Candidate gene analysis in Rett syndrome and the identification of 21 SNPs in Xq

Rett syndrome (RTT) is an X-linked dominant neurodevelopmental disorder that affects females. Exclusion mapping studies using a new family with maternal inheritance of RTT defined Xq28 as the candidate region for the RTT gene. Six candidate genes were selected for mutation analysis based on their established expression patterns and known functions in the CNS. These are: Glutamate receptor subunit 3 (GLUR3), GABA receptor subunit alpha 3 (GABRA3), GABA receptor subunit e1 (GABRE1), Vacuolar ATPase subunit 1 (VATPS1, XAP3), the human homologue of plexin 3-SEX (XAP6) and the Synaptobrevin-like protein (SYBL1). Major rearrangements involving these genes were excluded by Southern analysis. No disease-causing mutations were found, but several single-nucleotide polymorphisms (SNPs) were detected. These SNPs will be useful in future linkage analysis and whole-genome association studies for other diseases. The genomic characterization of GLUR3 and GABRA3 will allow mutational analysis of these genes as candidates for other X-linked neurological disorders mapping to Xq25-Xq26 and Xq28.     

Association analysis of chromosome 1 migraine candidate genes

Background  

Migraine with aura (MA) is a subtype of typical migraine. Migraine with aura (MA) also encompasses a rare severe subtype Familial Hemiplegic Migraine (FHM) with several known genetic loci. The type 2 FHM (FHM-2) susceptibility locus maps to chromosome 1q23 and mutations in the ATP1A2 gene at this site have recently been implicated. We have previously provided evidence of linkage of typical migraine (predominantly MA) to microsatellite markers on chromosome 1, in the 1q31 and 1q23 regions. In this study, we have undertaken a large genomic investigation involving candidate genes that lie within the chromosome 1q23 and 1q31 regions using an association analysis approach.     

Pentraxin 3 Values During Normal Pregnancy

Pentraxin 3 (PTX3) is an inflammatory molecule that has been reported to be a promising early biomarker for subsequent preeclampsia. The levels of PTX3 vary during pregnancy and it is thus a need to establish reference intervals during normal pregnancy. Repeated blood samples were collected from 52 healthy pregnant females. The samples were divided according to collection time into the following groups: week 7–17, week 17–24, week 24–28, week 28–31, week 31–34, week 34–38, before delivery and after delivery. The samples were analyzed for PTX3 with a sandwich ELISA and the 2.5 and 97.5 percentiles for each sample period was calculated. There was a continuous increase of serum PTX3 as pregnancy progressed. The increase was most evident after week 31 with the highest levels just before delivery.     

Association of a Rare Variant with Mismatch Negativity in a Region Between <Emphasis Type="Italic">KIAA0319</Emphasis> and <Emphasis Type="Italic">DCDC2</Emphasis> in Dyslexia

It has been repeatedly shown that mismatch negativity (MMN), an event related potential measurement, reveals differences between dyslexic children and age-matched controls. MMN reflects the automatic detection of deviance between a stream of incoming sounds presented to the passive listener, and deficits in MMN (i.e. attenuated amplitudes) have been especially reported in dyslexia for detecting differences between speech sounds (e.g./ba/vs./da/). We performed an association analysis in 200 dyslexic children. This analysis focused on two MMN components, an early MMN (188–300 ms) and a late MMN (300–710 ms), and the dyslexia candidate genes KIAA0319 and DCDC2 on chromosome 6. Additionally, we imputed rare variants located in this region based on the 1000 genomes project. We identified four rare variants that were significantly associated with the late MMN component. For three of these variants, which were in high LD to each other, genotyping confirmed the association signal. Our results point to an association between late MMN and rare variants in a candidate gene region for dyslexia.     

Chromosome 3p and breast cancer

 Solid tumors in humans are now believed to develop through a multistep process that activates oncogenes and inactivates tumor suppressor genes. Loss of heterozygosity at chromosomes 3p25, 3p22–24, 3p21.3, 3p21.2–21.3, 3p14.2, 3p14.3, and 3p12 has been reported in breast cancers. Retinoid acid receptor β2 (3p24), thyroid hormone receptor β1 (3p24.3), Ras association domain family 1A (3p21.3), and the fragile histidine triad gene (3p14.2) have been considered as tumor suppressor genes (TSGs) for breast cancers. Epigenetic change may play an important role for the inactivation of these TSGs. Screens for promoter hypermethylation may be able to identify other TSGs in chromosome 3p. Alternatively, use of an “epigenetic modifier” may enhance the response to another type of agent for breast cancer. Received: April 30, 2002 / Accepted: May 27, 2002     

An archipelago of CpG islands in Xq28: identification and fine mapping of 20 new CpG islands of the human X chromosome.

