X-chromosome methylation in manifesting and healthy carriers of dystrophinopathies: concordance of activation ratios among first degree female relatives and skewed inactivation as cause of the affected phenotypes

The X-chromosome activity states of 11 manifesting carriers of dystrophinopathies, all with normal karyotypes, were estimated by restriction fragment length polymorphism (RFLP)-methylation analysis with the probes M27 (DXS255), p2-19(DXS605) and pSPT/PGK (PGK1) to test the role of skewed X-inactivation ratios as the cause of their affected phenotypes. In eight cases preferential inactivation of the putative X chromosome carrying the normal dystrophin allele in 90% of their peripheral lymphocytes was observed, two cases showed non-appparent deviant ratios (6040 and 7030) from the theoretically expected values around the mean of 50% and in one case the three markers employed yielded no information. The analysis of the X-inactivation ratio in six mother-daughter pairs, all non-manifesting Duchenne muscular dystrophy (DMD) carriers, and in the close female relatives of the patients showed: (a) neither of the two X chromosomes was preferentially inactivated with respect to their parental origin; (b) a high concordance among the activation ratios of mothers and daughters, a result difficult to explain just in terms of random X-chromosome inactivation.     

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.     

Isodicentric X chromosome in a patient with Turner syndrome — implications for localization of the X-inactivation center

Summary Cytogenetic analyses have previously shown that the region Xq11.2–q21 is retained in all structurally abnormal X chromosomes. From these observations the conclusion has been drawn that this critical region on the proximal long arm of the X chromosome contains the locus controlling X-inactivation. Structurally abnormal X chromosomes without the X-inactivation center would allow nullisomy, disomy, or trisomy for genes on the X chromosome, and this condition is presumed nonviable. We studied a 28-year-old woman with primary amenorrhea and features of Turner syndrome who had an unusual isodicentric chromosome of the short arm of X. This patient provided us with the opportunity to more closely define the location of the X-inactivation center. High resolution chromosome analysis showed a 46,X,idic(X)(pterq13.2::q13.2pter) chromosome pattern in 94% of her cells and a 45,X complement in 6%. Replication studies showed this derivative X chromosome to be late-replicating (inactive) in all cells analyzed. DNA analysis confirmed the breakpoint of the isodicentric chromosome to be proximal to PGK1. Based on these results, the locus for the X-inactivation center can be refined to be within Xq11.2–q13.2.     

Evolution of karyotypic abnormalities and C-MYC oncogene amplification in human colonic carcinoma cell lines

Cell lines (COLO 320 DM and COLO 320 HSR), established from a human neuroendocrine tumor, contain an amplified cellular oncogene (c-myc). We have previously shown that the homogeneously staining regions (HSRs) of a marker chromosome in the COLO 320 HSR cells that evolved in culture from COLO 320 DM cells contain amplified c-myc. Molecular hybridization in situ has now been used to demonstrate that the HSRs are on both arms of what was once an X chromosome. We also show that amplified c-myc copies are present in the isolated double minute chromosomes (DMs) of the COLO 320 DM cells that were characteristic of the tumor cells initially established from the patient. The results suggest that the amplified c-myc appeared first as DMs and was subsequently transposed to engender HSRs on an X chromosome. The initial COLO 320 tumor cell may have acquired two early replicating (i.e., active) X chromosomes and lost the late replicating (i.e., inactive) X.     

