Evaluation of the facioscapulohumeral muscular dystrophy (FSHD1) phenotype in correlation to the concurrence of 4q35 and 10q26 fragments

Probe p13E-11 (locus D4F104S1) detects two highly homologous polymorphic loci on chromosomes 4q35 and 10q26. Previous reports in the literature have described a correlation of shortened 4q35-specific fragments and facioscapulohumeral muscular dystrophy (FSHD1). We have identified 30 FSHDI families (46 patients) carrying one short 4q35 and one short 10q26 fragment. The clinical data of these patients were compared with those of 47 families (131 patients) showing a single short 4q35 fragment, in order to evaluate a potentially modifying influence of shortened 10q26 fragments on the phenotype. According to our results, the polymorphic locus on 10q26 does not modify the FSHDI phenotype. The normal population (14%) and our FSHDI population (13%) did not significantly differ in the overall frequency of short polymorphic 10q26 fragments. The specificity of the p13E-11/EcoRI-BlnI test for FSHD1 was 100%.     

Assignment of the human gene encoding eukaryotic initiation factor 4E (EIF4E) to the region q21-25 on chromosome 4

We recently cloned genomic sequences containing the promoter region for the messenger RNA cap binding protein (eIF4E). As the rate-limiting step in translation, eukaryotic initiation factor 4E is important in cellular growth control. Using oligonucleotide primers specific for the promoter region in polymerase chain reactions (PCR), we amplified the human gene in a chromosome 4-specific human/rodent somatic cell panel. This panel mapped single copy genomic sequences for eIF4E in the region 4q21 to 4q25.     

Direct detection of 4q35 rearrangements implicated in facioscapulohumeral muscular dystrophy (FSHD).

The p13E-11 probe has been shown to detect DNA rearrangements in sporadic and familial cases of FSHD. Its use, however, has been hampered by the fact that it detects at least two pairs of EcoRI alleles, one derived from the 4q35 region (D4F104S1), the other from 10q26 (D10F104S2). We have cloned p13E-11 EcoRI fragments from the 4q35 and 10q26 subtelomeric regions and shown the presence of several restriction site differences within the KpnI tandem repeat units. The two loci present a different distribution of restriction sites for the enzyme BlnI which allows differential cleavage of the KpnI units derived from 10q26, leaving intact the 4q35 pair of alleles. This method of differential restriction greatly facilitates the interpretation of Southern blots obtained from affected and unaffected subjects, with an important improvement in reliability for diagnosis and genetic counselling. In addition, this method can be used to investigate the molecular mechanism of the 4q35 rearrangement implicated in the disease and to ascertain whether the rearrangement is because of interchromosomal exchange between 4qter and 10qter KpnI repeats.     

The first recurring chromosome translocation in hepatoblastoma: Der(4)t(1;4)(q12;q34)

We report four cases of hepatoblastoma with a derivative chromosome 4 from an unbalanced translocation between the long arms of chromosomes 1 and 4, an aberration reported only rarely in isolated cases of other types of neoplasms. The abnormality in three hepatoblastomas was der(4)t(1;4)(q12;q34), whereas the fourth case appeared to have a der(4)t (q25;q32). All had hyperdiploid tumor karyotypes; however, in the case with t(q25;q32), the der(4) was the only abnormality in the stemline. We speculate that the oncogenetic event in our cases may be the loss of a gene or genes on distal 4q or their alteration by juxtaposition to 1q12 heterochromatin. Genes Chromosom. Cancer 19:291–294, 1997. © 1997 Wiley-Liss, Inc.     

Fine deletional mapping of chromosome 4q22-35 region in oral cancer

We analyzed the loss of heterozygosity of the long arm of chromosome 4 in 40 oral cancers, using 16 microsatellite markers based on data from the human genome sequence, and defined the deletional mapping of the region with putative tumor suppressor genes. Our data revealed two distinct commonly deleted regions around the markers, D4S2623 and D4S1644, with an allelic deletion of 44 and 39%, respectively. Additional mapping and use of the markers near one of these hot spots narrowed down the minimally deleted region about 1.5 Mbp around the marker, D4S2623. Caspase 6 is localized 280 kb from the marker, D4S2623. Fine mapping of this region with possible tumor suppressor gene suggests caspase 6 as a putative tumor suppressor gene. Further molecular analysis of caspase 6 should be performed to clarify its role in oral carcinogenesis.     

