Androgen insensitivity syndrome

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Androgen insensitivity syndrome
Androgen receptor 3-d model.jpg
AIS results when the function of the androgen receptor (AR) is impaired. The AR protein (pictured) mediates the effects of androgens in the human body.
Specialty Endocrinology

Androgen insensitivity syndrome (AIS) is a condition involving the inability to respond to androgens, typically due to androgen receptor dysfunction. [1]

Contents

It affects 1 in 20,000 to 64,000 XY (karyotypically male) births. The condition results in the partial or complete inability of cells to respond to androgens. [2] This unresponsiveness can impair or prevent the development of male genitals, as well as impairing or preventing the development of male secondary sexual characteristics at puberty. It does not significantly impair female genital or sexual development. [3] [4] The insensitivity to androgens is therefore clinically significant only when it occurs in genetic males, (i.e. individuals with a Y-chromosome, or more specifically, an SRY gene). [5] Clinical phenotypes in these individuals range from a typical male habitus with mild spermatogenic defect or reduced secondary terminal hair, to a full female habitus, despite the presence of a Y-chromosome. [6]

AIS is divided into three categories that are differentiated by the degree of genital masculinization:

Androgen insensitivity syndrome is the largest single entity that leads to 46,XY undermasculinized genitalia. [9]

Management of AIS is currently limited to symptomatic management; no method is currently available to correct the malfunctioning androgen receptor proteins produced by AR gene mutations. Areas of management include sex assignment, genitoplasty, gonadectomy to reduce tumor risk, hormone replacement therapy, genetic counseling, and psychological counseling.

Genetics

Location and structure of the human androgen receptor: Top, the AR gene is located on the proximal long arm of the X chromosome. Middle, the eight exons are separated by introns of various lengths. Bottom, illustration of the AR protein, with primary functional domains labeled (not representative of actual 3-D structure). Functional domains of the human androgen receptor.svg
Location and structure of the human androgen receptor: Top, the AR gene is located on the proximal long arm of the X chromosome. Middle, the eight exons are separated by introns of various lengths. Bottom, illustration of the AR protein, with primary functional domains labeled (not representative of actual 3-D structure).

The human androgen receptor (AR) is a protein encoded by a gene located on the proximal long arm of the X chromosome (locus Xq11-Xq12). [10] The protein coding region consists of approximately 2,757 nucleotides (919 codons) spanning eight exons, designated 1-8 or A-H. [5] [3] Introns vary in size between 0.7 and 26 kb. [3] Like other nuclear receptors, the AR protein consists of several functional domains: the transactivation domain (also called the transcription-regulation domain or the amino / NH2-terminal domain), the DNA-binding domain, the hinge region, and the steroid-binding domain (also called the carboxyl-terminal ligand-binding domain). [5] [11] [3] [12] The transactivation domain is encoded by exon 1, and makes up more than half of the AR protein. [3] Exons 2 and 3 encode the DNA-binding domain, while the 5' portion of exon 4 encodes the hinge region. [3] The remainder of exons 4 through 8 encodes the ligand binding domain. [3]

Trinucleotide satellite lengths and AR transcriptional activity

The AR gene contains two polymorphic trinucleotide microsatellites in exon 1. [11] The first microsatellite (nearest the 5' end) contains 8 [13] to 60 [14] [15] repetitions of the glutamine codon "CAG" and is thus known as the polyglutamine tract. [3] The second microsatellite contains 4 [16] to 31 [17] repetitions of the glycine codon "GGC" and is known as the polyglycine tract. [18] The average number of repetitions varies by ethnicity, with Caucasians exhibiting an average of 21 CAG repeats, and Blacks 18. [19] In men, disease states are associated with extremes in polyglutamine tract length; prostate cancer, [20] hepatocellular carcinoma, [21] and intellectual disability [13] are associated with too few repetitions, while spinal and bulbar muscular atrophy (SBMA) is associated with a CAG repetition length of 40 or more. [22] Some studies indicate that the length of the polyglutamine tract is inversely correlated with transcriptional activity in the AR protein, and that longer polyglutamine tracts may be associated with male infertility [23] [24] [25] and undermasculinized genitalia in men. [26] However, other studies have indicated no such correlation exists. [27] [28] A comprehensive meta-analysis of the subject published in 2007 supports the existence of the correlation, and concluded these discrepancies could be resolved when sample size and study design are taken into account. [29] Some studies suggest longer polyglycine tract lengths are also associated with genital masculinization defects in men. [30] [31] Other studies find no such association. [32]