19 probes for CpG islands, mapping to Xq28, have been used as probes to construct a physical map of genes of this band of the human X chromosome. A total of 22 CpG islands have been precisely mapped in respect to known loci along the 9-10 Mb of Xq28. The fine mapping of such a large number of CpG islands has demonstrated that also in gene rich Giemsa light bands, like Xq28, gene distribution is non uniform: the CpG islands are clustered in the distal portion of the band in a 2 Mb region between the G6PD gene and the DXS15 locus. Moreover, 16 CpG islands were found between the G6PD and the RCP/GCP genes, a region of DNA of only about 300 kb. If this structural organization has a biological function it has yet to be determined. However, the isolation of large genomic regions enriched in gene sequences and the availability of cosmid or YAC contigs will provide the means to test the significance of such gene organization, as well as the material for large sequencing projects and gene search, for the identification of candidate genes for inherited disorders mapped to Xq28 and for comparative mapping.     

Refinement of the locus for autosomal recessive cone–rod dystrophy (CORD8) linked to chromosome 1q23–q24 in a Pakistani family and exclusion of candidate genes

Cone–rod retinal dystrophy (CORD) characteristically leads to early impairment of vision due to the simultaneous involvement of both cone and rod photoreceptor cells. Several loci/genes have been identified for CORD, including the cone–rod dystrophy (CORD8) locus [OMIM#605549] identified for a Pakistani family. All members of this family underwent detailed clinical re-examination to determine the nature of the dystrophy. All affected individuals suffered from bilateral CORD8 with an autosomal recessive mode of inheritance. The CORD8 locus, mapped on chromosome 1q12–q24, consisted of a very large critical disease region of 21 cM. Analysis with more recently available microsatellite markers within the reported region showed heterozygosity with some of the new markers, and the crossovers lead to a refinement of the disease region from 21 to 11.53 cM. Mutation screening has excluded some of the candidate genes in the region. The disease phenotype of this family could be due to a mutation in a novel gene located within the refined CORD8 locus.Electronic Supplementary Material Supplementary material is available to authorised users in the online version of this article at .Khalid Anwar: Deceased     

Mapping of two genes encoding isoforms of the actin binding protein ABP-280, a dystrophin like protein, to Xq28 and to chromosome 7

ABP-280 is a ubiquitous actin binding protein present in thecytoskeleton of many different cell types. ABP-280 was mappedto distal Xq28, 50–60 kb downstream of the Green ColourPigment (GCP) genes. To establish if ABP-280 may be a candidatefor one of the muscle diseases localized by linkage analysisto distal Xq28 we looked for alternative forms of ABP-280 mRNA.Several different ABP-280 mRNAs were indeed identified: twoare X-linked and are produced by alternative splicing of a smallexon of 24 nucleotides. At least one additional gene encodinga RNA more than 70% identical to ABP-280 in the 1700 bp sequencedhas also been found. It was mapped to chromosome 7. While bothforms of the X-linked ABP-280 are ubiquitous, the gene on chromosome7 is highly expressed only in skeletal muscle and heart. Thetwo genes were therefore excellent candidates for the X-linkedand for the autosomal dominant form of the Emery-Dreifuss MuscularDystrophy (EDMD) both of which have been described. So far,however we were unable to demonstrate mutations in the codingregion or affecting the alternative splicing of the X-linkedform of ABP-280, in several patients studied, and we think thatit is quite unlikely that this is the gene responsible for EDMD.     

