A new DNA probe of potential use for diagnosis of the fragile-X syndrome

A new cloned DNA probe (U6.2), which recognizes a TaqI polymorphism near the locus for the fragile-X syndrome, was tested in a great Xq-fra pedigree. In the corresponding four families studied, the probe is informative and no recombinations were observed between the probe and the disease locus, although recombinational events were observed with several other probes tested in the past. The locus defined by the probe, DXS304, cosegregated with the fragile-X phenotype in 20 informative meioses (z = 3.09, theta = 0.00). The degree of polymorphism at this locus and its proximity to the fragile-X locus makes it useful for diagnostic applications.     

DXS539, a polymorphic DNA marker proximal of the fragile-X gene

We report a new polymorphic DNA marker (pJH89, DXS539) proximal to the fragile-X site. The pJH89 probe identifies a TaqI and a NcoI restriction fragment length polymorphism (combined heterozygosity of 42%) and is linked to the fragile-X locus with a maximal LOD score of 12 at 4 cM. Multipoint linkage analysis and physical mapping studies indicate that the pJH89 probe is located within the interval defined by the markers DXS369 and DXS548.     

Chromosome 4q35 haplotypes and DNA rearrangements segregating in affected subjects of 19 Italian families with facioscapulohumeral musculatur dystrophy (FSHD)

Four DNA markers on the distal long arm of chromosome 4 have been analyzed for their linkage to facioscapulohumeral muscular dystrophy locus (FSHD) in a series of 16 Italian families. We found that, in two families, the disease is not linked to the 4q35 markers, indicating the presence of genetic heterogeneity among Italian FSHD families. Linkage analysis in the remaining families supports the order cen-D4S171-D4S163-D4S139-D4S810-FSHD-qter, in agreement with the physical map from the literature. EcoRI digestion and hybridization with the distal marker p13E-11 (D4S810) detected DNA rearrangements in the affected members of both sporadic and familial cases of FSHD, with family-specific fragments ranging in size between 15 kb and 28 kb. In three sporadic FSHD cases, the appearance of a new small fragment not present in either parent was clearly associated with the development of FSHD disease. However, in the familial cases analyzed, we observed two recombinations between all four 4q35 markers and the disease locus in apparently normal subjects, leaving open the possibility of nonpenetrance of the FSHD mutation.

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PME of Unverricht-Lundborg type in the Mediterranean region: linkage and linkage disequilibrium confirm the assignment to the EPM1 locus

Seven phenotypically homogeneous Mediterranean myoclonus families were studied using DNA markers from the genetically defined EPM1 region on chromosome 21. No recombinations between the disease phenotype and the markers studied were detected. Within the EPM1 region, the highest lod score value of 5.07 (at = 0.00) was reached at locus PFKL. Significant allelic association (P = 0.02) between the disease mutation and PFKL was detected suggesting a founder effect in Mediterranean myoclonus. However, haplotype data using four marker loci residing within 300kb of each other and of EPM1 suggest the occurrence of more than one mutation. The data are compatible with Mediterranean myoclonus being caused by mutations in the EPM1 gene and strengthen the concept that a large subset of progressive myoclonus epilepsies conforms with Unverricht-Lundborg disease and that this subset is an etiologically homogeneous entity.     

A new polymorphic marker (D10S97) tightly linked to the multiple endocrine neoplasia type 2A (MEN2A) locus

Familial multiple endocrine neoplasia type 2A (MEN 2A) is a cancer syndrome that is inherited as an autosomal dominant with high penetrance. Its clinical features are medullary carcinoma of the thyroid, pheochromocytomas, and hyperparathyroidism. A new polymorphic locus D10S97 (probe: KW6SacI) detects a codominant EcoRI polymorphism that is tightly linked to the MEN2A locus. The peak lod score for linkage between D10S97 with MEN2A is 13.03 at =0.00. The polymorphic locus D10S97 maps, by linkage analysis, into the previously defined interval between FNRB and RBP3 to which MEN2A has been assigned. We present physical mapping data showing that the probe pKW6 originates from 10p13 and that the polymorphic locus D10S97 in 10q11.2 is detected by cross-hybridization.     

