spinal muscular atrophy (SMA) is a common motor neuron disease in humans and in its most severe form causes death by the age of 2 years. It is caused by defects in the telomeric survival motor neuron gene ( SMN1 ), but patients retain at least one copy of a highly homologous gene, centromeric SMN ( SMN2 ). Mice possess only one survival motor neuron gene ( Smn ) whose loss is embryonic lethal. Therefore, to obtain a mouse model of SMA we created transgenic mice that express human SMN2 and mated these onto the null Smn (-/-)background. We show that Smn (-/-); SMN2 mice carrying one or two copies of the transgene have normal numbers of motor neurons at birth, but vastly reduced numbers by postnatal day 5, and subsequently die. This closely resembles a severe type I SMA phenotype in humans and is the first report of an animal model of the disease. Eight copies of the transgene rescues this phenotype in the mice indicating that phenotypic severity can be modulated by SMN2 copy number. These results show that SMA is caused by insufficient SMN production by the SMN2 gene and that increased expression of the SMN2 gene may provide a strategy for treating SMA patients.

Spinal muscular atrophy variant with congenital fractures

A single report of brothers born to first-cousin parents with a form of acute spinal muscular atrophy (SMA) and congenital fractures suggested that this combination represented a distinct form of autosomal recessive SMA. We describe a boy with hypotonia and congenital fractures whose sural nerve and muscle biopsies were consistent with a form of spinal muscular atrophy. Molecular studies identified no abnormality of the SMN(T) gene on chromosome 5. This case serves to validate the suggestion of a distinct and rare form of spinal muscular atrophy while not excluding possible X-linked inheritance.

Methylation analysis of the fragile X syndrome by PCR

The fragile X syndrome is predominantly caused by a large expansion of a CGG trinucleotide repeat in the promoter region of the FMR1 gene, which is associated with methylation and downregulation of transcription. The molecular diagnosis of this disorder is based on repeat size and methylation analysis of the FMR1 gene usually by Southern blot analysis. We describe a PCR-based method for the analysis of methylation of the FMR1 gene, which involves bisulfite treatment of DNA prior to amplification. Fifty-two normal and 48 affected, premutation, or mosaic males were analyzed in a blinded study by this method. A prospective study of 30 males suspected of fragile X was also performed. Amplification specific for the methylated FMR1 sequence was readily observed in all individuals with a full mutation, whereas all normal and premutation individuals showed only amplification-specific for the unmethylated sequence, thus, allowing affected and unaffected males to be distinguished. A full mutation in the presence of mosaicism was also detectable by this method. Methylation-specific PCR appears to be a rapid and reliable tool for the diagnosis of fragile X males.

Polymorphic variation at the BAT-25 and BAT-26 loci in individuals of African origin. Implications for microsatellite instability testing

Instability in the repeat size of microsatellite sequences has been described in both hereditary nonpolyposis and sporadic colorectal cancers. Tumors expressing microsatellite instability are identified through the comparison of the repeat sizes at multiple microsatellite loci between tumor and matched normal tissue DNA. The use of a five-marker panel including two mononucleotide repeat microsatellites, BAT-25 and BAT-26, has recently been suggested for the clinical determination of tumor microsatellite instability. The BAT-25 and BAT-26 loci included in this panel have both demonstrated sensitivity to microsatellite instability and normal quasimonomorphic allelic patterns, which has simplified the distinction between normal and unstable alleles. However, in this study, we identified allelic variations in the size of the poly(A) tract at BAT-26 in 12.6% of 103 healthy African-Americans screened. In addition, 18.4% exhibited allelic size variations in the poly(T) tract at BAT-25. Finally, 2.9% showed variant alleles at both BAT-25 and BAT-26 loci. Screening a small population of Nigerians confirmed the polymorphic nature of both loci and the ethnic origin of alleles not identified in other populations studied thus far. Our results dispute the quasimonomorphic nature of both BAT-25 and BAT-26 in all populations and support the need for thorough population studies to define the different allelic profiles and frequencies at microsatellite loci.

