Detection of a CfoI polymorphism within exon 5 of the human neuronal nicotinic acetylcholine receptor α4 subunit gene (CHRNA4)

The gene coding for the 4 subunit of the neuronal nicotinic acetylcholine receptor (CHRNA4) has been recently mapped in the candidate region for benign familial neonatal convulsions (BFNC) on chromosome 20q13.2–q13.3. The region is only partially covered with polymorphic markers, and so far no PCR-based polymorphisms have been described in the critical region for BFNC. We now report the first polymorphic marker in the coding region of CHRNA4. The new marker, which is detected by PCR, will be useful for evaluation of the role of CHRNA4 as a candidate gene for BFNC. It will further enable the investigation of this important brain-specific gene in association studies with different types of epileptic diseases and other neurological disorders.     

Search for alpha4 and alpha7 nicotinic acetylcholine receptor markers in a pedigree of benign familial infantile convulsions (BFIC)

In this study we investigate the possible involvement of the recently reported locus for benign familial infantile convulsions (BFIC) in human chromosome 19 and that of the neuronal acetylcholine receptor 4 (CHRNA4) and 7 (CHRNA7) subunits in a family with at least twelve clinically diagnosed cases of BFIC. Six polymorphic microsatellite markers covering the BFIC locus on chromosomal region 19q, one marker for CHRNA4 (chromosome 20) and two for CHRNA7 (chromosome 15) were used for the screening. The two-point lod score analysis showed no evidence of BFIC phenotype on chromosome 19. Similarly, when markers for chromosome 20 (CHRNA4 intron1, Amplimer: CHRNA4. PCR.1) and chromosome 15 (D15S165 and D15S1010) were used, score analysis showed no indication of linkage. The most likely interpretation of these results is that BFIC is a genetically heterogeneous form of epilepsy.     

Identification of variable length polyadenosine tract at the dystrophin locus

We report the characterization of a length polymorphism in the human dystrophin gene, consisting of single-base pair increments in a polyadenosine tract located near the 3 end of exon 68. Using Single Strand Conformation Analysis (SSCA), three length alleles could be identified (10182 + 13A9/10/11). This class of 1-bp length variant is rare among known intronic gene sequences, and has been described only once in the dystrophin gene. Furthermore, the high polymorphic content (0.56) of this novel marker and its distal localization in the 3 end of the coding sequence make it suitable for diagnostic purposes.     

Rare McArdle disease locus polymorphic site on 11q13 contains CpG sequence

Summary When probes throughout the McArdle disease (myophosphorylase) gene region were used to search for DNA polymorphisms, only an MspI polymorphism was found in 94 enzyme-probe combinations. Along with an insertion/deletion polymorphism more 3 to the gene locus, these polymorphisms will be informative in 75% of at-risk patients. These results contrast strikingly to the six polymorphic sites detected in 15 enzyme-probe combinations in the homologous Her's disease (liver phosphorylase) gene region. This single MspI polymorphic site includes a CpG sequence of known increased mutability suggesting that DNA regions with rare polymorphisms will have most polymorphic sites at sequences with enhanced mutability. Fluorescence in situ hybridization sublocalized this gene to proximal band 11q13, establishing a point of cross-reference between the physical and genetic maps.     

Autosomal dominant nocturnal frontal-lobe epilepsy: genetic heterogeneity and evidence for a second locus at 15q24.

Autosomal dominant nocturnal frontal-lobe epilepsy (ADNFLE) is a recently identified partial epilepsy in which two different mutations have been described in the alpha4 subunit of the neuronal nicotinic acetylcholine receptor (CHRNA4). An additional seven families are presented in which ADNFLE is unlinked to the CHRNA4 region on chromosome 20q13.2. Seven additional sporadic cases showed no evidence of defective CHRNA4. One of the families showed evidence of linkage to 15q24, close to the CHRNA3/CHRNA5/CHRNB4 cluster (maximum LOD score of 3.01 with D15S152). Recombination between ADNFLE and CHRNA4, linkage to 15q24 in one family, and exclusion from 15q24 and 20q13.2 in others demonstrate genetic heterogeneity with at least three different genes for ADNFLE. The CHRNA4 gene and the two known CHRNA4 mutations are responsible for only a minority of ADNFLE. Although the ADNFLE phenotype is clinically homogeneous, there appear to be a variety of molecular defects responsible for this disorder, which will provide a challenge to the understanding of the basic mechanism of epileptogenesis.     

Evaluation of microsatellite markers in association studies: a search for an immune-related susceptibility gene in sarcoidosis

Association studies using linkage disequilibrium (LD) between candidate loci and nearby markers have been proposed to identify susceptibility genes for complex diseases. We analyzed polymorphisms of microsatellites (MSs) and LD patterns of the regions in which candidate genes related to the Th1 immune response have been annotated and attempted to identify a susceptibility gene for sarcoidosis in a marker-based association study. Nineteen MSs were identified in six Th1-related genes (IFNGR1, IFNGR2, IL12RB1, IL12RB2, STAT1 and STAT4) and then eight were further characterized as useful polymorphic markers. Most of these MSs showed LD with single nucleotide polymorphisms (SNPs) on both 5 and 3 ends of these candidate genes, in which r² values between at least one of the MS marker alleles and the SNPs were higher than 0.1. A significant association with one MS allele near STAT4 was shown and a cluster of SNPs in LD with the MS marker was associated with sarcoidosis. These results suggest that association studies using not only SNPs but also multi-allelic MS within or near candidate loci would be useful markers to search for a disease susceptibility gene, especially in populations with unknown LD structure.     