Three DNA markers for hypophosphataemic rickets

Summary This paper presents three markers, 16D/E, pHMAI (DXS208), and CRI-L1391 (DXS274), that show close linkage for X-linked hypophosphataemic rickets (HYP). DXS274 is closely linked to HYP ( _max= 0.00, Z_max = 4.20), and DXS41 (99.6), ( _max= 0.00, Z_max = 5.20). Marker 16D/E maps distal to the disease locus ( _max= 0.05, Z_max = 3.11). The pHMAI probe recognises the same restriction fragment length polymorphism (RFLP) as 99.6. Multipoint analysis suggests that the most probable order of loci is Xpter-(DXS43, 16D/E)-HYP-DXS274-(DXS208, DXS41)-Xcen. The location of DXS274 distal to HYP cannot be excluded, as no recombinants were observed between DXS274 and HYP, or between DXS274 and DXS41/DXS208. One of the families contains a large number of recombinants, four of which are double recombinants. This most probably means that the disease in this family maps elsewhere on the X chromosome or on an autosome, indicating locus heterogeneity.     

The modification of a common wheat-Thinopyrum distichum translocated chromosome with a locus homoeoallelic to Lr19

Summary The Chinese Spring ph1b and ph2b mutants, as well as the nulli 5B tetra 5D stock were utilized in an attempt to effect homoeologous chromatin exchange between the Indis chromosome translocation [derived from Thinopyrum distichum (Thunb.) Löve] and chromosome arm 7DL of common wheat. A homoeoallele of Lr19 and linked genes for yellow flour-pigmentation were utilized as markers. Seven selections with recombinations involving the foreign, translocated segment were recovered. Four of these had white endosperms and were leaf-rust resistant. The remaining lines were leaf-rust resistant and had levels of endosperm pigmentation intermediate to those of Indis and Chinese Spring. The recombined translocation segments coding for white endosperm are no longer associated with chromosome 7D. The original translocated segment may, therefore, not be fully homoeologous to 7DL. The recombinants with white endosperm also lack the stem-rust resitance gene Sr25, but retained the segregation distorter locus, Sd-1. However, it seems as though an enhancer locus (or loci) of Sd-1 had been lost.     

Mitochondrial DNA rearrangements in somatic hybrids of Solanum tuberosum and Solanum brevidens

Summary Thirty somatic hybrids between Solanum tuberosum and Solanum brevidens were analysed for mitochondrial and chloroplast genome rearrangements. In all cases, the chloroplast genomes were inherited from one of the parental protoplast populations. No chloroplast DNA alterations were evident but a range of mitochondrial DNA alterations, from zero to extensive intra- and inter-molecular recombinations, were found. Such recombinations involved specific recombination hot spots in the mitochondrial genome. Not all hybrids regenerated from a common callus possessed identical mitochondrial genomes, suggesting that sorting out of mitochondrial populations in the callus may have been incomplete at the plant regeneration stage. Sorting out of organelles in planta was not observed.     

A gene for blepharophimosis-ptosis-epicanthus inversus syndrome maps to chromosome 3q23

Blepharophimosis-ptosis-epicanthus inversus syndrome (BPES) is an autosomal dominant malformation of the eyelids that may severely impair visual function. Chromosomal aberrations involving chromosomes 3q23, 3p25 and 7p34 have been reported in BPES but the disease gene has not been hitherto localized by linkage analysis. We have mapped a gene for BPES to chromosome 3q23 in a large French pedigree (Z _max = 4.62 at =0 for probe AFM 182yc5 at locus D3S1549). The best estimate for the location of the disease gene is at locus D3S1549, between the loci D3S1292 and D3S1555 (maximum lod score of 5.10).     

Linkage analysis of families with fragile-X mental retardation, using a novel RFLP marker (DXS 304).

A new polymorphic DNA marker U6.2, defining the locus DXS304, was recently isolated and mapped to the Xq27 region of the X chromosome. In the previous communication we describe a linkage study encompassing 16 fragile-X families and using U6.2 and five previously described polymorphic markers at Xq26-q28. One recombination event was observed between DXS304 and the fragile-X locus in 36 informative meioses. Combined with information from other reports, our results suggest the following order of the examined loci on Xq: cen-F9-DXS105-DXS98-FRAXA-DXS304-(DXS52-F8 -DXS15). The locus DXS304 is closely linked to FRAXA, giving a peak lod score of 5.86 at a corresponding recombination fraction of .00. On the basis of the present results, it is apparent that U6.2 is a useful probe for carrier and prenatal diagnosis in fragile-X families.     