A single nucleotide difference that alters splicing patterns distinguishes the SMA gene SMN1 from the copy gene SMN2

Spinal muscular atrophy (SMA) is a recessive disorder characterized by loss of motor neurons in the spinal cord. It is caused by mutations in the telomeric survival motor neuron 1 ( SMN1 ) gene. Alterations within an almost identical copy gene, the centromeric survival motor neuron 2 ( SMN2 ) gene produce no known phenotypic effect. The exons of the two genes differ by just two nucleotides, neither of which alters the encoded amino acids. At the genomic level, only five nucleotides that differentiate the two genes from one another have been reported. The entire genomic sequence of the two genes has not been determined. Thus, differences which might explain why SMN1 is the SMA gene are not readily apparent. In this study, we have completely sequenced and compared genomic clones containing the SMN genes. The two genes show striking similarity, with the homology being unprecedented between two different yet functional genes. The only critical difference in an approximately 32 kb region between the two SMN genes is the C->T base change 6 bp inside exon 7. This alteration but not other variations in the SMN genes affects the splicing pattern of the genes. The majority of the transcript from the SMN1 locus is full length, whereas the majority of the transcript produced by the SMN2 locus lacks exon 7. We suggest that the exon 7 nucleotide change affects the activity of an exon splice enhancer. In SMA patients, the loss of SMN1 but the presence of SMN2 results in low levels of full-length SMN transcript and therefore low SMN protein levels which causes SMA.

Prevalence of the factor VLeiden mutation among autopsy patients with pulmonary thromboembolic disease using an improved method for factor VLeiden detection

Activated protein C resistance caused by factor VLeiden mutation is the most common inherited predisposing cause of venous thromboembolism, including pulmonary embolism (PE). We studied whether the incidence of factor VLeiden is higher among patients with PE evident at autopsy than in the general population. Paraffin-embedded fixed tissue blocks from all autopsy patients with diagnosed pulmonary thromboembolic disease during a 4-year period were collected for DNA extraction. Extraction and molecular analysis of the DNA was performed with an improved technique with an internal control to determine the presence of factor VLeiden mutation. Analysis of 82 autopsy cases with PE yielded 5 patients who were heterozygotes. Seventy-seven of the 82 patients analyzed were normal, and no homozygotes for factor VLeiden mutation were identified. This yielded a positive rate of 6% overall and 7% among white patients, which is similar to the incidence of heterozygotes in the white population. This study indicates that routine determination of factor VLeiden mutation is not warranted for patients with PE diagnosed at autopsy.

Identification of MEN1 mutations in sporadic enteropancreatic neuroendocrine tumors by analysis of paraffin-embedded tissue

Gastrinomas and other gastrointestinal neuroendocrine tumors may occur sporadically or as part of the inherited syndrome multiple endocrine neoplasia type 1 (MEN1). Mutations in the recently identified MEN1 gene have been described in sporadic gastrinomas and insulinomas. This study describes techniques used to identify mutations in the MEN1 gene in DNA extracted from paraffin-preserved tissue. Two novel mutations are identified in the MEN1 gene from nine archived paraffin-embedded neuroendocrine tumors, demonstrating that retrospective genetic analysis can be used to identify mutations in the MEN1 gene from preserved tissue. Conditions are provided by which paraffin-embedded tissue can be used as a source of genetic material for sequence information of sufficient quality for mutational studies of the MEN1 gene. It should also be possible to apply this retrospective genetic analysis of paraffin-embedded tissue to other disease models.