Human gamma X satellite DNA: an X chromosome specific centromeric DNA sequence

The cosmid clone, CX16-2D12, was previously localized to the centromeric region of the human X chromosome and shown to lack human X-specific satellite DNA. A 1.2 kb EcoRI fragment was subcloned from the CX16-2D12 cosmid and was named 2D12/E2. DNA sequencing revealed that this 1,205 bp fragment consisted of approximately five tandemly repeated DNA monomers of 220 bp. DNA sequence homology between the monomers of 2D12/E2 ranged from 72.8% to 78.6%. Interestingly, DNA sequence analysis of the 2D12/E2 clone displayed a change in monomer unit orientation between nucleotide positions 585–586 from a tail-to-head arrangement to a head-to-tail configuration. This may reflect the existence of at least one inversion within this repetitive DNA array in the centromeric region of the human X chromosome. The DNA consensus sequence derived from a compilation of these 220 bp monomers had approximately 62% DNA sequence similarity to the previously determined 8 satellite DNA consensus sequence. Comparison of the 2D12/E2 and 8 consensus sequences revealed a 20 bp DNA sequence that was well conserved in both DNA consensus sequences. Slot-blot analysis revealed that this repetitive DNA sequence comprises approximately 0.015% of the human genome, similar to that found with 8 satellite DNA. These observations suggest that this satellite DNA clone is derived from a subfamily of satellite DNA and is thus designated X satellite DNA. When genomic DNA from six unrelated males and two unrelated females was cut with SstI or HpaI and separated by pulsed-field gel electrophoresis, no restriction fragment length polymorphisms were observed for either X (2D12/E2) or 8 (50E4) probes. Fluorescence in situ hybridization localized the 2D12/E2 clone to the lateral sides of the primary constriction specifically on the human X chromosome.     

Unequal X Chromosomes in Bradysia Hygida (Diptera:Sciaridae) Females: Karyotype Assembly and Morphometric Analysis

The mitotic chromosomes of Bradysia hygida(Diptera:Sciaridae) neuroblast cells are described together with their morphometric data. Giemsa-stained neuroblast chromosomes from female and male larvae confirm the chromosome number of this species, 2n=8 (XX) and 2n=7 (XO), respectively. The karyotype assembly reveals two metacentric autosomic pairs, the A and B chromosome; a subtelocentric, the C chromosome, the smallest one; and a sexual unequal metacentric pair, X chromosome, in female karyotype and a one sexual metacentric X chromosome in male. The implications of the unequal X chromosome pair are discussed.     

Wiskott-Aldrich syndrome carrier detection with the hypervariable marker M27β

Summary Whole-blood cells of obligate carriers of the X-linked Wiskott-Aldrich syndrome (WAS) exhibit nonrandom inactivation of the X-chromosomes. However, because of the limited polymorphism of the probes available, the X-methylation pattern can only be determined in a restricted proportion of females. We thus analysed a large set of normal females and members of WAS families, using the recently described marker M27, which detects the hyperpolymorphic locus DXS255. The probe was used to detect differences in methylation between the active and inactive X-chromosome, and the findings were compared with the pattern obtained using the well-documented probes from the 5 end of the PGK and HPRT genes. All the normal females were found to use either X-chromosome randomly, and there was complete correlation between the three probes in the populations studied. Segregation analysis performed with M27 and other related markers in the WAS families was fully in accordance with the X-inactivation data. The use of M27, for both X-inactivation and segregation analysis of WAS kindreds, provides a basis for genetic counselling in the majority of families, including those with no surviving males.     

Assortative mating and the genetic correlation

Summary The effect of assortative mating on the genetic correlation between traits X and Y is considered. Assortation on trait X changes the magnitude of the genetic correlation but not its sign. There are two situations depending on the signs of the correlation between mates () and of the random mating genetic correlation (): 1) if sign () = sign (), then >, where is the genetic correlation at equilibrium after continued assortation, and 2) if sign () = sign (), then < . However, negative assortative mating is virtually powerless to alter the magnitude of the genetic correlation. The consequences of a mixed assortation model, e.g., high milk production females mated to fast growing males and lesser productive females mated to slower growing sires, were also studied. Mixed positive assortation always increases the genetic correlation, but negative assortation decreases it. The implications of assortative mating on correlated responses to selection and on the equilibrium covariances between relatives for pairs of traits are discussed.     

On the frequency of telomeric chromosomal changes induced by culture conditions suitable for fragile X expression

Summary Under culture conditions suitable for the expression of the fragile site Xq27, nonspecific telomeric structural changes similar to the specific fra(X) formation occurred apparently on every chromosome arm. Significant differences between individuals seem to exist. The total frequency of nonspecific terminal lesions not located on the long arm of the X chromosome was 0.22±0.17 per cell in 37 cultures examined. If telomeric lesions on Xq occur in more than 0.7% of the cells from a single culture in males and more than 1.5% of the cells from single culture in females, then this probably indicates a specific fra(X) expression. Lower percentages may be the result of nonspecific telomeric structural changes in Xq. These are expected to occur in the normal X as well and may, therefore, give rise to false positive diagnoses in the detection of hemi-, hetero-, and perhaps also homozygous fra(X) carriers.     