Use of RFLP markers for the identification of alleles of the Pm3 locus conferring powdery mildew resistance in wheat (Triticum aestivum L.)

The objective of this study was to identify molecular markers linked to genes for resistance to powdery mildew (Pm) in wheat using a series of Chancellor near-isogenic-lines (NILs), each having one powdery mildew resistance gene. A total of 210 probes were screened for their ability to detect polymorphism between the NILs and the recurrent parent. One of these restriction fragment length polymorphism (RFLP) markers (Xwhs179) revealed polymorphism not only between the NILs for the Pm3 locus, but also among NILs possessing different alleles of the Pm3 locus. The location of the marker Xwhs179 was confirmed to be on homoeologous chromosome group 1 with the help of nullitetrasomic wheat lines. The linkage relationship between this probe and the Pm3 locus was estimated with double haploid lines derived from a cross between wheat cvs Club and Chul (Pm3b). The genetic distance was determined to be 3.3±1.9 cM.     

TaqI polymorphism in the LDL receptor gene and a TaqI 1.5-kb band associated with familial hypercholesterolemia

Summary The low density lipoprotein (LDL) receptor gene was analyzed in 67 unrelated healthy Japanese and 38 members of six consecutive families with familial hypercholesterolemia (FH) by Southern blot hybridization with TaqI, an LDL receptor cDNA fragment containing exons 1 to 8 being used as a probe. A new TaqI RFLP at the LDL receptor locus was detected with allele frequencies of 0.67 and 0.33. The data obtained with smaller cDNA subfragment probes revealed that the TaqI RFLP site is located within 1.1 kb of the 5 side of the EcoRI site of exon 5. The TaqI RFLP was in linkage disequilibrium with the PstI RFLP but showed no significant linkage disequilibrium with the RFLPs for AvaII, ApaLI/I15, PvuII, NcoI, and ApaLI/3. Among the seven RFLPs at the LDL receptor locus, the TaqI RFLP was the only useful genetic marker in one of the six families with FH. Furthermore, the association of an additional TaqI 1.5-kb band with a mutant LDL receptor gene was observed in another family with FH in which the proband was homozygous for all of the seven RFLPs. The data obtained with various restriction enzymes and smaller cDNA subfragments probes suggested that a minor change in nucleotide sequences in the region including exons 5 to 8 is present in the mutant gene. These data suggest that the TaqI RFLP is a useful genetic marker at the LDL receptor locus and that TaqI serves for the analysis of some mutant LDL receptor genes, when used with small LDL receptor cDNA probes.     

An α-fucosidase pseudogene on human chromosome 2

Summary In Chinese hamster-human hybrids with overlapping translocations, the major site of hybridization of a cDNA clone for the liver form of human -l-fucosidase was 1p36.31p34, consistent with hybridization to the FUCA1 locus. No hybridization to the FUCA2 locus on chromosome 6 was observed. Hybridization to a genomic sequence on chromosome 2 was, however, detected, thus defining a new FUCA-like locus. The restriction map of the -fucosidase cDNA could be exactly superimposed upon its region of homology within a genomic clone containing this FUCA-like locus, suggesting that it is a processed pseudogene.     