The I1307K polymorphism of the APC gene in colorectal cancer

BACKGROUND & AIMS

Colorectal cancer is one of the most frequent cancers in humans. Recently, a germline missense mutation, I1307K, was identified in the adenomatous polyposis coli (APC) gene that was suggested to increase cancer predisposition in Ashkenazi Jews. However, a second study indicated that the I1307K mutation did not contribute greatly to the risk of colon cancer in Ashkenazi breast-ovarian cancer families, and a role of mismatch repair deficiency was suggested. This study investigated the frequency of the I1307K mutation in several non-Ashkenazi Jewish populations. We also compared the distribution and frequency of APC mutations from colon tumors that were positive and negative for the I1307K mutation. Finally, the association between the presence of mutations in the I1307K region and mismatch repair deficiency was studied.

METHODS

We tested for I1307K in 345 patients who were not Ashkenazi Jews using a heteroduplex screen. We also performed an extensive mutational analysis in this region of the APC gene on DNA extracted from 240 Italian, Finnish, and Hawaiian-Japanese colon tumors and determined replication error status.

RESULTS

The I1307K mutation was not found among 345 non-Ashkenazis. Somatic mutations occurred at a lower frequency and were more randomly distributed when the I1307K allele was not present. The most common characteristic somatic mutation occurring around codon 1307 in I1307K-positive patients did not occur in tumors negative for the I1307K mutation. An association between mutations in the region around APC codon 1307 and mismatch repair deficiency was not found.

CONCLUSIONS

Our findings support the hypothesis that the I1307K mutation is unique to the Ashkenazi Jews, contributes to tumor predisposition in colorectal cancer, and is unrelated to mismatch repair deficiency.

Intragenic telSMN mutations: frequency, distribution, evidence of a founder effect, and modification of the spinal muscular atrophy phenotype by cenSMN copy number

The autosomal recessive neuromuscular disorder proximal spinal muscular atrophy (SMA) is caused by the loss or mutation of the survival motor neuron (SMN) gene, which exists in two nearly identical copies, telomeric SMN (telSMN) and centromeric SMN (cenSMN). Exon 7 of the telSMN gene is homozygously absent in approximately 95% of SMA patients, whereas loss of cenSMN does not cause SMA. We searched for other telSMN mutations among 23 SMA compound heterozygotes, using heteroduplex analysis. We identified telSMN mutations in 11 of these unrelated SMA-like individuals who carry a single copy of telSMN: these include two frameshift mutations (800ins11 and 542delGT) and three missense mutations (A2G, S262I, and T274I). The telSMN mutations identified to date cluster at the 3' end, in a region containing sites for SMN oligomerization and binding of Sm proteins. Interestingly, the novel A2G missense mutation occurs outside this conserved carboxy-terminal domain, closely upstream of an SIP1 (SMN-interacting protein 1) binding site. In three patients, the A2G mutation was found to be on the same allele as a rare polymorphism in the 5' UTR, providing evidence for a founder chromosome; Ag1-CA marker data also support evidence of an ancestral origin for the 800ins11 and 542delGT mutations. We note that telSMN missense mutations are associated with milder disease in our patients and that the severe type I SMA phenotype caused by frameshift mutations can be ameliorated by an increase in cenSMN gene copy number.

Identification of a missense mutation in a Friedreich's ataxia patient: implications for diagnosis and carrier studies

Approximately 95% of all Friedreich's ataxia (FA) patients are homozygous for a large GAA triplet-repeat expansion in the first intron of the Friedreich's ataxia gene (FRDA). The remaining cases are expected to be compound heterozygous with a GAA expansion on one allele and a point mutation on the other. Generally, the clinical diagnostic profile in this group of patients is indistinguishable from that in classic FA patients with homozygous expansions. This study describes a mildly affected patient who presents with only one expanded allele by Southern blot analysis. Point mutation screening shows a single base change in FRDA exon 3 resulting in a nonconservative amino acid replacement in the N-terminal portion of the frataxin protein. Extended family studies show that two of the patient's sibs are carriers of the expanded allele and one is a carrier of the missense mutation. This case study demonstrates the benefits of implementing a combined Southern blot and point mutation diagnostic protocol for compound heterozygous patients. By identifying both mutations, this procedure confirms the diagnosis of FA in patients with an atypical disease course and allows for more complete family studies.