Lethal genes on the sex chromosomes concealed in a population of the mosquito Aedes aegypti L.

A population has been examined in which an overall parity between the sexes hides considerable between-family variation in sex ratio. A proportion of families show highly distorted sex ratios, with either an excess of females or an excess of males. Distorted sex ratios are invariably associated with mortality in the immature stages at a level appropriate to the action of recessive lethal genes. It has been shown that 26% of M-bearing (Y) chromosomes and at least 24% of m-bearing (X) chromosomes carry a recessive lethal gene.Two such genes have been investigated. l kills males and, in a cross between two heterozygotes, gives rise to a sex ratio close to 2:1 (excess families). k kills females and, in a cross between two heterozygotes, gives rise to a sex ratio close to 1:2 (excess families). Selection for excess or excess did not increase the level of sex ratio distortion.No crossing over occurs between k and the M/m locus whereas l shows 5–10% recombination with M/m. A test for allelism confirmed that l and k are not allelic. The penetrance of k is complete whereas l shows somewhat less than full penetrance. The penetrance of l has been improved by selection.The high frequency of lethals remained in the population during the two year period of study. There was evidence for heterosis preserving this frequency, the heterozygotes living longer and producing more progeny. However lethals were no longer to be found after four further years of laboratory culture.     

Chromosome behavior and cell lineage in triploid and mosaic salivary glands of species hybrids in Sciara

Summary A study of the salivary glands of triploid hybrids between females of Sciara ocellaris and males of Sciara reynoldsi throws light on several problems concerning chromosome behavior, species relationships and embryonic development. The specimens studied possess two sets of ocellaris chromosomes and one set of reynoldsi chromosomes. Three types of conditions are represented; 2X3A; 3X3A; and a mosaic possessing cells of both kinds.Heterozygosity of chromosome band pattern in the hybrids shows that the ocellaris homologs are not true sisters and that the sperm probably united with a diploid fusion nucleus composed of two polar bodies and not with the oötid nucleus. This indicates strongly that in a previously described diploid hybrid mosaic some cells developed parthenogenetically from such a fusion nucleus, while others were biparental in origin. The evidence supports the view that the initial influences or reactions of the foreign reynoldsi sperm differ from those of the ocellaris sperm immediately after entry into the egg, but that then and later the differences are relatively slight, although numerous. This agrees with our earlier evidence from the hybrids in indicating that the two parental species are separated genetically, as well as in chromosome band pattern, by many small differences.Species-specific characteristics of chromosome behavior are described which retain their specificity in the hybrids.The 2X3A cells lack a reynoldsi X. The double ocellaris X in such cells (including those in the mosaic) exhibits the peculiar features manifest by the single X in ordinary diploid XO males in the pure species (and in many other Diptera). It is pale and diffuse in structural appearance, and throughout its entire length is uniformly much greater in diameter than it is in the 3X3A cells. The possible significance of this behavior is discussed in relation to problems of sex determination (e. g., Bridges' ratio theory) and those concerning time of gene action. The structural resemblance to the puffs and bulbs found in salivary gland chromosomes is striking and raises the question as to how far morphological characteristics of chromosomes can be used as criteria of gene activity. The double X in the 2X cells of the mosaic, surrounded by 3X cells, exhibits the same peculiarities as those in a pure 2X3A male-type specimen, indicating that we are dealing with intracellular, not intercellular phenomena.Conditions in the mosaic gland support the evidence from the diploid hybrids (some described here for the first time) in indicating that the salivary gland is formed by differentiation of cells which happen to lie in the proper region, regardless of their ancestry. The triploid mosaic specimen (and also a diploid mosaic) is presumed to be a female in which the normal male-producing type of chromosome elimination occurred in one or more mitotic divisions during cleavage or later.     