Inter- and intrachromosomal sub-telomeric rearrangements on 4q35: implications for facioscapulohumeral muscular dystrophy (FSHD) aetiology and diagnosis

The autosomal dominant myopathy facioscapulohumeral muscular dystrophy (FSHD) is causally related to a short Eco RI fragment detected by probe p13E-11. This remnant fragment is the result of a deletion of an integral number of tandemly arrayed 3.3 kb repeat units (D4Z4) on 4q35. Despite intensive efforts, no transcribed sequences have been identified within this array. Previously, we have shown that these repeats on 4q35 have been exchanged for a similar highly homologous repeat locus on 10q26 in 20% of the population and that a short chromosome 10-like array on 4q35 also results in FSHD. Here, we describe the hybrid structure of some of these repeat arrays, reflecting additional sub-telomeric instability. In three healthy individuals carrying a 4-like repeat on chromosome 10 or vice versa, one repeat array was shown to consist of hybrid clusters of 4-derived and 10-derived repeat units. Moreover, employing pulsed field gel electrophoresis analysis, we identified two unrelated individuals carrying deletions of a chromosomal segment (p13E-11) proximal to the repeat locus. These deletions were not associated with FSHD. In one of these cases, however, an expansion of the deletion into the repeat array was observed in one of his children suffering from FSHD. These data provide additional evidence for instability of this sub-telomeric region and suggests that the length of the repeat, and not its intrinsic properties, is crucial to FSHD. Moreover, they are in agreement with the hypothesis that FSHD is caused by a position effect in which the repeat structure influences the expression of genes nearby. Therefore, the region deleted proximal to the repeat locus in healthy individuals can be instrumental to refine the critical region for FSHD1.      

Identification of a 1-cM region of common deletion on 4q35 associated with progression of hepatocellular carcinoma.

To identify the location of one or more of the putative tumor suppressor genes (TSG) on chromosome arm 4q that may be involved in hepatocellular carcinoma (HCC), we examined 96 primary HCCs for their patterns of allelic loss at 39 microsatellite marker loci distributed along this chromosome arm. Allelic loss at one or more loci was observed in 71 (74%) HCCs. Detailed deletion mapping identified two distinct commonly deleted regions; one was located within a 1-cM interval flanked by D4S1534 and D4S2929 at 4q21-22, the other in the 1-cM interval flanked by D4S2921 and D4S2930 at 4q35. Of the tumors for which clinical data were available, allelic loss at 4q35 was more frequent in poorly or moderately differentiated tumors than in well-differentiated tumors (3/15, 20%, vs. 14/21, 67%, P = 0.008); in tumors larger than 2 cm in size (2/11, 18%, vs. 34/62, 55%, P = 0.046); and in tumors that arose from liver cirrhosis as opposed to HCCs arising from chronic hepatitis (25/42, 60%, vs. 9/27, 33%, P = 0.048). The association of allelic losses on 4q35 with larger tumor size and aggressive histological type implies that loss or inactivation of TSG located within the 1-cM interval of 4q35 identified here contribute to progression of HCCs.     

Characterization of FMN2 gene at human chromosome 1q43

Mouse Formin (Fmn1) is an actin regulator interacting with Profilin, SRC, EMS1, FNBP1, FNBP2, FNBP3, FNBP4, WBP4 and alpha-catenin. FMN1, FHOD1, FHOD3, GRID2IP and FHDC1 are non-FDD-type Formin homology proteins, while FMNL1, FMNL2, FMNL3, DIAPH1, DIAPH2, DIAPH3, DAAM1 and DAAM2 are FDD-type Formin homology proteins. Here, we characterized human FMN2 gene by using bioinformatics. Complete coding sequence of human FMN2 cDNA was determined by assembling AL359918, AL513342, AL590490, AL646016 genome sequences, AF218941 partial cDNA, and AF218942 partial cDNA. FMN2 mRNA was expressed in fetal brain, adult whole brain, hypothalamus, retina, pancreatic islet and germinal-center B cells. Among various human tumors, FMN2 mRNA was expressed in parathyloid tumor, glioblastoma, retinoblastoma and chondrosarcoma. Human FMN2 (1722 aa) showed 74.7% total-amino-acid identity with mouse Fmn2, and 31.9% total-amino-acid identity with human FMN1. Although N-terminal half was divergent between FMN2 orthologs and FMN1 orthologs, FH1 and FH2 domains were conserved among FMN2 and FMN1 orthologs. Exon-intron structure was conserved between FMN2 and FMN1 genes. RYR2-FMN2-CKTSF1B2 (PRDC) locus at human chromosome 1q43 and RYR3-FMN1-CKTSF1B1 (Gremlin) locus at human chromosome 15q13-q14 were paralogous regions (paralogons) within the human genome. This is the first report on comprehensive characterization of the human FMN2 gene.     