Diagnosis of spinal muscular atrophy in an SMN non-deletion patient using a quantitative PCR screen and mutation analysis

We report a child with clinical findings consistent with Werdnig-Hoffmann disease (spinal muscular atrophy type I) who was found not to have the homozygous absence of the survival motor neurone (SMN(T)) gene observed in approximately 95% of spinal muscular atrophy patients. A quantitative PCR based dosage assay for SMN(T) copy number showed that this patient possessed a single copy of the SMN(T) gene. Heteroduplex and sequence analysis of the remaining copy of SMN(T) showed a 2 base pair deletion within exon 4 which produces a frameshift and premature termination of the deduced SMN(T) protein. This protocol of initial SMN(T) gene dosage analysis followed by mutation detection allows identification of SMA compound heterozygotes (patients lacking one copy of SMN(T) and having another mutation in their other copy), thereby increasing the sensitivity of SMA molecular diagnosis.

Differential diagnosis of hereditary hemochromatosis from other liver disorders by genetic analysis: gene mutation analysis of patients previously diagnosed with hemochromatosis by liver biopsy

BACKGROUND

Hereditary hemochromatosis, a common autosomal recessive trait caused by mutations in the HLA-H gene, is often diagnosed by the pathologist at the time of histologic examination. Unfortunately, histologic parameters alone do not differentiate between hereditary hemochromatosis and other causes of iron overload. We performed a retrospective study to determine the frequency of familial hemochromatosis in patients diagnosed with he mochromatosis by abnormal liver histology.

METHODS AND RESULTS

DNA was isolated from paraffin-embedded tissue sections from 15 patients and used in a polymerase chain reaction-based assay in which we tested for the C282Y and H63D mutations. We found that in this group of patients, 5 (33%) were homozygous for the common C282Y genetic mutation, 3 (20%) were heterozygous, and 7 (47%) were normal.

CONCLUSIONS

Our study shows that the molecular assay is the gold standard for the diagnosis of hereditary hemochromatosis. The case study also illustrates that a definitive diagnosis of familial hemochromatosis has significant counseling implications allowing for accurate family studies.

Detection of viral DNA in vestibular ganglia tissue from patients with Menière's disease

OBJECTIVE

The main goal of this study was to examine the vestibular ganglia from 11 patients with intractable classic Menière's disease (MD) for the presence or absence of DNA from three neurotropic viruses (herpes simplex virus, cytomegalovirus, and varicella zoster virus) using exquisitely sensitive molecular biologic techniques.

STUDY DESIGN

This was a prospective controlled study with vestibular ganglia from patients with MD and from patients with small vestibular schwannomas undergoing resection. Polymerase chain reaction was used for viral DNA detection from the ganglia along with known positive and negative polymerase chain reaction control subjects.

SETTING

The study was performed in an academic tertiary referral center.

PATIENTS

Patients for inclusion had medically uncontrolled MD, including documented fluctuating sensorineural hearing loss, episodic vertigo, and tinnitus who elected to undergo vestibular nerve section. Control patients were undergoing vestibular schwannoma removal.

INTERVENTIONS

The intervention was vestibular nerve section with removal of vestibular ganglion.

MAIN OUTCOME MEASURES

The presence or absence of viral DNA (herpes simplex virus, cytomegalovirus, and varicella zoster virus) in vestibular ganglion tissues detected by polymerase chain reaction.

RESULTS

No viral DNA was detected in the vestibular ganglia of patients with MD (p = 0.028) nor in the control group. The likelihood of a type II or beta type error was < 10%.

CONCLUSIONS

In patients with MD requiring surgical intervention, infection with herpes simplex virus, cytomegalovirus, or varicella zoster virus of the vestibular ganglia does not appear to play a major role in the pathoetiology of the disease.