The Genetics of Atopic Dermatitis

Background Atopic dermatitis (AD) is a complex genetic disorder influenced by environmental factors. The mode of inheritance and genes involved are not clear. Results This report here is focusing on the current progress in searching the disease-susceptibility genes of AD via both the linkage studies and candidate gene approaches. Genome-wide linkage studies have identified multiple susceptibility loci on 3q and 17q. Candidate region linkage studies identify other susceptibility loci on 5q23–33, 11q13, and 13q12–14. At least 28 candidate genes have to date been verified in association studies, but only association with genes of interleukin (IL)-4, IL-13, IL-4RA, mast cell chymase, and serine protease inhibitor, kazal-type 5 have been replicated in more than two different studies. More halpotype tests and family-based association studies may help to shed more light for the candidate gene approach. Conclusion Determining the candidate susceptibility genes for AD is not only helping understanding the pathophysiology but also affecting the response to therapy, which is important in pharmacogenetics. The effect of environmental trigger may also have to be considered to elucidate the real face of the disease.     

No evidence for significant association between GABA receptor genes in chromosome 15q11–q13 and autism in a Japanese population

The γ-aminobutyric acid (GABA) receptor genes GABRB3, GABRA5, and GABRG3 located on chromosome 15q11–q13 have been major candidates for susceptibility genes for autism, a neurodevelopmental disorder with a complex genetic etiology. In this study, we first investigated the association between the GABA receptor genes and autism in a Japanese population by analyzing 11 single nucleotide polymorphisms (SNPs). Intron 3 of GABRB3 was densely mapped because the previous studies observed the association of the microsatellite 155CA-2 located in the region. We observed no significant difference in allelic frequencies or genotypic distributions of the 11 SNPs between patients and controls. A permutation test showed no significant global differences in estimated haplotype frequencies between patients and controls. Analysis after confining the subjects to males showed similar results. Thus, this study provides no positive evidence of an association between the GABA receptor genes and autism in a Japanese population. However, in a SNP (rs3212337) located near the microsatellite 155CA-2, a significant deviation from the Hardy–Weinberg equilibrium was observed in patients (p = 0.029, corrected for multiple testing). This finding may suggest further studies around the markers for more definitive conclusions.     

Localisation of two candidate genes for mental retardation using a YAC physical map of the Xq21.1-21.2 subbands.

Genetic studies in families with X linked mental retardation have suggested the location of several MR genes in the human q21 region. Since the establishment of cloned resources is an essential step towards the cloning of genes involved in inherited diseases, we built a yeast artificial chromosome (YAC) contig and an STS map of this part of the X chromosome. The contig, which extends from PGK1 in Xq13.3 to DXS1002 in Xq21.2, consists of 30 YACs mapped with 21 markers and spans about 6 Mb. The YAC contig was used as a framework to localise several previously known genes and CEPH/Genethon polymorphic markers, as well as to construct a physical map of the region surrounding one of these genes. We recently localised a presumed MR locus to the region flanked by DXS233 (proximal) and CHM (distal). In the present work, the zinc finger gene, ZNF6, has been shown to lie within this region and to be highly expressed in brain, making it a good candidate MR gene. Similarly the VDAC1 gene has been mapped between DXS986 and DXS72 and its candidate gene status for the Allan-Herndon-Dudley syndrome is discussed.     

Mutation screening in Rett syndrome patients

Rett syndrome (RTT) was first described in 1966. Its biological and genetic foundations were not clear until recently when Amir et al reported that mutations in the MECP2 gene were detected in around 50% of RTT patients. In this study, we have screened the MECP2 gene for mutations in our RTT material, including nine familial cases (19 Rett girls) and 59 sporadic cases. A total of 27 sporadic RTT patients were found to have mutations in the MECP2 gene, but no mutations were identified in our RTT families. In order to address the possibility of further X chromosomal or autosomal genetic factors in RTT, we evaluated six candidate genes for RTT selected on clinical, pathological, and genetic grounds: UBE1 (human ubiquitin activating enzyme E1, located in chromosome Xp11.23), UBE2I (ubiquitin conjugating enzyme E2I, homologous to yeast UBC9, chromosome 16p13.3), GdX (ubiquitin-like protein, chromosome Xq28), SOX3 (SRY related HMG box gene 3, chromosome Xq26-q27), GABRA3 (gamma-aminobutyric acid type A receptor alpha3 subunit, chromosome Xq28), and CDR2 (cerebellar degeneration related autoantigen 2, chromosome 16p12-p13.1). No mutations were detected in the coding regions of these six genes in 10 affected subjects and, therefore, alterations in the amino acid sequences of the encoded proteins can be excluded as having a causative role in RTT. Furthermore, gene expression of MECP2, GdX, GABRA3, and L1CAM (L1 cell adhesion molecule) was also investigated by in situ hybridisation. No gross differences were observed in neurones of several brain regions between normal controls and Rett patients.     

