Homozygous deletion of the survival motor neuron 2 gene is a prognostic factor in sporadic ALS.

BACKGROUND: Spinal muscular atrophy (SMA) results from mutations of the survival motor neuron (SMN) gene on chromosome 5. The SMN gene exists in two highly homologous copies, telomeric (SMN1) and centromeric (SMN2). SMA is caused by mutations in SMN1 but not SMN2. The clinical phenotype of SMA appears to be related to the expression of SMN2. Patients suffering from the milder forms of SMA carry more copies of the SMN2 gene compared with patients with more severe SMA. It is suggested that the SMN2 gene is translated into an at least partially functional protein that protects against loss of motor neurons. OBJECTIVE: To investigate whether genetic mechanisms implicated in motor neuron death in SMA have a role in ALS. METHODS: The presence of deletions of exons 7 and 8 of SMN1 and SMN2 was determined in 110 patients with sporadic ALS and compared with 100 unaffected controls. RESULTS: The presence of a homozygous SMN2 deletion was overrepresented in patients with ALS compared with controls (16% versus 4%; OR, 4.4; 95% CI, 1.4 to 13.5). Patients with a homozygous SMN2 deletion had a shorter median time of survival (p < 0.009). Furthermore, multivariate regression analysis showed that the presence of an SMN2 deletion was independently associated with survival time (p < 0.02). No homozygous deletions in SMN1 were found. Carrier status of SMA appeared to be equally present in patients and controls (1 in 20). CONCLUSION: These results indicate that, similar to SMA, the SMN2 gene can act as a prognostic factor and may therefore be a phenotypic modifier in sporadic ALS. Increasing the expression of the SMN2 gene may provide a strategy for treatment of motor neuron disease.

RET and GDNF gene scanning in Hirschsprung patients using two dual denaturing gel systems.

Hirschsprung disease (HSCR) is a congenital disorder characterised by intestinal obstruction due to an absence of intramural ganglia along variable lengths of the intestine. RET is the major gene involved in HSCR. Mutations in the GDNF gene, and encoding one of the RET ligands, either alone or in combination with RET mutations, can also cause HSCR, as can mutations in four other genes (EDN3, EDNRB, ECE1, and SOX10). The rare mutations in the latter four genes, however, are more or less restricted to HSCR associated with specific phenotypes. We have developed a novel comprehensive mutation detection system to analyse all but three amplicons of the RET and GDNF genes, based on denaturing gradient gel electrophoresis. We make use of two urea-formamide gradients on top of each other, allowing mutation detection over a broad range of melting temperatures. For the three remaining (GC-rich) PCR fragments we use a combination of DGGE and constant denaturing gel electrophoresis (CDGE). These two dual gel systems substantially facilitate mutation scanning of RET and GDNF, and may also serve as a model to develop mutation detection systems for other disease genes. In a screening of 95 HSCR patients, RET mutations were found in nine out of 17 familial cases (53%), all containing long segment HSCR. In 11 of 78 sporadic cases (14%), none had long segment HSCR. Only one GDNF mutation was found, in a sporadic case.

SMA carrier testing--validation of hemizygous SMN exon 7 deletion test for the identification of proximal spinal muscular atrophy carriers and patients with a single allele deletion.

To facilitate the detection of carriers of a hemizygous survival motor neuron (SMN) exon 7 deletion we have modified the quantitative SMN exon 7 assay described by McAndrew et al (1997). The major changes include quantitative analysis of the amount of SMN exon 7-specific fluorescently-labelled PCR product on an automated sequencer, and the monitoring of the completeness of a DraI digestion necessary to distinguish the PCR products of exons 7 of SMN and its copy gene. In our method the amount of SMN exon 7 PCR product is compared with the amount of a co-amplified PCR product of the retinoblastoma (RB1) exon containing a DraI restriction site. By co-amplification using the same primers of plasmids included in the reaction as internal standards containing SMN exon 7 with a 36-nucleotide deletion and RB1 exon 13 with a 19-nucleotide deletion, respectively, the relative amplification efficacy can be monitored. The assay has been validated in 63 ascertained carriers and 28 ascertained non-carriers. The sensitivity of the test is approximately 97%, the specificity approaches 100%. In four out of six SMA patients without a homozygous deletion we detected a hemizygous deletion. The implications of the use of this assay for carrier testing and for confirmation of the clinical diagnosis of SMA are discussed.

