Linkage studies in Menkes' disease. The Xg blood group system and C-banding of the X chromosome

The Meaning of "Cause" in Genetics

Causation has multiple distinct meanings in genetics. One reason for this is meaning slippage between two concepts of the gene: Mendelian and molecular. Another reason is that a variety of genetic methods address different kinds of causal relationships. Some genetic studies address causes of traits in individuals, which can only be assessed when single genes follow predictable inheritance patterns that reliably cause a trait. A second sense concerns the causes of trait differences within a population. Whereas some single genes can be said to cause population-level differences, most often these claims concern the effects of many genes. Polygenic traits can be understood using heritability estimates, which estimate the relative influences of genetic and environmental differences to trait differences within a population. Attempts to understand the molecular mechanisms underlying polygenic traits have been developed, although causal inference based on these results remains controversial. Genetic variation has also recently been leveraged as a randomizing factor to identify environmental causes of trait differences. This technique-Mendelian randomization-offers some solutions to traditional epidemiological challenges, although it is limited to the study of environments with known genetic influences.

A family with mental retardation, variable macrocephaly and macro-orchidism, and linkage to Xq12-q21

A family with X linked inheritance of mental retardation (XLMR) is presented. There are 10 mentally retarded males and two affected females in two generations. There are four obligatory carriers, one of whom is described as "slow". Most affected males show macrocephaly and macro-orchidism, which are typical signs of the fragile X syndrome, but have been tested cytogenetically and by analysis of the FMR1 gene and do not have this syndrome. However, some normal males in the family also exhibit macro-orchidism and macrocephaly. Linkage analysis using markers derived from the X chromosome indicates that the causative gene in this family is located in the proximal long arm of the X chromosome, in the interval Xp11-q21. Maximum lod scores of 2.96 with no recombination were found at three loci in Xq13-q21: DXS1111, DXS566, and DXS986. Recombination was observed with DXS1002 (Xq21.31) and DXS991 (Xp11.2), loci separated by about 30 Mb. Although isolation of the gene in this family will be difficult because of the size of the region involved, the localisation should be helpful in investigating other similar families with XLMR, macrocephaly, and macro-orchidism not attributable to FMR1.

Translocation t(X;21)(q13.3; p11.1) in a girl with Menkes disease

A girl with a 46,X,t(X;21) (q13.3;p11.1) karyotype presented with skin redundancy, especially in the neck, prominent occiput and micrognathia, and later developed hypotonia, hypopigmentation, sparse scalp hair, and profound mental retardation characteristic of Menkes disease. Her serum copper (14 microg/dl) and ceruloplasmin (9 mg/dl) levels were extremely low. Fluorescent in situ hybridization analysis with a 100-kb P1-derived artificial chromosome probe containing the Menkes disease gene demonstrated three twin-signals, one on the normal X chromosome and one each on derivative chromosomes X and 21, indicating that the Xq13.3 breakpoint was located within the gene. Replication pattern analysis showed that the normal X chromosome was late replicating, whereas the derivative X chromosome was selectively early replicating. These results indicated that Menkes disease in our patient resulted from a de novo translocation that disrupts the disease gene.

Metabolic and molecular bases of Menkes disease and occipital horn syndrome

Menkes disease and occipital horn syndrome (OHS) are related disorders of copper transport that involve abnormal neurodevelopment, connective tissue problems, and often premature death. Location of the gene responsible for these conditions on the X chromosome was indicated by pedigree analysis from the time of these syndromes' earliest descriptions. Characterization of an affected female with an X-autosomal translocation was used to identify the Menkes/OHS gene, which encodes a highly evolutionarily conserved, copper-transporting P-type ATPase. The gene normally is expressed in nearly all human tissues, and it localizes to the trans-Golgi network of cells. However, in over 70% of Menkes and OHS patients studied, expression of this gene has been demonstrated to be abnormal. Major gene deletions detectable by Southern blotting account for 15-20% of patients, and an interesting spectrum of other mutations is evident among 58 families whose precise molecular defects have been reported as of this writing. The center region of the gene seems particularly prone to mutation, and those that influence mRNA processing and splicing appear to be relatively common. Further advances in understanding the molecular and cell biological mechanisms involved in normal copper transport may ultimately yield new and better approaches to the management of these disorders.