AR mutations

As of 2010, over 400 AR mutations have been reported in the AR mutation database, and the number continues to grow. [11] Inheritance is typically maternal and follows an X-linked recessive pattern; [5] [33] individuals with a 46,XY karyotype always express the mutant gene since they have only one X chromosome, whereas 46,XX carriers are minimally affected. About 30% of the time, the AR mutation is a spontaneous result, and is not inherited. [34] Such de novo mutations are the result of a germ cell mutation or germ cell mosaicism in the gonads of one of the parents, or a mutation in the fertilized egg itself. [35] In one study, [36] three of eight de novo mutations occurred in the postzygotic stage, leading to the estimate that up to one-third of de novo mutations result in somatic mosaicism. [5] Not every mutation of the AR gene results in androgen insensitivity; one particular mutation occurs in 8 to 14% of genetic males, [37] [38] [39] [40] and is thought to adversely affect only a small number of individuals when other genetic factors are present. [41]

Other causes

Some individuals with CAIS or PAIS do not have any AR mutations despite clinical, hormonal, and histological features sufficient to warrant an AIS diagnosis; up to 5% of women with CAIS do not have an AR mutation, [11] as well as between 27 [42] [43] and 72% [44] of individuals with PAIS.

In one patient, the underlying cause for presumptive PAIS was a mutant steroidogenic factor-1 (SF-1) protein. [45] In another patient, CAIS was the result of a deficit in the transmission of a transactivating signal from the N-terminal region of the androgen receptor to the basal transcription machinery of the cell. [46] A coactivator protein interacting with the activation function 1 (AF-1) transactivation domain of the androgen receptor may have been deficient in this patient. [46] The signal disruption could not be corrected by supplementation with any coactivators known at the time, nor was the absent coactivator protein characterized, which left some in the field unconvinced that a mutant coactivator would explain the mechanism of androgen resistance in CAIS or PAIS patients with a typical AR gene. [5]

XY karyotype

Depending on the mutation, a person with a 46,XY karyotype and AIS can have either a male (MAIS) or female (CAIS) phenotype, [47] or may have genitalia that are only partially masculinized (PAIS).[ citation needed ] The gonads are testes regardless of phenotype due to the influence of the Y chromosome. [48] [49] A 46,XY female, thus, does not have ovaries, [50] and can not contribute an egg towards conception. In some cases, 46, XY females do form a vestigial uterus and have been able to gestate children. Such examples are rare and have required the use of an egg donor, hormone therapy, and IVF. [51]

Several case studies of fertile 46,XY males with AIS have been published, [52] [53] although this group is thought to be a minority. [12] In some cases, infertile males with MAIS have been able to conceive children after increasing their sperm count through the use of supplementary testosterone. [5] [54]

A genetic male conceived by a man with AIS would not receive his father's X chromosome, thus would neither inherit nor carry the gene for the syndrome. A genetic female conceived in such a way would receive her father's X chromosome, thus would become a carrier.

XX karyotype

Genetic females (46,XX karyotype) have two X chromosomes, thus have two AR genes. A mutation in one (but not both) results in a minimally affected, fertile, female carrier. Some carriers have been noted to have slightly reduced body hair, delayed puberty, and/or tall stature, presumably due to skewed X-inactivation. [3] [4] A female carrier will pass the affected AR gene to her children 50% of the time. If the affected child is a genetic female, she, too, will be a carrier. An affected 46,XY child will have AIS.[ citation needed ]

A genetic female with mutations in both AR genes could theoretically result from the union of a fertile man with AIS and a female carrier of the gene, or from de novo mutation. However, given the scarcity of fertile AIS men and low incidence of AR mutation, the chances of this occurrence are small. The phenotype of such an individual is a matter of speculation; as of 2010, no such documented case has been published.[ citation needed ]