Improved mutation detection in GC-rich DNA fragments by combined DGGE and CDGE.

Denaturing gradient gel electrophoresis (DGGE) has proven to be a powerful pre-screening method for the detection of DNA variants. If such variants occur, however, in DNA fragments that are very rich in G and C, they may escape detection. To overcome this limitation, we tested a novel gel system which combines DGGE and constant denaturant gel electrophoresis (CDGE), as it might have the advantages of both methods. Indeed, this combination had the advantages of both methods, good separation of hetero-duplex molecules and prevention of total strand dissociation, and it proved successful in the detection of DNA variants in several GC-rich fragments.

Three novel KCNA1 mutations in episodic ataxia type I families.

Hereditary paroxysmal ataxia, or episodic ataxia (EA), is a rare, genetically heterogeneous neurological disorder characterized by attacks of generalized ataxia. By direct sequence analysis, a different missense mutation of the potassium channel gene (KCNA1) has been identified in three families with EA.

Absence of mutations in the RET gene in acute myeloid leukemia.

Expression of the tyrosine kinase receptor RET has previously been detected in normal hematopoietic cells, and especially in cells of the myeloid lineage. Furthermore, RET was shown to be differentially expressed in acute myeloid leukemia (AML), a disease characterized by excessive cell growth and aberrant maturation of cells, with the highest levels of expression in leukemias with monocytic differentiation. RET is known to be expressed in cells from the excretory system and from the developing central and peripheral nervous system. Both activating and inactivating aberrations in the RET gene have been detected in disorders derived from these tissues. To investigate whether the differential expression is a primary defect in AML, the presence of RET alterations was scanned by Southern blot analysis on DNA of blasts obtained from 17 AML patients. However, no RET gene aberrations were found. Subsequently, denaturing gradient gel electrophoresis (DGGE) analysis was performed on the DNA of blasts from ten selected cases. All five variants detected turned out to represent neutral DNA polymorphisms, including a novel polymorphism in exon 14. Since we were unable to detect mutations of RET in AML, it is unlikely that it plays an important role in leukemogenesis.

Implications of intragenic marker homozygosity and haplotype sharing in a rare autosomal recessive disorder: the example of the collagen type XVII (COL17A1) locus in generalised atrophic benign epidermolysis bullosa.

Generalised atrophic benign epidermolysis bullosa (GABEB) is a form of junctional epidermolysis bullosa with a recessive mode of inheritance. The gene considered likely to be involved in this disease is COL17A1, since in the majority of GABEB patients the product of that gene, the 180-kD bullous pemphigoid antigen (BP180), is undetectable in skin. We have identified an intragenic COL17A1 microsatellite marker for which 83% of randomly selected control individuals are heterozygous. We observed homozygosity for different alleles of this marker in five out of six collagen type XVII-negative GABEB patients of different European descent. Five of the six COL17A1 alleles of three patients originating from the eastern part of the Netherlands were identical, as were the haplotypes including flanking markers. The 2342delG mutation was identified in all these five alleles. This confirms the expectation that due to genetic drift and hidden inbreeding for an autosomal recessive disorder with low gene frequency, such as collagen type XVII-negative GABEB, most disease alleles from a restricted geographical area will be "identical by descent". Our results demonstrate that involvement of a candidate gene can be confirmed by looking for identity by descent of highly informative intragenic markers.

Revertant mosaicism in epidermolysis bullosa caused by mitotic gene conversion.

Mitotic gene conversion acting as reverse mutation has not been previously demonstrated in human. We report here that the revertant mosaicism of a compound heterozygous proband with an autosomal recessive genodermatosis, generalized atrophic benign epidermolysis bullosa, is caused by mitotic gene conversion of one of the two mutated COL17A1 alleles. Specifically, the maternal allele surrounding the mutation site on COL17A1 (1706delA) showed reversion of the mutation and loss of heterozygosity along a tract of at least 381 bp in revertant keratinocytes derived from clinically unaffected skin patches; the paternal mutation (R1226X) remained present in all cell samples. Revertant mosaicism represents a way of natural gene therapy.

RET mutation screening in familial cutaneous lichen amyloidosis and in skin amyloidosis associated with multiple endocrine neoplasia.