Genetics of Ia-like alloantigens in chickens and linkage withB major histocompatibility complex

Two sets of backcross matings were performed to test for linkage between genes coding for the Ia-like antigens (Ia) and the B erythrocyte antigens (Ea-B) of the chicken. Evidence is presented which indicates that the la antigens are determined by a single codominant locus and that theEa-B and Ia loci are on the same chromosome. Failure to detect a single recombinant between theEa-B and Ia loci out of 208 progeny suggests close linkage of the two genes with a map distance of up to about 2 centimorgans. The Ia genes are thus included in theB major histocompatibility complex of the chicken.     

Between-family variation in sex ratio in the Trinidad (T-30) strain of Aedes aegypti (L.) indicating differences in sensitivity to the meiotic drive gene M D

Sex ratio in the Trinidad (T-30) strain of Aedes aegypti has remained constant at around 43% during seventeen years of laboratory culture. The divergence from 50% is due to meiotic drive by the M ^D gene on the Y chromosome. The driving Y chromosome gives a much more distorted sex ratio (mean = 5.7%) when coupled with the highly sensitive X chromosomes from strain 64. This was demonstrated in all of 98 families tested, indicating that all or most of the Y chromosomes in T-30 carry the M ^D gene. Consequently the low level of sex ratio distortion in T-30 must be due to resistance to M ^D.Crosses made within T-30 demonstrated wide differences in sex ratio between families, depending on the sensitivity of the male parent's X chromosome to M ^D. However, sex ratios were not continuously variable but fell within fairly discrete categories. Thus, X chromosomes could be classified according to the modal sex ratios associated with them: m ^s3 (12.5%), m ^s2 (32.5%), m ^s1 (40%), m ^r1 (47.5%) m ^r2 (57.5%).The different sex ratio categories were more discrete in the families of sib matings than from random matings, suggesting the possibility of background modification of what is essentially a balanced polymorphism. Evidence is presented suggesting that the polymorphism could be due to interaction at two loci. A further X variant, m ^s4 (<10%) characterised strain 64 but was absent from T-30.A comparison of fertility between the different sex ratio categories in T-30 established that sex ratio distortion was not caused by differential mortality after fertilisation.     

Identification of functioning sweat pores and visualization of skin temperature patterns in X-linked hypohidrotic ectodermal dysplasia by whole body thermography

Summary In this preliminary study, non-invasive infrared thermography has been used to visualize individual sweat pores and whole body skin temperature patterns in subjects with X-linked hypohidrotic ectodermal dysplasia (XHED) and normal controls. The findings in eight obligate heterozygotes and four affected males were compared to six normal female controls and to six non-manifesting females at risk for carrier status. Sweat secretion from individual pores in circumscribed areas was imaged using a high spatial resolution SPRITE infrared detector system working in the 8–14 m band. In seven out of eight obligate heterozygotes, skin areas devoid of active sweat glands were found on the face, the hands or the trunk. Tear front movement over the cornea was also visualized and abnormal patterns were identified in obligate heterozygotes. Whole body skin temperature patterns, obtained with an Agema 780 Medical Thermovision system, identified abnormal skin temperature distributions, including characteristic aberrant cas-cade back patterns, in obligate carriers. Two out of six at risk females had skin temperature patterns comparable with obligate heterozygotes and we have tentatively concluded that they are carriers. Thermal imaging may be used for the examination of at risk non-manifesting females in families with a single affected male. The results of this study suggest that the random X-inactivation in females with XHED, as well as producing relatively large skin areas with sweat pore aplasia, is also associated with abnormal temperature patterns that are consistent with altered peripheral vascular perfusion.     