Issues related to DNA testing for Huntington's disease in symptomatic patients

The DNA test for Huntington's disease simplifies diagnosis, but does not eliminate clinical and ethical issues. Records of 80 consecutive patients who had testing were reviewed; 54 had a positive result. We present seven examples of the variety of problems disclosed by our review. Among the issues that remain unsettled are: (1) Who should do needed counseling and how much? (2) When, if ever, is presymptomatic testing for this incurable disease indicated? (3) Should the patient have access to information about the length of repeats, as the age of onset is affected by the length of repeat? (4) Is it true that insurance companies or relatives have no right to learn the results of DNA testing on a patient?

Molecular diagnosis of non-deletion SMA patients using quantitative PCR of SMN exon 7

The telomeric survival motor neuron (SMN(T)) gene is a valuable molecular diagnostic tool for childhood-onset spinal muscular atrophy (SMA) as homozygous deletions of SMN(T) exon 7 (delta7SMN(T)) are present in approximately 94% of patients. In this report, we provide the first comprehensive study of 32 unrelated non-deletion SMA patients. Quantitative polymerase chain reaction (PCR) studies established that 90% had two intact copies of SMN(T) exon 7 suggesting that these patients do not have 5q SMA. Once 5q SMA is confirmed, the SMN(T) gene can be screened for subtle mutations. Using single strand conformation analysis, we identified two missense mutations (P245L and Y272C) in exon 6 of the SMN(T) gene of two SMA patients shown to have a single copy of SMN(T) exon 7. Y272 is most likely critical for SMN(T) function as it is a target for recurring mutations and is associated with type I SMA. These results emphasize the need for dosage analysis in the differential diagnosis of 5q SMA in nondeletion patients, consistent with extensive clinical heterogeneity and some genetic heterogeneity in this disease. Homozygosity or heterozygosity for a delta7SMN(T) allele confirms the diagnosis of 5q SMA with greater precision than clinical examination alone.

The survival motor neuron protein in spinal muscular atrophy

The 38 kDa survival motor neuron (SMN) protein is encoded by two ubiquitously expressed genes: telomeric SMN (SMN(T)) and centromeric SMN (SMN(C)). Mutations in SMN(T), but not SMN(C), cause proximal spinal muscular atrophy (SMA), an autosomal recessive disorder that results in loss of motor neurons. SMN is found in the cytoplasm and nucleus. The nuclear form is located in structures termed gems. Using a panel of anti-SMN antibodies, we demonstrate that the SMN protein is expressed from both the SMN(T) and SMN(C) genes. Western blot analysis of fibroblasts from SMA patients with various clinical severities of SMA showed a moderate reduction in the amount of SMN protein, particularly in type I (most severe) patients. Immunocytochemical analysis of SMA patient fibroblasts indicates a significant reduction in the number of gems in type I SMA patients and a correlation of the number of gems with clinical severity. This correlation to phenotype using primary fibroblasts may serve as a useful diagnostic tool in an easily accessible tissue. SMN is expressed at high levels in brain, kidney and liver, moderate levels in skeletal and cardiac muscle, and low levels in fibroblasts and lymphocytes. In SMA patients, the SMN level was moderately reduced in muscle and lymphoblasts. In contrast, SMN was expressed at high levels in spinal cord from normals and non-SMA disease controls, but was reduced 100-fold in spinal cord from type I patients. The marked reduction of SMN in type I SMA spinal cords is consistent with the features of this motor neuron disease. We suggest that disruption of SMN(T) in type I patients results in loss of SMN from motor neurons, resulting in the degeneration of these neurons.