RFLP mapping of the sugary enhancer1 gene in maize

RFLP marker data from an F₂₃ population derived from a cross between a sugary1 (su1) and a sugary enhancer1 (su1, sel) inbred were used to construct a genetic linkage map of maize. This map includes 93 segregating marker loci distributed throughout the maize genome, providing a saturated linkage map that is suitable for linkage analysis with quantitative trait loci (QTL). This population, which has been immortalized in the form of sibbed F₂₃ families, was derived from each of the 214 F₂ plants and along with probe data are available to the scientific community. QTL analysis for kernel sucrose (the primary form of sugar) concentration at 20 days after pollination (DAP) uncovered the segregation of seven major QTL influencing sucrose concentration; a locus linked to umc36a described the greatest proportion of the variation (24.7%). Since maltose concentration has previously been reported to be associated with the se1 phenotype, an analysis of probe associations with maltose concentration at 40 DAP was also conducted. The highly significant association of umc36a with maltose and sucrose concentrations provided evidence that this probe is linked to se1. Phenotypic evaluation for the se1 genotype in each F₂₃ family enabled us to map the gene 12.1 cM distal to umc36a. In contrast to previous work where se1 was reported to be located on chromosome four, our data strongly suggest that the sugary enhancer1 locus maps on the the distal portion of the long arm of chromosome 2 in the maize genome.     

Molecular identification of powdery mildew resistance genes in common wheat (Triticum aestivum L.)

RFLP markers for the wheat powdery mildew resistance genes Pm1 and Pm2 were tagged by means of near-isogenic lines. The probe Whs178 is located 3 cM from the Pm1 gene. For the powdery mildew resistance gene Pm2, two markers were identified. The linkage between the Pm2 resistance locus and one of these two probes was estimated to be 3 cM with a F₂ population. Both markers can be used to detect the presence of the corresponding resistance gene in commercial cultivars. Bulked segregant analysis was applied to identify linkage disequillibrium between the resistance gene Pm18 and the abovementioned marker, which was linked to this locus at a distance of 4 cM. Furthermore, the RAPD marker OPH-11₁₉₀₀ (5-CTTCCGCAGT-3) was selected with pools created from a population segregating for the resistance of Trigo BR 34. The RAPD marker was mapped about 13 cM from this resistance locus.     

Assignment of the gene for dyskeratosis congenita to Xq28

Summary Dyskeratosis congenita is an X-linked recessive disorder with diagnostic dermatological features, bone marrow hypofunction, and a predisposition to neoplasia in early adult life. Linkage analysis was undertaken in an extensive family with the condition using the Xg blood group and 17 cloned X chromosomal DNA sequences which recognise restriction fragment length polymorphisms (RFLPs). No recombination was observed between the locus for dyskeratosis congenita (DKC) and the RFLPs identified by DXS52 (St 14-1) (Z_max=3.33 at _max=0 with 95% confidence limits of 0 to 14 cM). Similarly no recombination was observed for the disease locus and F8 (Z_max=1.23 at _max=0) nor for DXS15 (Z_max=1.62 at _max=0), but both of these markers were only informative in part of the family whereas DXS52 was fully informative. DXS52, DXS15, and F8 are known to be tightly linked and have previously been assigned to Xq28. Thus the gene for dyskeratosis congenita can be assigned to Xq28. These DNA sequence polymorphisms will be of clinical value for carrier detection and prenatal diagnosis.     

Close linkage of probe p212 (DXS178) to X-linked agammaglobulinemia

Summary Segregation analysis was performed in three families affected in X-linked agammaglobulinemia (XLA) with five polymorphic DNA probes linked to the disease locus. In agreement with previous studies, no recombination was observed with either pXG12 (DXS94) or S21 (DXS17). Segregation analysis was also performed with a marker, p212 (DXS178), which has been shown to be closely linked to pXG12 in normal families. No cross-over with XLA was observed in these three families and in five additional families previously analyzed with DXS17 and DXS94 (z = 5.92 at = 0). These data provide evidence against genetic heterogeneity in XLA and indicate the value of probe p212 for carrier detection and prenatal diagnosis of XLA. We were able to estimate the carrier status of six females (out of six) in the three previously unreported families.     

Estimating the stability of the proposed imprinted state of the fragile-X mutation when transmitted by females