Ovarian development in Culex nigripalpus and its implication for disease transmission

Ovarian development was investigated in wild and colonized Culex nigripalpus Theobald females. Blood-seeking females with morphologically distinct nulliparous, parous and resorbed ovarian follicles (as opposed to females with degenerating follicles) were collected from the field all year, indicating year around gonoactivity. During the cooler months a larger number of females with resorbed follicles were collected from the field than in warmer months. Laboratory experiments showed that resorbed ovarian follicles occurred in sucrose fed females when deprived of a blood meal after emergence. These resorbed ovarian follicles were functional, since most of them began to develop and mature after the females took a blood meal to repletion. Among females fed a partial blood meal, some did not begin ovarian development and, therefore, exhibited gonotrophic dissociation. Females fed partial blood meals had similar patterns of ovarian development, irrespective of temperature at which they were maintained. Implications of occurrence of females with resorbed ovarian follicles and disease transmission are discussed.Supported in part by National Institutes of Health Research Grants No. A1-06587 and RR-07021. A contribution of the Florida Medical Entomology Laboratory, Vero Beach, Florida, Florida Agriculture Experimental Station Journal Series No. 2367     

Notes on chromosome behaviour in the spermatogenesis of the damselflyEnallagma cyathigerum (Charp.) (Odonata: Coenagrionidae)

The chromosome number in the damselflyEnallagma cyathigerum (Charp.) is 2n =27, 2n =28, n =14 (13). The sex determining mechanism is XX-XO, the X segregates postreductionally in the male.     

Probable male heterogamety in the deep-sea fish Bathylagus wesethi (Teleostei: Bathylagidae)

A presumed XY chromosome pair is described fromt estis squashes from the mesopelagic deep-sea fish Bathylagus wesethi, whose 2N chromosome number was determined as 34-XY. Although the metacentric X-chromosome is the largest in the entire compliment, the Y is the smallest and only acrocentric element. The positive heteropycnosis of the sex elements was not easily distinguishable in the nuclei of first meiotic prophase. Tetraploid nuclei were observed in peripheral supporting cells of the testis. Males of at least two other congeners have similar karyotypes.     

Two phases of DNA replication in human cells

The course of DNA synthesis in the chromosomes was studied in synchronized human lymphocyte cultures, by means of the BrdU-Hoechst-Giemsa method. In comparing replication patterns and G-banding it was found that with regard to banding the process of DNA replication can be divided into two separate phases, an early replication period which is characterized by DNA synthesis in R bands of the autosomes and active X chromosome, and a late replication period which concerns the G-positive regions of the autosomes and all the bands of the heterochromatic X and Y chromosomes. No overlapping was found between the two phases mentioned. The possible role of regulatory mechanisms was discussed.     

The chromosomal localization of human β-galactosidase revisited: a locus for β-galactosidase on human chromosome 3 and for its protective protein on human chromosome 22

Summary A series of man-Chinese hamster and man-mouse somatic cell hybrids was investigated to study the localization of the genes coding for the human lysosomal enzyme -galactosidase (EC 3.2.1.23) and for its protective protein. Using a monoclonal antibody, raised against human placental -galactosidase, it was observed that the structural locus for the -galactosidase polypeptide is located on chromosome 3. The nature of the involvement of chromosome 22 in the expression of human -galactosidase was elucidated by metabolic labelling of the hybrids with radioactive amino acids, immunoprecipitation with monoclonal and polyclonal antibodies against -galactosidase, followed by analysis via gel electrophoresis and fluorography.The data show that the presence of chromosome 22 coincides with the presence of a 32 kd protein. This polypeptide, the protective protein was previously shown to be intimately associated with human -galactosidase. In addition, the protective protein was found to be essential for the in vivo stability of -galactosidase by aggregating -galactosidase monomers into high molecular weight multimes. Both chromosome 3 and 22 are therefore necessary to obtain normal levels og -galactosidase activity in human cells.     

Assignment of human ferritin genes to chromosomes 11 and 19q13.3→19qter

Summary Extracts of hamster-human and mouse-human hybrids, some with translocations involving chromosome 19, have been assayed for both human spleen ferritin (rich in L subunits) and human heart ferritin (rich in H subunits). Hybrid lines retaining part of the long arm of chromosome 19 including the region 19q13.319qter produced human L type ferritin. This confirms the previous assignment of the ferritin gene to chromosome 19 (Caskey et al. 1983). However, lines retaining chromosome 11 were found to contain human H type ferritin suggesting that the gene for the H subunit is on this chromosome. The presence of chromosome 6 was not necessary for the expression of either H or L type human ferritin. It thus seems unlikely that the gene for idiopathic haemochromatosis is a ferritin gene.