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Tetrasomy X

March 02, 2023

Tetrasomy X, also known as 48,XXXX, is a chromosomal disorder in which a female has four, rather than two, copies of the X chromosome. It is associated with intellectual disability of varying severity, characteristic "coarse" facial features, heart defects, and skeletal anomalies such as increased height, clinodactyly (incurved pinky fingers), and radioulnar synostosis (fusion of the long bones in the forearm). Tetrasomy X is a rare condition, with few medically recognized cases; it is estimated to occur in approximately 1 in 50,000 females.

Tetrasomy X
Other names48,XXXX
Karyotype of tetrasomy X
SpecialtyMedical genetics 
SymptomsIntellectual disability, facial dysmorphology, heart defects, skeletal anomalies, tall stature
Usual onsetConception
DurationLifelong
CausesNondisjunction
Diagnostic methodKaryotype
Differential diagnosisTrisomy X, pentasomy X, Down syndrome

The disorder has a wide range of symptoms, with phenotypes (presentations) ranging from slight to severe. It is suspected to be underdiagnosed, as are other sex chromosome disorders. Life outcomes vary; some women have had education, employment, and children, while others have remained dependent into adulthood. Life expectancy does not appear to be substantially reduced. Tetrasomy X has phenotypic overlap with a number of more common disorders, such as trisomy X and Down syndrome, and diagnosis is usually unclear prior to chromosomal testing.

Tetrasomy X is generally not inherited, but rather occurs via a random event called nondisjunction during gamete or zygote development. The formal term for the karyotype[note 1] observed in tetrasomy X is 48,XXXX, as the condition is typified by a 48-chromosome complement rather than the 46 chromosomes observed in normal human development.

Presentation

Tetrasomy X has a variable presentation with a spectrum of severity, and lacks obvious defining clinical abnormalities that can lead to a diagnosis in the absence of testing.[2] Recognizable characteristics include increased height and mild intellectual disability; the average adult height in tetrasomy X is 169 cm (5 ft 6+12 in)[2] compared with a reference height of around 162 cm (5 ft 4 in) for women in the Anglosphere,[3][4] while a review of the first 27 women to be diagnosed with tetrasomy X found IQs ranging from 30 to 101 with a mean of 62.[5] Although some degree of intellectual disability is traditionally characteristic, two medically reported cases were of normal intelligence,[6] and patient organizations report members who are only afflicted by specific learning disabilities such as dyslexia.[7] Speech and language delays may be associated with tetrasomy X, although the matter is unclear; some reports describe speech and language abilities in line with overall intelligence,[2] while others describe problems independent of intelligence, in particular with subjects who have normal intelligence but significant language delays.[6][8]

A number of facial and musculoskeletal anomalies are common to all aneuploidies of the sex chromosomes,[note 2] including X chromosome polysomy such as tetrasomy X.[10] Epicanthic folds (additional skin folds in the corners of the eyes) and hypertelorism (wide-spaced eyes) are frequent facial features.[2] Multiple reports have described the characteristic facial features as "coarse".[11][12] These dysmorphic features are relatively mild and do not necessarily "stand out from the crowd";[7] in general, X chromosome polysomy is not associated with severe physical dysmorphism, although tetrasomy and pentasomy X tend to be somewhat more noticeable in this respect than the milder and more frequent trisomy X.[2][10] Hypotonia (low muscle tone), often severe and early-onset, is a commonly observed musculoskeletal abnormality.[13] Clinodactyly, the bending inwards of the pinky finger, and radioulnar synostosis, the fusion of the long bones in the forearm, are frequent.[2] Dental abnormalities are associated with the syndrome, in particular taurodontism, where the pulp of the teeth is enlarged and extends into the roots.[14] These findings are not unique to tetrasomy X; epicanthic folds and hypertelorism are seen in trisomy X,[10] while clinodactyly and radioulnar synostosis are findings common to all sex chromosome aneuploidies[15] and taurodontism is prevalent in X-chromosome polysomy specifically.[16]

Heart defects of various types have been associated with the syndrome, albeit at unclear prevalence. A patient organization reports approximately one-third of cases in its membership had congenital heart defects, a larger proportion than reported in the medical literature.[7] Frequently reported heart defects include patent ductus arteriosus[11] and ventricular septal defects.[17] Kidney and bladder issues have been loosely associated with the syndrome,[7] as has epilepsy.[18] Epilepsy in sex chromosome aneuploidies generally is mild, amenable to treatment, and often attenuates or disappears with time.[19] There is also a potential association between tetrasomy X and autoimmune disorders, particularly lupus, which has been recorded in two women with tetrasomy X and appears to become more common as the number of X chromosomes increase.[20]