Urologic abnormalities in Menkes' kinky hair disease: report of three cases

Menkes' kinky hair disease is a rare congenital disorder of copper metabolism with X-linked recessive inheritance. It is well known that it is frequently associated with urologic abnormalities. The authors experienced three such cases, but each of them was different. Multiple bladder diverticula, right vesico-ureteral reflux, and right hydronephrosis were noted on the first baby boy. In the second case, hematomas in the left kidney, pelvis, ureter and the adipose capsule, which were thought to be the abnormality of vessels, were noted in the neonatal period. In the third body, multiple bladder diverticular were noted at the age of 1 year. One year, 10 months later, a spontaneous rupture at the huge diverticulum occurred.

Menkes disease: recent advances and new aspects

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Menkes disease: recent advances and new insights into copper metabolism

Copper is a trace element necessary for the normal function of several important enzymes but copper homeostasis is still poorly understood. In recent years remarkable progress has been made in this field following the isolation of the gene defective in Menkes disease. Menkes disease and occipital horn syndrome are X-linked recessive disorders, demonstrating the vital importance of copper, which is also highly toxic in excessive amounts. Its destructive effects are reflected in the autosomal recessive Wilson's disease. Progressive neurodegeneration and connective tissue disturbances are the main manifestations of Menkes disease. Although many patients present a severe clinical course, variable forms can be distinguished, and the occipital horn syndrome has been suggested to be a mild allelic form. The Menkes locus is mapped to Xq13.3 and the gene defective in Menkes disease has been isolated by positional cloning. The gene is predicted to encode an energy-dependent copper-binding protein, the first intracellular copper transporter described in eukaryotes. Isolation of the gene and subsequent characterization of the exon-intron organization now enables the establishment of DNA-based diagnostic methods. Furthermore, identification of the Menkes disease gene led to other important findings, such as isolation of its mouse homologue, confirming the allelic relationship between Menkes disease and occipital horn syndrome, and isolation of the defective genes in Wilson's disease and its rat homologue.

Zinc, copper and selenium in reproduction

Of the nine biological trace elements, zinc, copper and selenium are important in reproduction in males and females. Zinc content is high in the adult testis, and the prostate has a higher concentration of zinc than any other organ of the body. Zinc deficiency first impairs angiotensin converting enzyme (ACE) activity, and this in turn leads to depletion of testosterone and inhibition of spermatogenesis. Defects in spermatozoa are frequently observed in the zinc-deficient rat. Zinc is thought to help to extend the functional life span of the ejaculated spermatozoa. Zinc deficiency in the female can lead to such problems as impaired synthesis/secretion of (FSH) and (LH), abnormal ovarian development, disruption of the estrous cycle, frequent abortion, a prolonged gestation period, teratogenicity, stillbirths, difficulty in parturition, pre-eclampsia, toxemia and low birth weights of infants. The level of testosterone in the male has been suggested to play a role in the severity of copper deficiency. Copper-deficient female rats are protected against mortality due to copper deficiency, and the protection has been suggested to be provided by estrogens, since estrogens alter the subcellular distribution of copper in the liver and increase plasma copper levels by inducing ceruloplasmin synthesis. The selenium content of male gonads increases during pubertal maturation. Selenium is localized in the mitochondrial capsule protein (MCP) of the midpiece. Maximal incorporation in MCP occurs at steps 7 and 12 of spermatogenesis and uptake decreases by step 15. Selenium deficiency in females results in infertility, abortions and retention of the placenta. The newborns from a selenium-deficient mother suffer from muscular weakness, but the concentration of selenium during pregnancy does not have any effect on the weight of the baby or length of pregnancy. The selenium requirements of a pregnant and lactating mother are increased as a result of selenium transport to the fetus via the placenta and to the infant via breast milk.

Menkes' disease: perspective and update on a fatal copper disorder

Although the causes of the abnormal copper utilization seen in Menkes' disease remain unknown, a candidate gene reported by three laboratories has narrowed the search for the defective or missing factor. These genetic studies also suggest that a copper ATPase may be important in normal copper metabolism.

Isolation of a candidate gene for Menkes disease that encodes a potential heavy metal binding protein

Menkes disease is a lethal-X linked recessive disorder associated with copper metabolism disturbance. We have recently mapped two chromosome breakpoints related to this disease in a 1 megabase yeast artificial chromosome contig at Xq13.3. We now report the construction of a phage contig and the isolation of candidate partial cDNAs for the Menkes disease gene. The candidate gene expresses an 8 kb message in all investigated tissues, and deletions were detected in 16% of 100 unrelated Menkes patients. The deduced partial protein sequence shared the GMTCXXC motif with bacterial metal resistance operons, suggesting a potential heavy metal binding protein. These findings should lead to more accurate prenatal diagnosis of this severe disease and a better understanding of the cellular homeostasis of essential heavy metals.