Molecular characterisation of the human apo(a)-plasminogen gene family clustered on the telomeric region of chromosome 6 (6q26 - 27)

The genes coding for apo(a) and plasminogen belong to a familyof related genes sharing several structural sequences like leader,krlngle, and protease domains. YAC cloning has allowed to understandthat all these genes are clustered within 400 Kb of genomicDNA on the telomeric region of chromosome 6 (6q26 – 27).We have now characterized the two remaining members of the apo(a)and plasminogen gene cluster. One of them was found to containa leader highly homologous to that of apo(a) and plasminogen,followed by several kringle IV-like units, kringle V and proteasedomains although no tall sequences could be detected. This apo(a)-likegene was found to be expressed at the RNA level in liver althoughan in-frame stop codon was detected in one of its kringle units.The other member of the cluster besides the leader shows a plasminogentail-like domain whose sequences contain a frameshift resultingin a stop codon; another mutation, destroying a consensus splicingsite, has been found in a large Intron separating the exon codingfor the leader from the one encoding the tail-like sequences.The structural organisation of this cluster suggests that newarrangements of these four genes will be a likely finding.     

A balanced translocation t(4;9) (q35;q12) with a breakpoint within the heterochromatic region of chromosome 9 in a woman with recurrent abortion

A case of recurrent abortion was found to be associated with the presence in the mother of a balanced translocation between chromosomes 4 and 9. The karyotype of the proposita was: 46, XX, t(4;9)(q35;q12). The effects of this translocation are discussed in the light of other cases reported in the literature.     

Linkage of polymorphic congenital cataract to the gamma-crystallin gene locus on human chromosome 2q33-35

Cataract is one of the major causes of blindness in humans. We describe here an autosomal dominant polymorphic congenital cataract (PCC) which is characterised by wide variations in phenotype of non-nuclear lens opacities, even among affected members of the same family. PCC families included a large, unique pedigree (254 members, 103 affected individuals), and genetic linkage was conducted using a variety of polymorphic markers. Evidence for linkage was found for chromosome 2q33- 35 with PCC mapping near D2S72 and TNP1. A tri-nucleotide microsatellite marker for gamma-crystallin B gene (CRYG1) was found to co-segregate with PCC and yielded a maximum lod score of 10.62 at (theta = 0). A multipoint analysis demonstrated that the most probable location of the PCC gene was within an 8 cM genetic interval containing the gamma-crystallin gene cluster. These data provide strong evidence of the existence of an autosomal dominant mutation for PCC in or near the gamma-crystallin gene cluster. This defect is characterised by complete penetrance but variable expression of the cataract phenotype. Our study also suggests that non-nuclear human cataracts might be caused by some abnormality in gamma-crystallin genes.      

Serotonin receptor 1c gene assigned to X chromosome in human (band q24) and mouse (bands D-F4).

In the mammalian nervous system, serotonin (5-hydroxytryptamine) binds to distinct cell surface receptor subtypes that are defined by their ligand binding and effector-coupling properties. The 5HT1c receptor is a G-protein coupled receptor that stimulates phospholipase C-catalyzed hydrolysis of phosphatidylinositol bisphosphate, leading to the mobilization of intracellular calcium and to the activation of protein kinase C. By using somatic cell hybrid analysis and FISH, we have mapped the HTR1C locus to the human X chromosome, band q24 and to the mouse X chromosome region D-F4. Comparison of these map positions offers new insights into the evolution of human and murine X chromosomes. Since HTR1C is expressed in certain parts of the central nervous system and abnormal function of the serotoninergic system has been implicated in affective disorders, obsessive-compulsive disorder and epilepsy, establishing the precise map position of HTR1C is an important first step toward evaluating this locus as a candidate for mutations in these syndromes and in X-linked mental disorders.     