Correlation of genotype and phenotype

Individuals with partial AIS, unlike those with the complete or mild forms, present at birth with ambiguous genitalia, and the decision to raise the child as male or female is often not obvious. [5] [35] [55] Unfortunately, little information regarding phenotype can be gleaned from precise knowledge of the AR mutation itself; the same AR mutation may cause significant variation in the degree of masculinization in different individuals, even among members of the same family. [56] [57] Exactly what causes this variation is not entirely understood, although factors contributing to it could include the lengths of the polyglutamine and polyglycine tracts, [58] sensitivity to and variations in the intrauterine endocrine milieu,[ citation needed ] the effect of coregulatory proteins active in Sertoli cells, [18] [59] somatic mosaicism, [5] expression of the 5RD2 gene in genital skin fibroblasts, [56] reduced AR transcription and translation from factors other than mutations in the AR coding region, [60] an unidentified coactivator protein, [46] enzyme deficiencies such as 21-hydroxylase deficiency, [4] or other genetic variations such as a mutant steroidogenic factor-1 protein. [45] The degree of variation, however, does not appear to be constant across all AR mutations, and is much more extreme in some. [5] [4] [41] Missense mutations that result in a single amino acid substitution are known to produce the most phenotypic diversity. [11]

Pathophysiology

Normal function of the androgen receptor: Testosterone (T) enters the cell and, if 5-alpha-reductase is present, is converted into dihydrotestone (DHT). Upon steroid binding, the androgen receptor (AR) undergoes a conformational change and releases heat shock proteins (hsps). Phosphorylation (P) occurs before or after steroid binding. The AR translocates to the nucleus where dimerization, DNA binding, and the recruitment of coactivators occur. Target genes are transcribed (mRNA) and translated into proteins. Human androgen receptor and androgen binding.svg
Normal function of the androgen receptor: Testosterone (T) enters the cell and, if 5-alpha-reductase is present, is converted into dihydrotestone (DHT). Upon steroid binding, the androgen receptor (AR) undergoes a conformational change and releases heat shock proteins (hsps). Phosphorylation (P) occurs before or after steroid binding. The AR translocates to the nucleus where dimerization, DNA binding, and the recruitment of coactivators occur. Target genes are transcribed (mRNA) and translated into proteins.

Androgens and the androgen receptor

The effects that androgens have on the human body (virilization, masculinization, anabolism, etc.) are not brought about by androgens themselves, but rather are the result of androgens bound to androgen receptors; the androgen receptor mediates the effects of androgens in the human body. [62] Likewise, the androgen receptor itself is generally inactive in the cell until androgen binding occurs. [3]

The following series of steps illustrates how androgens and the androgen receptor work together to produce androgenic effects: [5] [11] [3] [12]

  1. Androgen enters the cell.
    1. Only certain organs in the body, such as the gonads and the adrenal glands, produce the androgen testosterone.
    2. Testosterone is converted into dihydrotestosterone, a chemically similar androgen, in cells containing the enzyme 5-alpha reductase.
    3. Both androgens exert their influence through binding with the androgen receptor.
  2. Androgen binds with the androgen receptor.
    1. The androgen receptor is expressed ubiquitously throughout the tissues of the human body.
    2. Before it binds with an androgen, the androgen receptor is bound to heat shock proteins.
    3. These heat shock proteins are released upon androgen binding.
    4. Androgen binding induces a stabilizing, conformational change in the androgen receptor.
    5. The two zinc fingers of the DNA-binding domain are exposed as a result of this new conformation.
    6. AR stability is thought to be aided by type II coregulators, which modulate protein folding and androgen binding, or facilitate NH2/carboxyl-terminal interaction.
  3. The hormone-activated androgen receptor is phosphorylated.
    1. Receptor phosphorylation can occur before androgen binding, although the presence of androgen promotes hyperphosphorylation.
    2. The biological ramifications of receptor phosphorylation are unknown.
  4. The hormone-activated androgen receptor translocates to the nucleus.
    1. Nucleocytoplasmic transport is in part facilitated by an amino acid sequence on the AR called the nuclear localization signal.
    2. The AR's nuclear localization signal is primarily encoded in the hinge region of the AR gene.
  5. Homodimerization occurs.
    1. Dimerization is mediated by the second (nearest the 3' end) zinc finger.
  6. DNA binding to regulatory androgen response elements occurs.
    1. Target genes contain (or are flanked by) transcriptional enhancer nucleotide sequences that interact with the first zinc finger.
    2. These areas are called androgen response elements.
  7. Coactivators are recruited by the AR.
    1. Type I coactivators (i.e., coregulators) are thought to influence AR transcriptional activity by facilitating DNA occupancy, chromatin remodeling, or the recruitment of general transcription factors associated with RNA polymerase II holocomplex.
  8. Target gene transcription ensues.