Identification of proximal spinal muscular atrophy carriers and patients by analysis of SMNT and SMNC gene copy number

The survival motor neuron (SMN) transcript is encoded by two genes, SMNT and SMNC. The autosomal recessive proximal spinal muscular atrophy that maps to 5q12 is caused by mutations in the SMNT gene. The SMNT gene can be distinguished from the SMNC gene by base-pair changes in exons 7 and 8. SMNT exon 7 is not detected in approximately 95% of SMA cases due to either deletion or sequence-conversion events. Small mutations in SMNT now have been identified in some of the remaining nondeletion patients. However, there is no reliable quantitative assay for SMNT, to distinguish SMA compound heterozygotes from non-5q SMA-like cases (phenocopies) and to accurately determine carrier status. We have developed a quantitative PCR assay for the determination of SMNT and SMNC gene-copy number. This report demonstrates how risk estimates for the diagnosis and detection of SMA carriers can be modified by the accurate determination of SMNT copy number.

Dystrophin expression in a Duchenne muscular dystrophy patient with a frame shift deletion

The exon 45 deletion is a common dystrophin gene deletion. Although this is an out-of-frame deletion, which should not allow for protein synthesis, it has been observed in mildly affected patients. We describe a patient with an exon 45 deletion who produced protein, but still had a severe Duchenne muscular dystrophy phenotype. RT-PCR analysis and cDNA sequencing from the muscle biopsy sample revealed that the exon 45 deletion induced exon skipping of exon 44, which resulted in an in-frame deletion and the production of dystrophin. A conformational change in dystrophin induced by the deletion is proposed as being responsible for the severe phenotype in the patient. We feel that the variable clinical phenotype observed in patients with the exon 45 deletion is not due to exon splicing but may be the result of other environmental or genetic factors, or both.

Deletion and conversion in spinal muscular atrophy patients: is there a relationship to severity?

The spinal muscular atrophy-determining gene, survival motor neuron (SMN), is present in two copies, telSMN and cenSMN, which can be distinguished by base-pair changes in exons 7 and 8. The telSMN gene is often absent in spinal muscular atrophy patients, which could be due to deletion or sequence conversion (telSMN conversion to cenSMN giving rise to two cenSMN genes). To test for conversion events in spinal muscular atrophy, we amplified a 1-kb fragment that spanned exons 7 and 8 of SMN from 5 patients who retained telSMN exon 8 but lacked exon 7. In all patients, sequence analysis demonstrated that cenSMN exon 7 was adjacent to telSMN exon 8, indicating conversion. All 5 patients with this mutation had type II or III spinal muscular atrophy, strongly supporting an association with chronic spinal muscular atrophy. We also identified 3 families in which 2 siblings had no detectable telSMN but presented with markedly different phenotypes. We suggest that sequence conversion is a common event in spinal muscular atrophy and is associated with the milder form of the disease. The severity, however, can be modified in either a positive or negative direction by other factors that influence splicing or expression of the sequence converted SMN gene.

An 11 base pair duplication in exon 6 of the SMN gene produces a type I spinal muscular atrophy (SMA) phenotype: further evidence for SMN as the primary SMA-determining gene

The gene for autosomal recessive spinal muscular atrophy (SMA) has been mapped to 5q12 in a region that contains repeated markers and genes. Three cDNAs that detect deletions in SMA patients have been reported. One of these, the survival motor neuron (SMN) cDNA, is encoded by two genes (SMNT and SMNC) which are distinguished by base changes in exons 7 and 8. Exon 7 of the SMNT gene is not detectable in approximately 95% of SMA cases, due either to deletion or sequence conversion. There is limited information on the mutations in SMA patients that have detectable SMNT, these are critical for confirmation of SMNT as the SMA gene. Using SSCP analysis of the SMN exons we screened our SMA patients that possess at least one intact SMNT allele for mutations in SMNT. We identified one type I SMA patient with an 11 bp duplication in exon 6 which causes a frameshift and premature termination of the deduced SMNT protein. Dosage and SSCP analysis of SMNT in this family indicated that the father contributed a SMNT-deleted allele to the affected child whereas the mother passed on the 11 bp exon 6 duplication SMNT allele. Analysis of RNA by RT-PCR conclusively demonstrated that the 11 bp duplication is associated with the SMNT locus and not SMNC. This mutation provides strong support for SMN as the SMA-determining gene and indicates that disruption of SMNT on its own is sufficient to produce a severe type I SMA phenotype.