Menkes disease: an X-linked neurological disorder of the copper metabolism

Menkes disease is an X-linked, recessive disturbance of copper metabolism associated with a progressive clinical course and abnormal hair. The disease is dominated by neurological symptoms combined with connective tissue manifestations, most of which can be explained by the lack of important copper enzymes. Despite excessive accumulation of the metal in various tissues, a functional copper deficiency is evident, probably caused by a defective intracellular copper transport protein of unknown nature. The molecular basis of the copper disturbance has proven difficult to define and will most likely have to await cloning of the gene. The chromosomal region of interest has now been narrowed down to a sub-band on the long arm of the chromosome (Xq13.3), and positional cloning is in progress in a number of laboratories including our own. Identification of the Menkes gene will be of importance for our understanding of the cellular handling of copper and other trace elements.

Mapping of the Menkes locus to Xq13.3 distal to the X-inactivation center by an intrachromosomal insertion of the segment Xq13.3-q21.2

During a systematic chromosomal survey of 167 unrelated boys with the X-linked recessive Menkes disease (MIM 309400), a unique rearrangement of the X chromosome was detected, involving an insertion of the long arm segment Xq13.3-q21.2 into the short arm at band Xp11.4, giving the karyotype 46,XY,ins(X) (p11.4q13.3q21.2). The same rearranged X chromosome was present de novo in the subject's phenotypically normal mother, where it was preferentially inactivated. The restriction fragment length polymorphism and methylation patterns at DXS255 indicated that the rearrangement originated from the maternal grandfather. Together with a previously described X;autosomal translocation in a female Menkes patient, the present finding supports the localization of the Menkes locus (MNK) to Xq13, with a suggested fine mapping to sub-band Xq13.3. This localization is compatible with linkage data in both man and mouse. The chromosomal bend associated with the X-inactivation center (XIC) was present on the proximal long arm of the rearranged X chromosome, in line with a location of XIC proximal to MNK. Combined data suggest the following order: Xcen-XIST(XIC), DXS128-DXS171, DXS56-MNK-PGK1-Xqter.

First-trimester diagnosis of Menkes disease: intermediate copper values in chorionic villi from three affected male fetuses

Chorionic villus samples with copper contents of 1.91, 4.2, 5.6, and 6.3 ng/mg were observed in four cases with male karyotypes. These values were outside the range for unaffected males (0.30-0.85 ng/mg), and three of them were outside the control range (0.20-2.39 ng/mg). But these three values were below the values previously observed for affected Menkes fetuses (12.0-24.8 ng/mg). Follow-up by 64Cu uptake studies on the amniotic fluid cells was performed in three of these cases. A combination of 64Cu uptake and chase experiments on the amniotic fluid cells showed more convincingly than 64Cu uptake per se the direct copper values of 4.2 and 5.6 ng/mg to correspond to affected fetuses. Amniotic fluid cells from the male fetus with the CV copper value of 1.9 ng/mg showed normal results. The CV copper value of 6.3 ng/mg was considered pathognomonic for Menkes disease. The pregnancy was terminated, and the diagnosis was confirmed on fetal fibroblasts. Maternal deciduum prepared from the placentae showed in one of the cases with an affected fetus copper values ranging from 1.5 to 5.7 ng/mg. In six additional diagnostic cases, the copper content was determined in both CV samples and maternal deciduum. In three of these cases with normal CV sample copper, maternal decidua values of 4.85-7.8 ng/mg copper were observed. These results show that maternal deciduum contamination of a CV sample could cause a false-positive diagnosis.

Kinky hair disease: twenty five years later

Kinky hair disease, first described in 1962, is a sex-linked disorder, with its gene located on the long arm of the X chromosome close to the centromere. The condition is marked by intellectural deterioration, seizures, and poorly pigmented, friable hair. Bony changes, resembling scurvy, tortuosities of the cerebral and systemic vasculature, and diverticuli of the bladder are also seen. Biochemically, the most diagnostic alteration is a marked reduction in blood copper and ceruloplasmin levels. The mechanism for the low serum copper has not been defined. Even though parental copper administration will correct the biochemical abnormalities, such treatment will not arrest cerebral deterioration.