Assignment of the human gene for muscle-type phosphofructokinase (PFKM) to chromosome 1 (region cen→q32) using somatic cell hybrids and monoclonal anti-M antibody

Human phosphofructokinase (PFK; EC 2.7.1.11) is under the control of three structural loci which encode muscle-type (M), liver-type (L), and platelet-type (P) subunits; human diploid fibroblasts and leukocytes express all three loci. In order to assign human PFKMlocus to a specific chromosome we have analyzed human × Chinese hamster somatic cell hybrids for the expression of human M subunits, using an anti-human M subunit-specific mouse monoclonal antibody. In 18 of 19 hybrids studied, the expression of the PFKMlocus segregated concordantly with the presence of chromosome 1 (discordancy rate 0.05) as indicated by chromosome and isozyme marker analysis. The discordancy rates for all the other chromosomes were 0.32 or greater, indicating that the PFKMlocus is on chromosome 1. For the regional mapping of PFKM,eight hybrids were studied that contained one of five distinct regions of chromosome 1. These results further localize the human PFKMlocus to region cenq32 of chromosome 1.     

Localisation of a gene causing endocrine neoplasia to a 4 cM region on chromosome 1p35-p36.

The development of some endocrine tumours, such as medullary thyroid carcinomas, phaeochromocytomas, anterior pituitary adenomas, and parathyroid adenomas involve a putative tumour suppressor gene located on chromosome 1p32-pter, a region that represents 111 cM. In order to refine the location of this gene, 93 endocrine tumours (39 parathyroid adenomas, 40 anterior pituitary adenomas, seven pancreatic islet cell adenomas, and seven carcinoids) were investigated for loss of tumour heterozygosity (LOH) using the seven polymorphic loci 1pter-D1S228-D1S507-D1S234-D1S476-D1S22 0-D1S207-D1S206-1cen. LOH was detected in 27% of the parathyroid tumours and in 7.5% of the pituitary tumours, but in none of the pancreatic islet cell or carcinoid tumours. In addition, seven of the 10 parathyroid tumours that showed LOH of chromosome 1p facilitated a more precise mapping of this putative tumour suppressor gene; five tumours involved a loss only of the telomeric locus D1S228, whereas two other tumours showed LOH at the centromeric loci D1S507, D1S234, D1S476, and D1S220, but not D1S228. Thus, our results have mapped this tumour suppressor gene implicated in endocrine tumours to a 4 cM region flanked by D1S228 and D1S507 on chromosome 1p35-p36.     

High-resolution SNP map in the 55-kb region containing the selectin gene family on chromosome 1q24–q25

 Immunoglobulin A nephropathy (IgAN) is the most common form of glomerulonephritis characterized by predominant IgA deposits in glomerular mesangium. By means of a genome-wide case-control association study, we previously demonstrated that eight single-nucleotide polymorphisms (SNPs) within the selectin gene cluster are significantly associated with IgAN. Here we provide more detailed information of variations corresponding to selectin loci, consisting of 88 SNPs and two insertion–deletion polymorphisms in the Japanese population: 27 in 5′ flanking regions, 1 in 5′ untranslated regions, 6 within coding regions, 46 in introns, 4 within 3′ untranslated regions, and 4 in 3′ flanking regions. The SNP map presented here will be a useful resource not only for examining the relationships between selectin genotypes and susceptibility to the IgAN phenotype, but also for analyzing gene scans of complex diseases mapped to this local segment on chromosome 1. Received: November 18, 2002 / Accepted: November 22, 2002 Correspondence to:Y. Nakamura     

Case Report: Two newborns with chromosome 4 imbalances: deletion 4q33 → q35 and ring r (4) (pterq35.2-qter)

Two patients are reported who presented with 4q deletion and r(4), respectively. Cytogenetic and FISH analysis denned the breakpoints respectively at bands 4q33 → q35 proximal to the telomere, and 4pter and 4q35.2-qter. Moreover in both cases rearranged chromosomes maintained telomeric sequences. The first patient showed some clinical features of deletion 4q and a pointed 5th finger, a characteristic finding in deletion 4q31 → qter. The second patient had mild dysmorphism associated with growth retardation.