In this way, androgens bound to androgen receptors regulate the expression of target genes, thus produce androgenic effects. [63]

Theoretically, certain mutant androgen receptors can function without androgens; in vitro studies have demonstrated that a mutant androgen receptor protein can induce transcription in the absence of androgen if its steroid binding domain is deleted. [64] [65] Conversely, the steroid-binding domain may act to repress the AR transactivation domain, perhaps due to the AR's unliganded conformation. [3]

Sexual differentiation: The human embryo has indifferent sex accessory ducts until the seventh week of development. Human sexual differentiation.gif
Sexual differentiation: The human embryo has indifferent sex accessory ducts until the seventh week of development.

Androgens in fetal development

Human embryos develop similarly for the first six weeks, regardless of genetic sex (46,XX or 46,XY karyotype); the only way to tell the difference between 46,XX or 46,XY embryos during this time period is to look for Barr bodies or a Y chromosome. [67] The gonads begin as bulges of tissue called the genital ridges at the back of the abdominal cavity, near the midline. By the fifth week, the genital ridges differentiate into an outer cortex and an inner medulla, and are called indifferent gonads. [67] By the sixth week, the indifferent gonads begin to differentiate according to genetic sex. If the karyotype is 46,XY, testes develop due to the influence of the Y chromosome's SRY gene. [48] [49] This process does not require the presence of androgen, nor a functional androgen receptor. [48] [49]

Until around the seventh week of development, the embryo has indifferent sex accessory ducts, which consist of two pairs of ducts: the Müllerian ducts and the Wolffian ducts. [67] Sertoli cells within the testes secrete anti-Müllerian hormone around this time to suppress the development of the Müllerian ducts, and cause their degeneration. [67] Without this anti-Müllerian hormone, the Müllerian ducts develop into the female internal genitalia (uterus, cervix, fallopian tubes, and upper vaginal barrel). [67] Unlike the Müllerian ducts, the Wolffian ducts will not continue to develop by default. [68] In the presence of testosterone and functional androgen receptors, the Wolffian ducts develop into the epididymides, vasa deferentia, and seminal vesicles. [67] If the testes fail to secrete testosterone, or the androgen receptors do not function properly, the Wolffian ducts degenerate. [69]

Masculinization of the male genitalia is dependent on both testosterone and dihydrotestosterone. Androgen dependencies of male genital tissues.png
Masculinization of the male genitalia is dependent on both testosterone and dihydrotestosterone.

Masculinization of the male external genitalia (the penis, penile urethra, and scrotum), as well as the prostate, are dependent on the androgen dihydrotestosterone. [70] [71] [72] [73] Testosterone is converted into dihydrotestosterone by the 5-alpha reductase enzyme. [74] If this enzyme is absent or deficient, then dihydrotestosterone is not created, and the external male genitalia do not develop properly. [70] [71] [72] [73] [74] As is the case with the internal male genitalia, a functional androgen receptor is needed for dihydrotestosterone to regulate the transcription of target genes involved in development. [62]

Pathogenesis of AIS

Mutations in the androgen receptor gene can cause problems with any of the steps involved in androgenization, from the synthesis of the androgen receptor protein itself, through the transcriptional ability of the dimerized, androgen-AR complex. [3] AIS can result if even one of these steps is significantly disrupted, as each step is required for androgens to activate the AR successfully and regulate gene expression. [3] Exactly which steps a particular mutation will impair can be predicted, to some extent, by identifying the area of the AR in which the mutation resides. This predictive ability is primarily retrospective in origin; the different functional domains of the AR gene have been elucidated by analyzing the effects of specific mutations in different regions of the AR. [3] For example, mutations in the steroid binding domain have been known to affect androgen binding affinity or retention, mutations in the hinge region have been known to affect nuclear translocation, mutations in the DNA-binding domain have been known to affect dimerization and binding to target DNA, and mutations in the transactivation domain have been known to affect target gene transcription regulation. [3] [68] Unfortunately, even when the affected functional domain is known, predicting the phenotypical consequences of a particular mutation (see Correlation of genotype and phenotype) is difficult.[ citation needed ]

Some mutations can adversely impact more than one functional domain. For example, a mutation in one functional domain can have deleterious effects on another by altering the way in which the domains interact. [68] A single mutation can affect all downstream functional domains if a premature stop codon or framing error results; such a mutation can result in a completely unusable (or unsynthesizable) androgen receptor protein. [3] The steroid binding domain is particularly vulnerable to the effects of a premature stop codon or framing error, since it occurs at the end of the gene, and its information is thus more likely to be truncated or misinterpreted than other functional domains. [3]