Significant linkage to migraine with aura on chromosome 11q24

Migraine with aura (MA) is a prevalent neurological condition with strong evidence for a genetic basis. Familial hemiplegic migraine, a rare Mendelian form of MA, can be caused by mutations in the calcium channel gene, CACNA1A or in the ATP1A2 gene, a Na+/K+ pump. Susceptibility genes for the more prevalent forms of migraine have yet to be identified despite several reports of linkage including loci on 4q24, 1q31, 19p13 and Xq24-28. We have undertaken a genome-wide screen of 43 Canadian families, segregating MA with families chosen for an apparent autosomal dominant pattern of transmission. Diagnosis was based upon International Headache Society Criteria. Parametric linkage analysis revealed a novel locus on 11q24 with a two-point LOD score of 4.2 and a multi-point parametric LOD score of 5.6. We did not find any support for linkage at previously reported loci. The lack of consensus amongst linkage studies, including this study, is probably an indication of the heterogeneity that is inherent for MA. Nevertheless, the finding of a highly significant locus with a LOD score of 5.6 is powerful evidence that a gene increasing susceptibility to MA resides on 11q24. Several candidate genes map to this region of the genome including a number of ion channel genes such as GRIK4, SCNB2, KCNJ5 and KCNJ1.     

Mapping to distal Xq28 of nonspecific X‐linked mental retardation MRX72: Linkage analysis and clinical findings in a three‐generation Sardinian family

Families with mentally retarded males found to be negative for FRAXA and FRAXE mutations are useful in understanding the genetic basis of X‐linked mental retardation. According to the most recent data (updated to 1999), 69 MRX loci have been mapped and 6 genes cloned. Here we report on a linkage study performed on 20 subjects from a 4‐generation Sardinian family segregating a non‐specific X‐linked recessive mental retardation (XLMR)(MRX72) associated with global delay of all psychomotor development. Five of 8 affected males have been tested for mental age, verbal and performance skills and behavioral anomalies; mental impairment ranged from mild to severe. Only minor anomalies were present in the affected subjects. Two‐point linkage analysis based on 28 informative microsatellites spanning the whole X chromosome demonstrated linkage between the disorder and markers DXS1073 and F8c in Xq28 (maximum Lod score of 2.71 at θ = 0.00). Multipoint linkage analysis confirmed the linkage with a Z_max of 3.0 at θ = 0.00 at DXS1073 and F8c. Recombination in an affected male at DXS1073 and F8c allowed us to delimit centromerically and telomerically the region containing the putative candidate gene. The region, where MRX72 maps, overlaps that of another MRX families previously mapped to Xq28, two of which harbored mutations in GDI. Involvement of this gene was excluded in our family, suggesting another MRX might reside in Xq28. Am. J. Med. Genet. 94:376–382, 2000. © 2000 Wiley‐Liss, Inc.     

Identification of a 650 kb duplication at the X chromosome breakpoint in a patient with 46,X,t(X;8)(q28;q12) and non-syndromic mental retardation

A female patient with non-syndromic mental retardation was shown by high resolution GTL banding to have inherited an apparently balanced translocation, 46,X,t(X;8)(q28;q12)mat. Replication studies in the mother and daughter showed a skewed X inactivation pattern in lymphocytes, with the normal X chromosome preferentially inactivated. The mother also had significant intellectual disability. To investigate the possibility that a novel candidate gene for XLMR was disrupted at the X chromosome translocation breakpoint, we mapped the breakpoint using fluorescence in situ hybridisation (FISH). This showed that the four known genes involved in non-syndromic mental retardation in Xq28, FMR2, SLC6A8, MECP2, and GDI1, were not involved in the translocation. Intriguingly, we found that the X chromosome breakpoint in the daughter could not be defined by a single breakpoint spanning genomic clone and further analysis showed a 650 kb submicroscopic duplication between DXS7067 and DXS7060 on either side of the X chromosome translocation breakpoint. This duplicated region contains 11 characterised genes, of which nine are expressed in brain. Duplication of one or several of the genes within the 650 kb interval is likely to be responsible for the mental retardation phenotype seen in our patient. Xq28 appears to be an unstable region of the human genome and genomic rearrangements are recognised as major causes of two single gene defects, haemophilia A and incontinentia pigmenti, which map within Xq28. This patient therefore provides further evidence for the instability of this genomic region.     