The psychological and behavioural phenotype of tetrasomy X is understudied. Some reports describe girls and women with tetrasomy X as generally placid and pleasant, while others report emotional lability and inappropriate behaviour.[2] Family background and environment has a significant impact on behaviour, and cases with severe behavioural dysfunction frequently have similarly dysfunctional unaffected relatives. Expressive language delays and executive dysfunction are common heralds of behavioural issues, due to the difficulties they cause for educational, vocational, and social functioning.[6] In both men and women X-chromosome polysomy is known to be associated with psychosis,[21] and a case is known of a girl with tetrasomy X and childhood-onset schizophrenia.[22] Parent reports describe children and young adults who are generally pleasant and affectionate yet shy, and have issues relating to temper tantrums, mood swings, and frustration at an inability to communicate.[7]

Tetrasomy X can interfere with pubertal development. Of the adult women recorded with tetrasomy X, half have had normal pubertal development with menarche at an appropriate age, while the other half have had some form of pubertal dysfunction[2] such as primary amenorrhea, irregular menstrual cycles, or incomplete development of secondary sex characteristics.[7] Premature ovarian failure, or early menopause, has been recorded.[23] In trisomy X, premature menopause has occurred between the ages of 19 and 40,[10] while in tetrasomy X, it has been recorded as young as 15.[24] In tetrasomy X as for other causes of premature menopause or incomplete puberty, some writers have recommended hormone replacement therapy.[23] Fertility in tetrasomy X is possible. In the first discussion of the phenomenon, three cases have been reported of women bearing children. One woman had two children, one with a normal chromosome complement and the other with Down syndrome. Two women had one child each; one had a daughter with normal chromosomes, while the other had a stillbirth with an omphalocele.[2] An additional woman was reported as having three children, all with normal chromosomes.[7]

Causes

 
Nondisjunction in tetrasomy X

Tetrasomy X, like other aneuploidy disorders, is caused by a process called nondisjunction. Nondisjunction occurs when homologous chromosomes or sister chromatids fail to separate properly during meiosis, the process that produces gametes (eggs or sperm), and result in gametes with too many or too few chromosomes.[25] In the specific case of sex chromosome tetrasomy and pentasomy, nondisjunction occurs multiple times with the same parent; for tetrasomy X specifically, all known cases have inherited either three maternal X chromosomes and one paternal, or four maternal X chromosomes with no paternal contribution.[26][27] The cause of this specific pattern of inheritance is unclear. An early research group proposed that due to the gap in prevalence between the related conditions 49,XXXXY, which has a similar prevalence to tetrasomy X, and pentasomy X, which is far rarer, the paternal X chromosomes may frequently be lost in high-level aneuploidy.[28] More recently, speculation has been based in genomic imprinting, with the suggestion that a similarly high number of paternal X-chromosomes would be incompatible with life.[29] Nondisjunction can also occur after conception, which frequently results in a mosaic karyotype.[30]

Nondisjunction is related to advanced maternal age.[31] In common aneuploidies such as Down syndrome, the relationship with maternal age is extensively studied.[32] In Klinefelter syndrome, the most common and most studied sex chromosome aneuploidy, incidence increases substantially as maternal age rises.[33] Less is understood about the role of maternal age in sex chromosome tetrasomy and pentasomy conditions, primarily due to their rarity, and no clear relationship has been established.[5][34]

Tetrasomy X is generally a random occurrence and does not recur in the same family. In rare cases, it may be related to a mother having trisomy X, mosaic or otherwise. It is not caused by environmental factors.[7]

Diagnosis

Chromosome aneuploidies such as tetrasomy X are diagnosed via karyotype,[35] the process in which chromosomes are tested from blood, bone marrow, amniotic fluid, or placental cells.[36] Due to significant differential diagnosis potential, diagnosis cannot be made on the basis of phenotype alone.[2]

Differential diagnosis

Tetrasomy X has many possibilities for differential diagnosis, with multiple other conditions overlapping with the phenotype. One differential diagnosis is trisomy X, in which a female has three copies of the X chromosome. The two conditions have overlapping phenotypes with a broad range of severity.[37] Both are associated with hypotonia, mild facial anomalies such as hypertelorism and epicanthic folds, increased height, premature ovarian failure, and some reduction in intelligence. However, the phenotype of tetrasomy X is generally more severe than that of trisomy X.[10] In addition, while both are associated to some degree with tall stature, the association is much stronger for trisomy X.[7][38] The clinical portrait is made more complex by the possibility of mosaicism, where both 47,XXX and 48,XXXX cell lines are present; such cases frequently, but not certainly, present closer to the tetrasomy than trisomy profile.[39] As well as simple 47,XXX/48,XXXX mosaicism, complex 46,XX/47,XXX/48,XXXX mosaicism has been reported.[40]

Pentasomy X, a karyotype of five X chromosomes, is another major differential diagnosis. The phenotype of pentasomy X is similar but on average more severe. Intellectual disability is more severe, with an average IQ of 50, and pubertal delay or incomplete puberty appears more common.[2] Unlike other X-chromosome polysomies, pentasomy X is associated with short stature.[10] Similarly, pentasomy X is commonly associated with findings that are infrequent in tetrasomy X such as microcephaly and intrauterine growth restriction.[13] Cases of 48,XXXX/49,XXXXX mosaicism have been reported, and are often categorized as cases of pentasomy X.[41] More complex mosaics have been reported, such as 47,XXX/48,XXXX/49,XXXXX[17] and 45,X0/46,XX/47,XXX/48,XXXX/49,XXXXX.[42]