Mutational spectrum in the neurofibromatosis type 2 gene in sporadic and familial schwannomas

Using a heteroduplex approach and direct sequencing, we have completed the screening of approximately 88% of the neurofibromatosis type 2 (NF2)-coding sequence of DNA extracted from 33 schwannomas from NF2 patients and from 29 patients with sporadic schwannomas. The extensive screening has resulted in the identification of 33 unique mutations. Similarly to other human genes, we have shown that the CpG sites are more highly mutable in the NF2 gene. The frequency, distribution, and types of mutations were shown to differ between the sporadic and familial tumors. The majority of the mutations resulted in protein truncation and were consistent with more severe phenotype, however three missense mutations were identified during this study and were all associated with milder manifestations of the disease.

The incidence of the gene for thermolabile methylene tetrahydrofolate reductase in African Americans

Increased levels of homocysteine have been linked to both arterial and venous thromboembolic problems (1,2). Homocystinuria is a relatively rare disorder caused by a deficiency of cystathione synthase and is characterized by markedly increased levels of homocysteine and premature vascular disease (3-5). Epidemiological studies have suggested that mild elevations of homocysteine are also associated with vascular disease (2). Recent evidence suggests that a polymorphism of the gene encoding for 5,10-methylene tetrahydrofolate reductase (MTHFR) gives rise to a thermolabile form of the enzyme that is associated with increased levels of homocysteine when inherited as a homozygous trait (6). This polymorphism is due to a C --> T substitution at nucleotide 677 which converts an alanine to valine in a conserved portion of the molecule (6). The allele frequency for the thermolabile form of the enzyme was quite high (0.38) in a population of French Canadians. This polymorphism thus appears to be a common risk factor for increased plasma levels of homocysteine and vascular diseases. As the incidence of such genetic polymorphisms often varies among ethnic populations, we were interested in comparing the incidence of this polymorphism in Caucasians and African Americans.

A novel splice site mutation in a Becker muscular dystrophy patient

A Becker muscular dystrophy patient was found to have a single base substitution at the 5' end of intron 54. This single base substitution disrupts the invariant GT dinucleotide within the 5' donor splice site and was shown to cause an out of frame deletion of exon 54 during mRNA processing. This is predicted to produce a truncated dystrophin protein which is more consistent with a DMD phenotype. However, small quantities of normal mRNA are also transcribed and these are sufficient to produce a reduced amount of normal molecular weight dystrophin and give rise to a milder BMD phenotype. This indicates that a single base substitution at an invariant dinucleotide of the splice site consensus sequence may still allow read through of the message and allow the production of some normal protein. This shows that there are a greater number of possible intronic mutations that can lead to a mild phenotype and it also underlines the importance of performing cDNA analysis when screening for small gene alterations in the BMD patient population.

Perspectives and molecular diagnosis of Duchenne and Becker muscular dystrophies

Molecular genetic understanding of Duchenne and Becker muscular dystrophies has unfolded rapidly in the past decade. The new molecular understanding has enhanced diagnosis, prognosis, carrier detection, and prenatal diagnosis. Most importantly, strategies are being devised currently for the treatment of the disorder. This article provides an update on the molecular findings and their applicability in clinical practice.

Myoblast transfer in the treatment of Duchenne's muscular dystrophy

BACKGROUND

Myoblast transfer has been proposed as a technique to replace dystrophin, the skeletal-muscle protein that is deficient in Duchenne's muscular dystrophy. Donor myoblasts injected into muscles of affected patients can fuse with host muscle fibers, thus contributing their nuclei, which are potentially capable of replacing deficient gene products. Previous controlled trials involving a single transfer of myoblasts have been unsuccessful.