In several families, multiple endocrine neoplasia type 2A (MEN 2A) has been found in association with cutaneous lichen amyloidosis. It has been debated, however, whether the skin amyloidosis found in MEN 2A families, localized exclusively in the interscapular area, represents the same anomaly as that found in autosomal dominant familial cutaneous lichen amyloidosis, which is more generalized. We screened two MEN 2A families with associated skin amyloidosis for germline mutations in the RET gene responsible for the MEN 2A cancer syndrome, and found the same mutation characteristic of MEN 2A in both families. We also screened probands from three pedigrees with familial cutaneous lichen amyloidosis for RET mutations. In none of the RET coding and flanking intronic sequences was a mutation detected. This most probably indicates that skin amyloidosis found in some MEN 2A families and familial cutaneous lichen amyloidosis are different conditions. Consequently, patients with apparent familial cutaneous lichen amyloidosis do not appear to be at risk for MEN 2A.

Extensive mutation scanning of RET in sporadic medullary thyroid carcinoma and of RET and VHL in sporadic pheochromocytoma reveals involvement of these genes in only a minority of cases.

Sporadic medullary thyroid carcinoma (MTC) and pheochromocytoma (PC) have been reported to be associated with some specific RET gene mutations. To assess the role of RET in the development of MTC and PC, we screened 14 sporadic MTC, two MTC-derived cell lines, and 5 sporatic PC cases of RET mutations by a systematic analysis of the whole coding sequence, including all intron-exon junctions. In only 6 of the 14 sporadic MTC we were able to detect a RET mutation. Apart from the MET918-->Thr mutation in 5 of the MTC cases, we found a 3-bp deletion in exon 11, only present in the tumor, in another case. Analysis of 2 cell lines revealed the Met918-->Thr mutation in 1 and a Cys634-->Trp mutation in the other cell line. A possible somatic nature of these mutations could not be confirmed because in neither case was constitutive DNA available. We conclude that a large proportion of sporadic MTC must be due to mutations in an unidentified gene(s) other than RET. In none of the sporadic PC cases was a RET mutation found. As PC is a frequent complication in families suffering from von Hippel Lindau disease, for which mutations of the VHL gene are responsible, we also screened the 5 sporadic PC cases for VHL mutations. This revealed a Gly164-->Ser mutation in a single specimen. Thus, in PC, a large majority of tumors are due to mutations in an unidentified gene(s) other than RET and VHL.

A homozygous mutation in the endothelin-3 gene associated with a combined Waardenburg type 2 and Hirschsprung phenotype (Shah-Waardenburg syndrome).

Hirschsprung disease (HSCR) or colonic aganglionosis is a congenital disorder characterized by an absence of intramural ganglia along variable lengths of the colon resulting in intestinal obstruction. The incidence of HSCR is 1 in 5,000 live births. Mutations in the RET gene, which codes for a receptor tyrosine kinase, and in EDNRB which codes for the endothelin-B receptor, have been shown to be associated with HSCR in humans. The lethal-spotted mouse which has pigment abnormalities, but also colonic aganglionosis, carries a mutation in the gene coding for endothelin 3 (Edn3), the ligand for the receptor protein encoded by EDNRB. Here, we describe a mutation of the human gene for endothelin 3 (EDN3), homozygously present in a patient with a combined Waardenburg syndrome type 2 (WS2) and HSCR phenotype (Shah-Waardenburg syndrome). The mutation, Cys159Phe, in exon 3 in the ET-3 like domain of EDN3, presumably affects the proteolytic processing of the preproendothelin to the mature peptide EDN3. The patient's parents were first cousins. A previous child in this family had been diagnosed with a similar combination of HSCR, depigmentation and deafness. Depigmentation and deafness were present in other relatives. Moreover, we present a further indication for the involvement of EDNRB in HSCR by reporting a novel mutation detected in one of 40 unselected HSCR patients.

No mutations found by RET mutation scanning in sporadic and hereditary neuroblastoma.