An additional differential diagnosis in some cases is Down syndrome. Some cases of tetrasomy X have been described as having "a false air of trisomy 21" (the underlying chromosomal aneuploidy in Down's), and karyotyping resulting in a diagnosis of tetrasomy X has been performed due to suspicion of Down syndrome.[37][43] However, this is only a differential diagnosis for a subset of cases, while others have more normal phenotypes or abnormalities inconsistent with the Down's profile.[37] The matter is complicated by the observation that a number of women with X chromosome polysomy, including tetrasomy X, have had children with Down syndrome.[2][44]

Prognosis

The long-term prognosis for tetrasomy X appears generally good. While life expectancy is unclear, patients have been diagnosed in their 50s and 60s, and long-term follow-up of individual cases shows healthy aging with good physical health.[5][45] Some women live fully independent lives, while others require more persistent support from parents and caregivers, consistent with other intellectual disability syndromes of comparable severity.[7] Many are able to work part-time, and some full-time; some young women attend tertiary education, mostly vocational.[46] Girls and women with tetrasomy X and good outcomes are typified by supportive family environments and strong personal advocacy for their success; "[t]he children have been exposed to many varied activities and experiences and are praised for their strengths, while their limitations and delays are minimised".[2]

Epidemiology

Tetrasomy X is estimated to occur in around 1 in 50,000 females.[47] Considering the variable phenotype, tetrasomy X support organizations and researchers think it likely there are many cases that have not come to medical attention.[7] This is common to all sex chromosome aneuploidies, which have very low diagnosis rates compared to their overall population prevalence.[10] Overall, sex chromosome tetrasomy and pentasomy disorders occur in 1 in 18,000 to 1 in 100,000 male live births, and are somewhat rarer in females.[2][48]

Tetrasomy X only occurs in females, as the Y chromosome is in most cases necessary for male sexual development.[49][note 3]

History

Tetrasomy X was first recorded in 1961 in two intellectually disabled women residing in an institution.[53] The late 1950s and early 1960s were a period of frequent ascertainment of previously unknown sex chromosome aneuploidies, with the discovery of the 48,XXXX karyotype being alongside that of 45,X0,[54] 47,XXY,[55] and 47,XXX[56] in 1959, 48,XXYY in 1960,[57] and 47,XYY the same year.[58] One of the two women first diagnosed with tetrasomy X was followed up twenty-six years later in her late fifties, by which time she had left the institution and was living semi-independently with her sister; she was in good physical health, had experienced menarche and menopause at typical ages (14 and 50), and showed no signs of cognitive decline.[45]

Much of the medical literature for tetrasomy X dates to the 1960s and 1970s, an era of particular interest in and research on sex chromosome aneuploidy.[7] Early reports were frequently discovered during chromosome screenings in institutions for the intellectually disabled.[5][59][60] The early preference for diagnosis of sex chromosome aneuploidy in selected samples, such as institution residents and prisoners, led to a biased perspective on the conditions that painted an unduly negative portrait of their phenotypes and prognoses. Further research on sex chromosome aneuploidy via unselected samples such as newborn screening allowed for major conditions such as XYY syndrome, Klinefelter syndrome, and trisomy X to be re-defined by more representative phenotypes; however, rarer conditions such as tetrasomy X were not ascertained in any such studies, and therefore the medical literature continues to describe cases that were diagnosed due to developmental or behavioural issues.[2] Aspects of the early studies remain accepted; a 1969 proposal that each supernumerary X chromosome reduces IQ by an average of 15 points[61] is still used as a rule of thumb.[2][7]

Sex chromosome tetrasomy and pentasomy conditions have consistently received little attention compared to the more common trisomy conditions. Research into conditions such as tetrasomy X has been stymied by biased samples, outdated information, and a lack of publications above the case report level.[2] Dedicated patient and family support groups, such as Unique[7] and the Tetrasomy and Pentasomy X Support Group,[62] began to appear online in the early 2000s. A patient registry in the United Kingdom was established in 2004, amidst concerns that little serious research had been conducted on tetrasomy X for many years.[7]

Diagnosis of sex chromosome aneuploidies is increasing,[16] as is the number of supports available for families.[63] The rarity of and variation in tetrasomy X limits the amount of specific support available, but major chromosome disorder organizations serve the condition and have members who are or are associates of people with it.[46]