Summary Fragile-X syndrome is a major cause of mental retardation in humans. The X-inactivation imprinting model accounts for the unusual pattern of inheritance and expression of this syndrome. According to this model, the fragile-X mutation creates a local block to the attempted reactivation of the mutant X chromosome prior to oogenesis. This local block results in an imprinted fragile-X chromosome that is deleterious in males and in females for whom this chromosome is predominantly the active X chromosome. The imprinted state of the fragile-X mutation is inferred to be stable when transmitted by an imprinted female because the penetrance of the syndrome in sons of affected females is estimated to be 1.0. To provide a more precise estimate of the stability of the proposed fragile-X imprint, we have analyzed published pedigrees that include restriction fragment length polymorphism and cytogenetic data from sibships with mothers who are interpreted as having an imprinted fragile-X allele. We conclude that the fragile-X imprint was stable in 46 out of 48 female meioses. This analysis leads to a preliminary estimate of about 96% for the stability of the imprint through female meiosis. Two imprinted females had progeny who appeared to be carriers of a nonimprinted fragile-X allele. If this interpretation is correct, then reversion from the imprinted to the nonimprinted state, or erasure, can occasionally occur when the mutant fragile-X allele is transmitted by an imprinted female. We discuss the genetic and epigenetic significance of possible female erasure. We request DNA and cytogenetic information from unpublished pedigrees to quantify further the stability, during female meiosis, of the proposed imprinted state of the mutant fragile-X allele.     

Biogenesis of mitochondria 49 identification and mapping of a new mitochondrial locus (tsr1) which maps within polar region of yeast mitochondrial genome.

Summary An enrichment procedure which facilitates the isolation of conditional respiratory-deficient mutants of Saccharomyces cerevisiae is reported. Detailed genetic analysis of one mutant which exhibits a respiratory deficient phenotype at low temperature (18°C) is also presented. The phenotype is due to a single lesion at a new locus, tsr1, located on the mitochondrial DNA. By analysis of locus retention patterns in a set of physically characterized petite strains, the tsr1 mutation has been mapped within the segment 0–5 map units on the physical map of the yeast mitochondrial genome. This segment of the mitochondrial DNA also contains the cap1 and ery1 loci and the cistron for the mitochondrial 21S rRNA. Studies of the frequencies of co-retention of markers in petite populations, and of the frequencies of recombination of markers in non-polar crosses (⁺ × ⁺), demonstrate linkage of the tsr1 locus to both the cap1 and ery1 loci. The degree of linkage indicates that tsr1 is closer to the ery1 locus. Comparison of pairwise recombination frequencies for these three markers indicate the order cap1-tsr1-ery1. The tsr1 locus lies within the segment of the mitochondrial genome which is influenced by the polarity locus , and analysis of transmission and recombination frequencies and polarities in a polar (⁺ × ^-) cross show that the behaviour of the tsr1 locus is similar to that of ery1. However striking features of this cross are that the recombination frequency between tsr1 and ery1 is comparable to that observed in non-polar crosses, and that the polarity for recombination between tsr1 and cap1 or ery1 is extremely low.     

Identification of expressed bovine class I MHC genes at two loci and demonstration of physical linkage

A cDNA library prepared from lymphocytes of a cow (E98), homozygous at major histocompatibility complex (MHC) loci (BoLA phenotype w10, KN104), was screened with a bovine MHC class I probe. Of the cDNA clones isolated, two, (2.1 and 5.1) were selected and showed divergence at both 5 and 3 termini. E98 DNA was digested with rare-cutter enzymes (Sfi I, Mlu I, Not I, and Cla I) and fragments were size-separated by field inversion gel electrophoresis (FIGE). Hybridization with an entire class I cDNA probe revealed multiple fragments generated by each enzyme. When the 3 untranslated regions (UT) of 2.1 and 5.1 were used as probes, only one fragment was revealed in each digested sample, showing locus specificity of these probes in cattle. Further, DNA of transfected mouse fibroblasts L4 (expressing KN104) and L10 (expressing w10) hybridized to the 3UT regions of clones 2.1 and 5.1, respectively, Northern blot analysis of the mRNA of the L4 and L10 transfected cells provided further evidence that the cDNA clones 2.1 and 5.1 code for the BoLA-KN104 and BoLA-w10 class I molecules respectively, and thus these represent the products of two different genes. A long range physical mapping of the BoLA-w10 and KN104 genes was performed using FIGE analysis of DNA of and homozygous and an heterozygous animal. This analysis revealed that the BoLA-w10 and KN104 genes are separated by not more than 210 kilobases (kb) and that they are components of a multigene family spanning 1550 kb. As the] w10 gene is at the BoLA-A locus we assign the KN104 gene to a B locus.