Neuroblastoma occasionally occurs in diseases associated with abnormal neurocrest differentiation, e.g. Hirschsprung disease. Expression studies in developing mice suggest that the proto-oncogene RET plays a role in neurocrest differentiation. In humans expression of RET is limited to certain tumor types, including neuroblastoma, that derive from migrating neural crest cells. Mutations of RET are found associated with Hirschsprung disease. These data prompted us to investigate expression of RET and to search for gene mutations in neuroblastoma. Out of 16 neuroblastoma cell lines analyzed, 9 show clear expression of RET in a Northern blot analysis. In a single strandt conformation polymorphism (SSCP) analysis of all exons, no mutations were detected other than neutral polymorphisms. In a patient with neuroblastoma, from a family in which different neurocrestopathies, including neuroblastoma and Hirschsprung disease, had occurred, we also failed to detect RET mutations. Possibly, expression of RET in neuroblastoma merely reflects the differentiation status of the tumor cells. The absence of mutations suggests that RET does not play a crucial role in the tumorigenesis of neuroblastoma.

Hereditary myokymia and paroxysmal ataxia linked to chromosome 12 is responsive to acetazolamide.

A sixth family with autosomal dominantly inherited myokymia and paroxysmal ataxia is described. The syndrome in this family is linked to the recently discovered locus for inherited myokymia and paroxysmal ataxia on the human chromosome 12p, and a missense mutation is shown in the KCNA1 gene. The attacks of ataxia in this family compare well with those of previously described families and similarly are precipitated by kinesigenic stimuli, exertion, and startle. Responsiveness of these attacks to low dose acetazolamide is confirmed, but some loss of efficacy occurs with prolonged treatment, and side effects are notable. Although not all affected family members showed myokymia on clinical examination, electromyography invariably showed myokymic discharges, in one patient only after a short provocation with regional ischaemia. One affected family member also had attacks of paroxysmal kinesigenic choreoathetosis, responsive to carbamazepine.

DNA polymorphisms and conditions for SSCP analysis of the 20 exons of the ret proto-oncogene.

Recently identified mutations affecting different domains of the RET proto-oncogene are associated with Multiple Endocrine Neoplasia type 2A (MEN 2A) and type 2B (MEN 2B), familial and sporadic Medullary Thyroid Carcinomas (MTC) and Hirschsprung disease (HSCR). In order to facilitate the screening for RET mutations, and to study possible genotype-phenotype correlations, we established exon-intron junctions and extended the intronic sequences flanking the 20 exons of this gene. This made it possible to design primers and to develop PCR conditions useful for SSCP analysis of the whole RET coding sequence. Nine conformational variants were observed which after sequencing turned out to be 8 silent mutations and a conservative amino acid substitution. Restriction analysis performed on DNA samples from unrelated controls confirmed the polymorphic nature of six of these nucleotide changes and made it possible to estimate the frequency of the corresponding alleles.

A mutation in the RET proto-oncogene associated with multiple endocrine neoplasia type 2B and sporadic medullary thyroid carcinoma.

Multiple endocrine neoplasia type 2 (MEN 2) comprises three clinically distinct, dominantly inherited cancer syndromes. MEN 2A patients develop medullary thyroid carcinoma (MTC) and phaeochromocytoma. MEN 2B patients show in addition ganglioneuromas of the gastrointestinal tract and skeletal abnormalities. In familial MTC, only the thyroid is affected. Germ-line mutations of the RET proto-oncogene have recently been reported in association with MEN 2A and familial MTC. All mutations occurred within codons specifying cysteine residues in the transition point between the RET protein extracellular and transmembrane domains. We now show that MEN 2B is also associated with mutation of the RET proto-oncogene. A mutation in codon 664, causing the substitution of a threonine for a methionine in the tyrosine kinase domain of the protein, was found in all nine unrelated MEN 2B patients studied. The same mutation was found in six out of 18 sporadic tumours.

Analysis of a metastasizing testicular mixed gonadal stromal tumor with osteosarcoma components suggests that a malignant tumor with the histology of osteosarcoma may develop without primary involvement of RB1 and TP53.

A malignant stromal tumor of the testis with an osteosarcoma component and five of its metastases mainly containing osteosarcoma have been analyzed for RB1 and TP53 abnormalities. Whereas in the primary tumor and in some of the metastases loss of heterozygosity could not be detected for RB1 or for the 17p13 region in which TP53 is located, other metastases showed such losses of heterozygosity. By polymerase chain reaction analysis an 18-base pair deletion from exon 5 of the TP53 gene was found in a small proportion of primary tumor cells and in one of the metastases, but not in the other metastases. Therefore, in this case neither RB1 nor TP53 seems to play an essential role in the initiation of osteosarcoma.