Notes

  1. ^ 'Karyotype' as a term has multiple meanings, all of which are used here. It may refer to a person's chromosome complement, to the test used to discern said chromosome complement, or to an image of chromosomes ascertained via such a test.[1]
  2. ^ Aneuploidy is the presence of too many or too few chromosomes in a cell.[9]
  3. ^ Male phenotypes, innate or induced, with forms of X chromosome polysomy that are usually phenotypically female do occur. For trisomy X, a trans man and several men with sex reversal have been recorded.[50][51][52]

References

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External links

  •   Media related to Tetrasomy X at Wikimedia Commons

March 02, 2023
tetrasomy, also, known, xxxx, chromosomal, disorder, which, female, four, rather, than, copies, chromosome, associated, with, intellectual, disability, varying, severity, characteristic, coarse, facial, features, heart, defects, skeletal, anomalies, such, incr. Tetrasomy X also known as 48 XXXX is a chromosomal disorder in which a female has four rather than two copies of the X chromosome It is associated with intellectual disability of varying severity characteristic coarse facial features heart defects and skeletal anomalies such as increased height clinodactyly incurved pinky fingers and radioulnar synostosis fusion of the long bones in the forearm Tetrasomy X is a rare condition with few medically recognized cases it is estimated to occur in approximately 1 in 50 000 females Tetrasomy XOther names48 XXXXKaryotype of tetrasomy XSpecialtyMedical genetics SymptomsIntellectual disability facial dysmorphology heart defects skeletal anomalies tall statureUsual onsetConceptionDurationLifelongCausesNondisjunctionDiagnostic methodKaryotypeDifferential diagnosisTrisomy X pentasomy X Down syndromeThe disorder has a wide range of symptoms with phenotypes presentations ranging from slight to severe It is suspected to be underdiagnosed as are other sex chromosome disorders Life outcomes vary some women have had education employment and children while others have remained dependent into adulthood Life expectancy does not appear to be substantially reduced Tetrasomy X has phenotypic overlap with a number of more common disorders such as trisomy X and Down syndrome and diagnosis is usually unclear prior to chromosomal testing Tetrasomy X is generally not inherited but rather occurs via a random event called nondisjunction during gamete or zygote development The formal term for the karyotype note 1 observed in tetrasomy X is 48 XXXX as the condition is typified by a 48 chromosome complement rather than the 46 chromosomes observed in normal human development Contents 1 Presentation 2 Causes 3 Diagnosis 3 1 Differential diagnosis 4 Prognosis 5 Epidemiology 6 History 7 Notes 8 References 9 External linksPresentation EditTetrasomy X has a variable presentation with a spectrum of severity and lacks obvious defining clinical abnormalities that can lead to a diagnosis in the absence of testing 2 Recognizable characteristics include increased height and mild intellectual disability the average adult height in tetrasomy X is 169 cm 5 ft 6 1 2 in 2 compared with a reference height of around 162 cm 5 ft 4 in for women in the Anglosphere 3 4 while a review of the first 27 women to be diagnosed with tetrasomy X found IQs ranging from 30 to 101 with a mean of 62 5 Although some degree of intellectual disability is traditionally characteristic two medically reported cases were of normal intelligence 6 and patient organizations report members who are only afflicted by specific learning disabilities such as dyslexia 7 Speech and language delays may be associated with tetrasomy X although the matter is unclear some reports describe speech and language abilities in line with overall intelligence 2 while others describe problems independent of intelligence in particular with subjects who have normal intelligence but significant language delays 6 8 A number of facial and musculoskeletal anomalies are common to all aneuploidies of the sex chromosomes note 2 including X chromosome polysomy such as tetrasomy X 10 Epicanthic folds additional skin folds in the corners of the eyes and hypertelorism wide spaced eyes are frequent facial features 2 Multiple reports have described the characteristic facial features as coarse 11 12 These dysmorphic features are relatively mild and do not necessarily stand out from the crowd 7 in general X chromosome polysomy is not associated with severe physical dysmorphism although tetrasomy and pentasomy X tend to be somewhat more noticeable in this respect than the milder and more frequent trisomy X 2 10 Hypotonia low muscle tone often severe and early onset is a commonly observed musculoskeletal abnormality 13 Clinodactyly the bending inwards of the pinky finger and radioulnar synostosis the fusion of the long bones in the forearm are frequent 2 Dental abnormalities are associated with the syndrome in particular taurodontism where the pulp of the teeth is enlarged and extends into the roots 14 These findings are not unique to tetrasomy X epicanthic folds and