Effect of Corticotropin-Like Intermediate Lobe Peptide on Presynaptic and Postsynaptic Glutamate Receptors and Postsynaptic GABA Receptors in Rat Brain

We studied the effect of corticotropin-like intermediate lobe peptide (CLIP) on presynaptic NMDA receptors and postsynaptic GABA, NMDA, and AMPA receptors in rat brain. CLIP inhibited presynaptic and postsynaptic NMDA receptors, but potentiated postsynaptic GABA and AMPA receptors. Our results indicate that CLIP modulates function of ionotropic receptors for glutamate and GABA. Translated from Byulleten’ Eksperimental’noi Biologii i Meditsiny, Vol. 147, No. 3, pp. 291–294, March, 2009     

X chromosome insertion in the MLL gene in a case of childhood acute myeloblastic leukemia

Band 11q23 is known to be involved in translocations and insertions with a variety of partner chromosomes. These lead to MLL rearrangement, resulting in a fusion with numerous genes. We report here the case of a 5-month-old boy presenting with hemianopsia and severe diffuse intravascular coagulopathy in whom a diagnosis of acute myeloblastic leukemia (AML) French-American-British M4 classification was made. Conventional cytogenetic techniques showed an ins(11;X) (q23;q28q12). Fluorescent in situ hybridization (FISH) with whole chromosome paints confirmed this finding. Using a specific probe, the MLL gene was found to be disrupted, a portion of the X chromosome being inserted between the 5' and 3' regions of the MLL gene. Although some cases of insertion involving chromosomes X and 11 have been reported in AML, this appears to be the first case involving band Xq28. We postulate that this chromosomal rearrangement led to the fusion of the 5' region of the MLL gene with a yet unidentified gene located in band Xq28.     

Characterization of novel isoforms and evaluation of <Emphasis Type="Italic">SNF2L/SMARCA1</Emphasis> as a candidate gene for X-linked mental retardation in 12 families linked to Xq25-26

Background  

Mutations in genes whose products modify chromatin structure have been recognized as a cause of X-linked mental retardation (XLMR). These genes encode proteins that regulate DNA methylation (MeCP2), modify histones (RSK2 and JARID1C), and remodel nucleosomes through ATP hydrolysis (ATRX). Thus, genes encoding other chromatin modifying proteins should also be considered as disease candidate genes. In this work, we have characterized the SNF2L gene, encoding an ATP-dependent chromatin remodeling protein of the ISWI family, and sequenced the gene in patients from 12 XLMR families linked to Xq25-26.     

FG syndrome: linkage analysis in two families supporting a new gene localization at Xp22.3 [FGS3

FG syndrome (OMIM 305450) is an X-linked condition comprising mental retardation, congenital hypotonia, constipation or anal malformations, and a distinctive appearance with disproportionately large head, tall and broad forehead, cowlicks and telecanthus. In a first linkage analysis carried out on 10 families, we demonstrated heterogeneity and assigned one gene [FGS1] to region Xq12-q21.31 [Briault et al., 1997: Am J Med Genet 73:87-90] corroborated by Graham et al. [1998: Am J Med Genet 80:145-156]. Heterogeneity was supported by the study of one family with apparent FG syndrome co-segregating with an inversion of X chromosome [inv(X)(q11q28)] ([FGS2], OMIM 300321) [Briault et al., 1999: Am J Med Genet 86:112-114 and Briault et al., 2000: Am J Med Genet 95:178-181]. We present the results of a new linkage analysis carried out on two families with FG syndrome. The two earlier known loci for FG syndrome, FGS1 and FGS2 (Xq11 or Xq28) were excluded by multipoint analysis of both families. Linkage was found, however, with locus DXS1060 suggesting that a third FG locus might be located at Xp22.3. In this region, two potential candidate genes, VCX-A and PRKX, were excluded by sequence analysis of the coding region in patients of the two reported FG families. The search for new candidate genes is in progress.