Chromosome maps of man and mouse, III

Data on loci whose positions are known in both man and mouse are presented in the form of chromosomal displays, a table, and autosomal and X-chromosomal grids. At least 40 conserved autosomal segments with two or more loci, as well as 17 homologous X-linked loci, are now known in the two species, in which mitochondrial DNA is also highly conserved. Apart from the Y, the only chromosome now lacking a conserved group is human 13. Human 17 has a single conserved group which includes both short and long arms, and so may have remained largely intact in mammalian evolution. Human and mouse chromosomal maps show the approximate locations of homologous genes while the mouse map also shows the positions of translocations used in gene location.

Genetic mapping of nine DNA markers in the q11----q22 region of the human X chromosome

We have ordered nine polymorphic DNA markers within detailed map of the proximal part of the human X chromosome long arm, extending from band q11 to q22, by use of both physical mapping with a panel of rodent-human somatic hybrids and multipoint linkage analysis. Analysis of 44 families (including 17 families from the Centre d'Etude du Polymorphisme Humain) provided highly significant linkage data for both order and estimation of map distances between loci. We have obtained the following order: DXS1-DXS159-DXYS1-DXYS12-DXS3-(DXS94 , DXS178)-DXYS17. The most probable location of DXYS2 is between DXS159 and DXS3, close to DXYS1 and DXYS12. The high density of markers (nine loci within 30 recombination units) and the improvement in the estimation of recombination frequencies should be very useful for multipoint mapping of disease loci in this region and for diagnostic applications.

Menkes syndrome in a girl with X-autosome translocation

We report on a girl with Menkes syndrome (M.S.) and X-2 reciprocal translocation. We conclude that the probable locus for M.S. gene is at band Xq13. This case and other previous case reports of X-linked disorders in females suggest that chromosome analysis is indicated in all females who present with manifestations of a known X-linked lethal condition in order to detect a possible associated balanced X-autosome translocation.

Genetic epidemiology of Menkes disease

Copper incorporation studies were performed on individuals from 58 pedigrees, comprising 140 sibships. As previously reported, there is considerable overlap between heterozygotes and normal homozygotes. Segregation analysis supports recessive inheritance of disease, with residual heritability for 64Cu uptake in cultured cells. The population frequency of sporadic cases is compatible with the 1/3 expected for an X-linked lethal with equal mutation rates in egg and sperm, which implies a mutation rate of 6.7 X 10(-6)/gamete/generation. The parameters estimated here are likely to provide the best basis for genetic counseling until more reliable carrier tests are performed on a systematic sample from a large, defined population.

On the genetic length of the short arm of the human X chromosome

Published estimates of the length of the human X chromosome are unreliable because they are based on scanty linkage data and complex assumptions about the frequency and distribution of chiasmata in female meiosis. In recent months we have established linkage between restriction fragment length polymorphisms (RFLPs) and several genes on the short arm of the X chromosome. These and previous data can be combined to construct a continuous linkage map spanning the short arm from the Xg gene to the centromere. They suggest that the genetic length of the Xg-Xcen segment may be in the order of 75-90 cM.

Menkes' X-linked disease: prenatal diagnosis and carrier detection

Increased 64Cu uptake into cultured cells is a biochemical marker for mutant cells in Menkes' disease (McKusick 30940). Using this marker selective prenatal diagnosis has been carried out in more than 80 at-risk pregnancies. The 64Cu uptake into cultures from affected male fetuses is however, negatively correlated to the fetal age at amniocentesis. After the 18th week of gestation the risk of false negatives is significant. Using copper uptake into uncloned cultures, a number of obligate and possible carriers showed significantly increased values, but the range of values of obligate carriers considerably overlapped those of the normal controls. All values of normal controls were within a limited range and values above the upper limit in females at risk must, therefore, be caused by mutant cells and establish the carrier diagnosis. However, the extreme skewing of the distribution towards normal values in obligate carriers indicates a strong selection against the mutant cell type and this will hamper the detection of all female carriers in risk families. C-banding heteromorphism of the X-chromosome provides a supplementary carrier detection method. Linkage analysis in five Danish families demonstrated a close physical relationship between the gene for Menkes' disease and the centromere region. By comparative gene mapping (mouse/man) the most likely localization of the gene for Menkes' disease can be suggested to be in band q13 on the long arm of the human X-chromosome. This regional assignment facilitates the choice of appropriate X-specific DNA probes in search for linkage at the DNA level.