hypertelorism are seen in trisomy X 10 while clinodactyly and radioulnar synostosis are findings common to all sex chromosome aneuploidies 15 and taurodontism is prevalent in X chromosome polysomy specifically 16 Heart defects of various types have been associated with the syndrome albeit at unclear prevalence A patient organization reports approximately one third of cases in its membership had congenital heart defects a larger proportion than reported in the medical literature 7 Frequently reported heart defects include patent ductus arteriosus 11 and ventricular septal defects 17 Kidney and bladder issues have been loosely associated with the syndrome 7 as has epilepsy 18 Epilepsy in sex chromosome aneuploidies generally is mild amenable to treatment and often attenuates or disappears with time 19 There is also a potential association between tetrasomy X and autoimmune disorders particularly lupus which has been recorded in two women with tetrasomy X and appears to become more common as the number of X chromosomes increase 20 The psychological and behavioural phenotype of tetrasomy X is understudied Some reports describe girls and women with tetrasomy X as generally placid and pleasant while others report emotional lability and inappropriate behaviour 2 Family background and environment has a significant impact on behaviour and cases with severe behavioural dysfunction frequently have similarly dysfunctional unaffected relatives Expressive language delays and executive dysfunction are common heralds of behavioural issues due to the difficulties they cause for educational vocational and social functioning 6 In both men and women X chromosome polysomy is known to be associated with psychosis 21 and a case is known of a girl with tetrasomy X and childhood onset schizophrenia 22 Parent reports describe children and young adults who are generally pleasant and affectionate yet shy and have issues relating to temper tantrums mood swings and frustration at an inability to communicate 7 Tetrasomy X can interfere with pubertal development Of the adult women recorded with tetrasomy X half have had normal pubertal development with menarche at an appropriate age while the other half have had some form of pubertal dysfunction 2 such as primary amenorrhea irregular menstrual cycles or incomplete development of secondary sex characteristics 7 Premature ovarian failure or early menopause has been recorded 23 In trisomy X premature menopause has occurred between the ages of 19 and 40 10 while in tetrasomy X it has been recorded as young as 15 24 In tetrasomy X as for other causes of premature menopause or incomplete puberty some writers have recommended hormone replacement therapy 23 Fertility in tetrasomy X is possible In the first discussion of the phenomenon three cases have been reported of women bearing children One woman had two children one with a normal chromosome complement and the other with Down syndrome Two women had one child each one had a daughter with normal chromosomes while the other had a stillbirth with an omphalocele 2 An additional woman was reported as having three children all with normal chromosomes 7 Causes Edit Nondisjunction in tetrasomy X Tetrasomy X like other aneuploidy disorders is caused by a process called nondisjunction Nondisjunction occurs when homologous chromosomes or sister chromatids fail to separate properly during meiosis the process that produces gametes eggs or sperm and result in gametes with too many or too few chromosomes 25 In the specific case of sex chromosome tetrasomy and pentasomy nondisjunction occurs multiple times with the same parent for tetrasomy X specifically all known cases have inherited either three maternal X chromosomes and one paternal or four maternal X chromosomes with no paternal contribution 26 27 The cause of this specific pattern of inheritance is unclear An early research group proposed that due to the gap in prevalence between the related conditions 49 XXXXY which has a similar prevalence to tetrasomy X and pentasomy X which is far rarer the paternal X chromosomes may frequently be lost in high level aneuploidy 28 More recently speculation has been based in genomic imprinting with the suggestion that a similarly high number of paternal X chromosomes would be incompatible with life 29 Nondisjunction can also occur after conception which frequently results in a mosaic karyotype 30 Nondisjunction is related to advanced maternal age 31 In common aneuploidies such as Down syndrome the relationship with maternal age is extensively studied 32 In Klinefelter syndrome the most common and most studied sex chromosome aneuploidy incidence increases substantially as maternal age rises 33 Less is understood about the role of maternal age in sex chromosome tetrasomy and pentasomy conditions primarily due to their rarity and no clear relationship has been established 5 34 Tetrasomy X is generally a random occurrence and does not recur in the same family In rare cases it may be related to a mother having trisomy X mosaic or otherwise It is not caused by environmental factors 7 Diagnosis EditChromosome aneuploidies such as