METHODS

We injected donor muscle cells once a month for six months to the biceps brachii muscles of one arm of each of 12 boys with Duchenne's muscular dystrophy. The opposite arms served as sham-injected controls. In each procedure 110 million cells donated by fathers or brothers were transferred. The patients were randomly assigned to receive either cyclosporine or placebo. Strength was measured by quantitative isometric muscle testing. Six months after the final myoblast transfer, the presence of dystrophin was assessed with the use of peptide antibodies specific to the deleted exons of the dystrophin gene.

RESULTS

There was no significant difference in muscle strength between arms injected with myoblasts and sham-injected arms. In one patient, 10.3 percent of muscle fibers expressed donor-derived dystrophin after myoblast transfer. Three other patients also had a low level of donor dystrophin (< 1 percent); eight had none.

CONCLUSIONS

Myoblasts transferred once a month for six months failed to improve strength in patients with Duchenne's muscular dystrophy. The value of exon-specific peptide antibodies in the interpretation of myoblast-transfer results was demonstrated in a patient with Duchenne's muscular dystrophy who had a high percentage of donor-derived dystrophin. Specific variables affecting the efficiency of myoblast transfer need to be identified in order to improve upon this technique.

Spectrum of small mutations in the dystrophin coding region

Duchenne and Becker muscular dystrophies (DMD and BMD) are caused by defects in the dystrophin gene. About two-thirds of the affected patients have large deletions or duplications, which occur in the 5' and central portion of the gene. The nondeletion/duplication cases are most likely the result of smaller mutations that cannot be identified by current diagnostic screening strategies. We screened approximately 80% of the dystrophin coding sequence for small mutations in 158 patients without deletions or duplications and identified 29 mutations. The study indicates that many of the DMD and the majority of the BMD small mutations lie in noncoding regions of the gene. All of the mutations identified were unique to single patients, and most of the mutations resulted in protein truncation. We did not find a clustering of small mutations similar to the deletion distribution but found > 40% of the small mutations 3' of exon 55. The extent of protein truncation caused by the 3' mutations did not determine the phenotype, since even the exon 76 nonsense mutation resulted in the severe DMD phenotype. Our study confirms that the dystrophin gene is subject to a high rate of mutation in CpG sequences. As a consequence of not finding any hotspots or prevalent small mutations, we conclude that it is presently not possible to perform direct carrier and prenatal diagnostics for many families without deletions or duplications.

The childhood muscular dystrophies: diseases sharing a common pathogenesis of membrane instability

New observations demonstrate that several childhood forms of muscular dystrophy share a common pathogenesis. In muscle, dystrophin occurs as part of a membrane complex (dystrophin-glycoprotein) linking the cytoskeleton to the basal lamina. In Duchenne muscular dystrophy, dystrophin deficiency disrupts the linkage of the integral glycoproteins of the sarcolemma and leads to muscle fiber necrosis. In severe childhood autosomal recessive muscular dystrophy, a selective deficiency of adhalin (50-kd glycoprotein) also causes dysfunction of the dystrophin-glycoprotein complex. Most recently, a form of congenital muscular dystrophy demonstrates deficiency of laminin M (merosin) further demonstrating that sarcolemmal instability results from defects in structural proteins of the basal lamina. Animal models have been identified also demonstrating defects in specific proteins linking the subsarcolemmal cytoskeleton to the extracellular matrix. The mdx mouse has a defect in the gene encoding dystrophin. The cardiomyopathic hamster shows a specific deficiency of adhalin in skeletal muscle. The dy/dy mouse has been found deficient in merosin. These animal models will help researchers to understand their human counterparts and provide a system for testing therapeutic strategies.

Germline mosaicism at the fragile X locus

We have identified a fragile X syndrome pedigree where the disorder is associated with a molecular deletion. The deletion was present in the DNA of 2 sons but was absent in the mother's somatic cell (lymphocyte) DNA. The results are consistent with the deletion arising as a postzygotic event in the mother, who therefore is germinally mosaic. This finding has important implications for counseling fragile X families with deletion mutations.