Tight linkage between the Beckwith-Wiedemann syndrome and a microsatellite marker for the TH locus

The Beckwith-Wiedemann syndrome (BWS) is characterized by somatic overgrowth, developmental anomalies, and proneness to embryonic tumor development. The majority of cases are sporadic, but several families with an autosomal dominant mode of inheritance with variable expression and reduced penetrance have been described. In three such families, BWS has been linked to DNA markers for the insulin gene (INS) and H-ras on chromosome band 11p15. Two additional families with inherited BWS are described here. Linkage analysis has been performed with a highly informative marker for the tyrosine hydroxylase (TH) locus within the INS-IGF2 (insulin-like growth factor II)-TH gene cluser and confirms the previous observed linkage to this region (lod score 2.16 at = 0). Linkage analysis to TH provides a basis for informed genetic counselling and carrier detection in the hereditary form of the syndrome. Based on the hypothesis that IGF2 may be a candidate gene for BWS, we screened for mutations in the coding exons 7 and 9, but found no abnormalities in 5 unrelated BWS cases.     

Analysis of a second family with hereditary non-chromaffin paragangliomas locates the underlying gene at the proximal region of chromosome 11q

The gene for autosomal, dominantly inherited, non-chromaffin paragangliomas has previously been mapped at 11q23-qter by linkage analysis of a single family. In the present study, we have used genetic markers from 11q for the analysis of two distantly related pedigrees with the same disorder. Linkage analysis and haplotyping indicate that the gene underlying the disorder in the present family is located on chromosome 11q proximal to the tyrosinase gene locus (11q14–q21). Closely linked markers are the human homologue of the murine INT2 protooncogene and the anonymous DNA marker D11S527. A maximum lod score of 5.4 (=0.0) has been obtained for linkage between the disorder and the chromosomal region defined by these markers. The human INT2 gene can be regarded as a candidate for the disorder on the basis of its expression pattern during embryogenesis in the mouse. However, haplotype analysis indicates that this gene is probably not the predisposing genetic factor in the present family.     

Reevaluation of the chromosome 4q candidate region for early onset periodontitis

Evidence of linkage (lod=3.1, =0.05) was reported previously in one large kindred (the Brandywine genetic isolate) for an autosomal dominant form of early onset periodontitis (EOP) with a protein polymorphism in the vitamin D binding protein (GC) located on chromosome 4q12-q13. To evaluate the generality of this finding, 19 unrelated families (228 individuals), each with two or more EOP affected individuals, were ascertained and sampled. A restriction fragment length polymorphism (RFLP) at the GC locus and eight other polymorphic DNA markers and two red blood cell antigens located on proximal chromosome 4q in the vicinity of the GC locus were typed. Twelve genetic models of EOP were evaluated, which varied in diagnostic classification, penetrance, and mode of disease transmission. Results for all models strongly exclude linkage between an EOP susceptibility gene and this chromosomal region assuming locus homogeneity. Our data statistically exclude (lod -2.0) the possibility that more than 40% of our families are linked to this candidate region for one model tested. Linkage under heterogeneity was excluded less strongly for other models, but no significant evidence in support of linkage was obtained for any model. Our results indicate that either the previous report of linkage was a false positive, or that there are two or more unlinked forms of EOP, with the form located in 4q12-q13 being less common.     

Characterization of a Gy4 glycinin gene from soybean Glycine max cv. Forrest

The glycinin gene family encoding the glycinin subunits in soybean plants is composed of at least five gene members. A genomic clone S312 containing the Gy4 gene from a genomic library of cv. Forrest was isolated and partially characterized. The organization of this gene was found to be similar to that of a null allele from cv. Raiden, but different from the Gy4 gene from cv. Dare. The complete nucleotide sequence of this gene has been determined. It is 2599 bp long consisting of four exons and three introns. Comparing the DNA sequences between this gene and the gene from Dare and a null allele from Raiden, the difference found in the coding region was 5-GCAGTGCAAG-3 (nt 824 to 833) in the former case versus 5-TGGAGTTGCAATT-3 (nt 1314 to 1326) in the latter case in the exon 2 domain, resulting in three amino acid differences and one amino acid absence. Some other differences were also found in the non-coding region. The coding sequence and 5-flanking region of the Gy4 gene, when compared with that of other legumin genes as well as group 1 glycinin subunit genes, revealed some interesting features: (1) a transposable element-like sequence was found in the hypervariable region (HVR) of the exon 3 domain, which was lacking in the legumin and the glycinin group 1 genes; (2) in the 5-flanking region from nt –145 to –1, two high-homology sequences were found: one from nt –141 to nt –132, the other from nt –118 to nt –92 which includes the legumin box and the RY repeat element.