tetrasomy X are diagnosed via karyotype 35 the process in which chromosomes are tested from blood bone marrow amniotic fluid or placental cells 36 Due to significant differential diagnosis potential diagnosis cannot be made on the basis of phenotype alone 2 Differential diagnosis Edit Tetrasomy X has many possibilities for differential diagnosis with multiple other conditions overlapping with the phenotype One differential diagnosis is trisomy X in which a female has three copies of the X chromosome The two conditions have overlapping phenotypes with a broad range of severity 37 Both are associated with hypotonia mild facial anomalies such as hypertelorism and epicanthic folds increased height premature ovarian failure and some reduction in intelligence However the phenotype of tetrasomy X is generally more severe than that of trisomy X 10 In addition while both are associated to some degree with tall stature the association is much stronger for trisomy X 7 38 The clinical portrait is made more complex by the possibility of mosaicism where both 47 XXX and 48 XXXX cell lines are present such cases frequently but not certainly present closer to the tetrasomy than trisomy profile 39 As well as simple 47 XXX 48 XXXX mosaicism complex 46 XX 47 XXX 48 XXXX mosaicism has been reported 40 Pentasomy X a karyotype of five X chromosomes is another major differential diagnosis The phenotype of pentasomy X is similar but on average more severe Intellectual disability is more severe with an average IQ of 50 and pubertal delay or incomplete puberty appears more common 2 Unlike other X chromosome polysomies pentasomy X is associated with short stature 10 Similarly pentasomy X is commonly associated with findings that are infrequent in tetrasomy X such as microcephaly and intrauterine growth restriction 13 Cases of 48 XXXX 49 XXXXX mosaicism have been reported and are often categorized as cases of pentasomy X 41 More complex mosaics have been reported such as 47 XXX 48 XXXX 49 XXXXX 17 and 45 X0 46 XX 47 XXX 48 XXXX 49 XXXXX 42 An additional differential diagnosis in some cases is Down syndrome Some cases of tetrasomy X have been described as having a false air of trisomy 21 the underlying chromosomal aneuploidy in Down s and karyotyping resulting in a diagnosis of tetrasomy X has been performed due to suspicion of Down syndrome 37 43 However this is only a differential diagnosis for a subset of cases while others have more normal phenotypes or abnormalities inconsistent with the Down s profile 37 The matter is complicated by the observation that a number of women with X chromosome polysomy including tetrasomy X have had children with Down syndrome 2 44 Prognosis EditThe long term prognosis for tetrasomy X appears generally good While life expectancy is unclear patients have been diagnosed in their 50s and 60s and long term follow up of individual cases shows healthy aging with good physical health 5 45 Some women live fully independent lives while others require more persistent support from parents and caregivers consistent with other intellectual disability syndromes of comparable severity 7 Many are able to work part time and some full time some young women attend tertiary education mostly vocational 46 Girls and women with tetrasomy X and good outcomes are typified by supportive family environments and strong personal advocacy for their success t he children have been exposed to many varied activities and experiences and are praised for their strengths while their limitations and delays are minimised 2 Epidemiology EditTetrasomy X is estimated to occur in around 1 in 50 000 females 47 Considering the variable phenotype tetrasomy X support organizations and researchers think it likely there are many cases that have not come to medical attention 7 This is common to all sex chromosome aneuploidies which have very low diagnosis rates compared to their overall population prevalence 10 Overall sex chromosome tetrasomy and pentasomy disorders occur in 1 in 18 000 to 1 in 100 000 male live births and are somewhat rarer in females 2 48 Tetrasomy X only occurs in females as the Y chromosome is in most cases necessary for male sexual development 49 note 3 History EditTetrasomy X was first recorded in 1961 in two intellectually disabled women residing in an institution 53 The late 1950s and early 1960s were a period of frequent ascertainment of previously unknown sex chromosome aneuploidies with the discovery of the 48 XXXX karyotype being alongside that of 45 X0 54 47 XXY 55 and 47 XXX 56 in 1959 48 XXYY in 1960 57 and 47 XYY the same year 58 One of the two women first diagnosed with tetrasomy X was followed up twenty six years later in her late fifties by which time she had left the institution and was living semi independently with her sister she was in good physical health had experienced menarche and menopause at typical ages 14 and 50 and showed no signs of cognitive decline 45 Much of the medical literature for tetrasomy X dates to the 1960s and 1970s an era of particular interest in and research on sex chromosome aneuploidy 7 Early reports were frequently discovered during chromosome screenings in institutions for the intellectually disabled 5 59 60 The early preference for diagnosis of sex chromosome aneuploidy in selected samples such as institution residents and prisoners led to a biased perspective on the conditions that painted an unduly negative portrait of their phenotypes and prognoses Further research on sex chromosome aneuploidy via unselected samples such as newborn screening allowed for major conditions such as XYY syndrome Klinefelter syndrome and trisomy X to be re defined by more representative phenotypes however rarer conditions such as tetrasomy X were not ascertained in any such studies and therefore the medical literature continues to describe cases that were diagnosed due to developmental or behavioural issues 2 Aspects of the early studies remain accepted a 1969 proposal that each supernumerary X chromosome reduces IQ by an average of 15 points 61 is still used as a rule of thumb 2 7 Sex chromosome tetrasomy and pentasomy conditions have consistently received little attention compared to the more common trisomy conditions Research into conditions such as tetrasomy X has been stymied by biased samples outdated information and a lack of publications above the case report level 2 Dedicated patient and family support groups such as Unique 7 and the Tetrasomy and Pentasomy X Support Group 62 began to appear online in the early 2000s A patient registry in the United Kingdom was established in 2004 amidst concerns that little serious research had been conducted on tetrasomy X for many years 7 Diagnosis of sex chromosome aneuploidies is increasing 16 as is the number of supports available for families 63 The rarity of and variation in tetrasomy X limits the amount of specific support available but major chromosome disorder organizations serve the condition and have members who are or are associates of people with it 46 Notes Edit Karyotype as a term has multiple meanings all of which are used here It may refer to a person s chromosome complement to the test used to discern said chromosome complement or to an image of chromosomes ascertained via such a test 1 Aneuploidy is the presence of too many or too few chromosomes in a cell 9 Male phenotypes innate or induced with forms of X chromosome polysomy that are usually phenotypically female do occur For trisomy X a trans man and several men with sex reversal have been recorded 50 51 52 References Edit Biesecker BB Genetics Glossary Karyotype National Human Genome Research Institute Retrieved 12 April 2021 a b c d e f g h i j k l m n o p q Linden MG Bender BG Robinson A October 1995 Sex chromosome tetrasomy and pentasomy Pediatrics 96 4 672 682 doi 10 1542 peds 96 4 672 PMID 7567329 US Dept of Health and Human Services et al August 2016 Anthropometric reference data for children and adults United States 2011 2014 PDF National Health Statistics Reports 11 Archived PDF from the original on 2 February 2017 Retrieved 23 March 2021 Australian health survey first results Australian Bureau of Statistics 29 October 2012 Archived from the original on 20 January 2017 Retrieved 23 March 2021 a b c d Nielsen J Homma A Christiansen F Rasmussen K 1977 Women with tetra X 48 XXXX Hereditas 85 2 151 156 doi 10 1111 j 1601 5223 1977 tb00962 x PMID 885729 a b c Samango Sprouse C Keen C Mitchell F Sadeghin T Gropman A 18 June 2015 Neurodevelopmental variability in three young girls with a rare chromosomal disorder 48 XXXX American Journal of Medical Genetics Part A 167A 10 2251 2259 doi 10 1002 ajmg a 37198 PMID 26086740 S2CID 23652023 a b c d e f g h i j k l m n o Rooman Raoul Hulten Maj 2005 Tetrasomy X PDF Unique Archived PDF from the original on 18 March 2021 Blackston RD Chen AT June 1972 A case of 48 XXXX female with normal intelligence Journal of Medical Genetics 9 2 230 232 doi 10 1136 jmg 9 2 230 PMC 1469029 PMID 5046634 Mandrioli D Belpoggi F Silbergeld EK Perry MJ 12 October 2016 Aneuploidy a common and early evidence based biomarker for carcinogens and reproductive toxicants Environmental Health 15 97 97 doi 10 1186 s12940 016 0180 6 PMC 5059969 PMID 27729050 a b c d e f g Tartaglia NR Howell S Sutherland A Wilson R Wilson L 11 May 2010 A review of trisomy X 47 XXX Orphanet Journal of Rare Diseases 5 8 8 doi 10 1186 1750 1172 5 8 PMC 2883963 PMID 20459843 a b Xiong WY Jiang ZY Zou CC January 2014 Tetrasomy X in a child with multiple abnormalities case report and literature review from China Hong Kong Journal of Paediatrics 19 1 37 40 Alvarez Vazquez P Rivera A Figueroa I Paramo C Garcia Mayor RV 10 July 2006 Acromegaloidism with normal growth hormone secretion associated with X Tetrasomy Pituitary 9 2 145 149 doi 10 1007 s11102 006 9330 0 PMID 16832583 S2CID 8358623 a b Schoubben E Decaestecker K Quaegebeur K Danneels L Mortier G Cornette L 18 May 2011 Tetrasomy and pentasomy of the X chromosome European Journal of Pediatrics 170 10 1325 1327 doi 10 1007 s00431 011 1491 9 PMID 21590264 S2CID 21348257 Kaur A Pandi M Singh JR 2009 48 XXXX a rare aneuploidy Balkan Journal of Medical Genetics 12 1 65 68 doi 10 2478 v10034 009 0006 8 Visootsak J Graham JM 24 October 2006 Klinefelter syndrome and other sex chromosomal aneuploidies Orphanet Journal of Rare Diseases 1 1 42 doi 10 1186 1750 1172 1 42 PMC 1634840 PMID 17062147 a b Tartaglia N Howell S Wilson R Janusz J Boada R Martin S Frazier JB Pfeiffer M Regan K McSwegin S Zeitler P 17 July 2015 The eXtraordinarY Kids Clinic an interdisciplinary model of care for children and adolescents with sex chromosome aneuploidy Journal of Multidisciplinary Healthcare 8 1 323 334 doi 10 2147 JMDH S80242 PMC 4514383 PMID 26229481 a b Wood A Kleis L Toriello H Cemeroglu AP 17 May 2011 Mosaic pentasomy X tetrasomy X syndrome and premature ovarian failure Indian Pediatrics 48 5 402 404 PMID 21654007 Bilge S Mert GG Ozcan N Ozcanyuz D September 2020 Tetrasomy X a rare cause of epilepsy and behavior disorder Acta Scientific Neurology 3 9 56 58 AXYS Berry Kravis E December 2020 Seizures and tremor in people with X amp Y chromosome variations PDF AXYS Association for X and Y Chromosome Variations Retrieved 26 March 2021 Slae M Heshin Bekenstein M Simckes A Heimer G Engelhard D Eisenstein EM 2014 Female polysomy X and systemic lupus erythematosus Seminars in Arthritis and Rheumatism 43 4 508 512 doi 10 1016 j semarthrit 2013 07 014 PMID 24012046 DeLisi LE Friedrich U Wahlstrom J Boccio Smith A Forsman A Eklund K Crow TJ 1994 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woman with tetra X chromosomes Journal of Mental Deficiency Research 32 1 67 74 doi 10 1111 j 1365 2788 1988 tb01389 x PMID 3361607 a b Isaacs Cover Virginia 2012 Trisomy X Tetrasomy X and Pentasomy X Living with Klinefelter Syndrome 47 XXY Trisomy X 47 XXX and 47 XYY A Guide for Families and Individuals Affected by Extra X and Y Chromosome Variations Altona Manitoba Friesens pp 114 116 ISBN 978 0 615 57400 4 Wilson Rebecca Bennett Elizabeth Howell Susan E Tartaglia Nicole 20 December 2012 Sex Chromosome Aneuploidies Psychopathology of Childhood and Adolescence A Neuropsychological Approach New York Springer Publishing pp 596 597 ISBN 978 0826109200 Tartaglia N Ayari N Howell S D Epagnier C Zeitler P June 2011 48 XXYY 48 XXXY and 49 XXXXY syndromes not just variants of Klinefelter syndrome Acta Paediatrica 100 6 851 860 doi 10 1111 j 1651 2227 2011 02235 x PMC 3314712 PMID 21342258 Tetrasomy X Genetic and Rare Diseases Information Center 19 February 2014 Retrieved 10 April 2021 Turan MT Esel E Dundar M Candemir Z Basturk M Sofuoglu S Ozkul Y 1 December 2000 Female to male transsexual with 47 XXX karyotype Biological Psychiatry 48 1 1116 1117 doi 10 1016 S0006 3223 00 00954 9 PMID 11094147 S2CID 16396520 Ogata T Matsuo M Muroya K Koyama Y Fukutani K 1 February 2001 47 XXX male A clinical and molecular study American Journal of Medical Genetics 98 4 353 356 doi 10 1002 1096 8628 20010201 98 4 lt 353 AID AJMG1110 gt 3 0 CO 2 D PMID 11170081 Muller U Latt SA Donlon T Opitz JM October 1987 Y specific DNA sequences in male patients with 46 XX and 47 XXX karyotypes American Journal of Medical Genetics 28 2 393 401 doi 10 1002 ajmg 1320280218 PMID 2827475 Carr DH Barr ML Plunkett ER 21 January 1961 An XXXX sex chromosome complex in two mentally defective females Canadian Medical Association Journal 84 3 131 137 PMC 1939166 PMID 13690988 Ford CE Jones KW Polani PE de Almeida JCC Briggs JH 1959 A sex chromosome anomaly in a case of gonadal dysgenesis Turner s syndrome Lancet 273 7075 711 713 doi 10 1016 S0140 6736 59 91893 8 PMID 13642858 Jacobs PA Strong JA 31 January 1959 A case of human intersexuality having a possible XXY sex determining mechanism Nature 183 4657 302 303 Bibcode 1959Natur 183 302J doi 10 1038 183302a0 PMID 13632697 S2CID 38349997 Jacobs PA Baikie AG Court Brown WM MacGregor TN Harnden DG 26 September 1959 Evidence for the existence of the human super female Lancet 274 7100 423 425 doi 10 1016 S0140 6736 59 90415 5 PMID 14406377 Muldal S Ockey CH 27 August 1960 The double male a new chromosome constitution in Klinefelter s syndrome Lancet 276 7147 492 493 doi 10 1016 S0140 6736 60 91624 X Sandberg AA Koepf GF Ishihara T Hauschka TS 26 August 1961 An XYY human male Lancet 278 7200 488 489 doi 10 1016 S0140 6736 61 92459 X PMID 13746118 Berkeley MI Faed MJ March 1970 A female with the 48 XXXX karyotype Journal of Medical Genetics 7 1 83 85 doi 10 1136 jmg 7 1 83 PMC 1468910 PMID 5480970 Ricci N Dallapiccola B Ventimiglia B Tiepolo L Fraccaro M 1968 48 XXXX 49 XXXXX mosaic asynchronies among the late replicating X chromosomes Cytogenetics 7 4 249 259 doi 10 1159 000129989 PMID 5722744 Polani PE 16 August 1969 Abnormal sex chromosomes and mental disorders Nature 223 5207 680 686 Bibcode 1969Natur 223 680P doi 10 1038 223680a0 PMID 4896514 S2CID 4242480 Tetrasomy Pentasomy X Support Group National Organization for Rare Disorders Retrieved 10 April 2021 Auchmutey Pam 2018 Extraordinary care Emory Health Digest Archived from the original on 6 August 2020 Retrieved 26 March 2021 External links Edit Media related to Tetrasomy X at Wikimedia Commons Retrieved from https en wikipedia org w index php title Tetrasomy X amp oldid 1109441751, wikipedia, wiki, book, books, library,

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