Other, more complex relationships have been observed as a consequence of mutated AR; some mutations associated with male phenotypes have been linked to male breast cancer, prostate cancer, or in the case of spinal and bulbar muscular atrophy, disease of the central nervous system. [75] [20] [76] [77] [78] The form of breast cancer seen in some men with PAIS is caused by a mutation in the AR's DNA-binding domain. [76] [78] This mutation is thought to cause a disturbance of the AR's target gene interaction that allows it to act at certain additional targets, possibly in conjunction with the estrogen receptor protein, to cause cancerous growth. [3] The pathogenesis of spinal and bulbar muscular atrophy (SBMA) demonstrates that even the mutant AR protein itself can result in pathology. The trinucleotide repeat expansion of the polyglutamine tract of the AR gene that is associated with SBMA results in the synthesis of a misfolded AR protein that the cell fails to proteolyze and disperse properly. [79] These misfolded AR proteins form aggregates in the cell cytoplasm and nucleus. [79] Over the course of 30 to 50 years, these aggregates accumulate and have a cytotoxic effect, eventually resulting in the neurodegenerative symptoms associated with SBMA. [79]

Diagnosis

The phenotypes that result from the insensitivity to androgens are not unique to AIS, thus the diagnosis of AIS requires thorough exclusion of other causes. [9] [80] Clinical findings indicative of AIS include the presence of a short vagina [81] or undermasculinized genitalia, [5] [57] [70] partial or complete regression of Müllerian structures, [82] bilateral nondysplastic testes, [83] and impaired spermatogenesis and/or virilization. [5] [84] [42] [75] Laboratory findings include a 46,XY karyotype [11] and typical or elevated postpubertal testosterone, luteinizing hormone, and estradiol levels. [11] [9] The androgen binding activity of genital skin fibroblasts is typically diminished, [3] [85] although exceptions have been reported. [86] Conversion of testosterone to dihydrotestosterone may be impaired. [3] The diagnosis of AIS is confirmed if androgen receptor gene sequencing reveals a mutation, although not all individuals with AIS (particularly PAIS) will have an AR mutation (see Other Causes). [11] [42] [43] [44]

Each of the three types of AIS (complete, partial, and mild) has a different list of differential diagnoses to consider. [5] However, cases have been reported of individuals with both AIS and certain diagnoses listed here, such as Klinefelter syndrome or Turner syndrome with mosaicism. [87] [88] Depending on the form of AIS suspected, the list of differentials can include: [48] [49] [89] [90] [91]

Classification

Individuals with AIS and related DSD/intersex conditions Women with androgen insensitivity syndrome.jpg
Individuals with AIS and related DSD/intersex conditions

AIS is broken down into three classes based on phenotype: complete androgen insensitivity syndrome (CAIS), partial androgen insensitivity syndrome (PAIS), and mild androgen insensitivity syndrome (MAIS). [5] [11] [84] [42] [92] [34] [29] [93] [12] A supplemental system of phenotypic grading that uses seven classes instead of the traditional three was proposed by pediatric endocrinologist Charmian A. Quigley et al. in 1995. [3] The first six grades of the scale, grades 1 through 6, are differentiated by the degree of genital masculinization; grade 1 is indicated when the external genitalia is fully masculinized, grade 6 is indicated when the external genitalia is fully feminized, and grades 2 through 5 quantify four degrees of decreasingly masculinized genitalia that lie in the interim. [3] Grade 7 is indistinguishable from grade 6 until puberty, and is thereafter differentiated by the presence of secondary terminal hair; grade 6 is indicated when secondary terminal hair is present, whereas grade 7 is indicated when it is absent. [3] The Quigley scale can be used in conjunction with the traditional three classes of AIS to provide additional information regarding the degree of genital masculinization, and is particularly useful when the diagnosis is PAIS. [11] [94]

Complete AIS

Partial AIS

Mild AIS

Management

Management of AIS is currently limited to symptomatic management; no method is currently available to correct the malfunctioning androgen receptor proteins produced by AR gene mutations. Areas of management include sex assignment, genitoplasty, gonadectomy in relation to tumor risk, hormone replacement therapy, genetic counseling, and psychological counseling.[ citation needed ]

MAIS

PAIS

CAIS

Epidemiology

AIS represents about 15% to 20% of DSDs and affects 1 in 20,000 to 1 in 64,000 males. [95]

Estimates for the incidence of androgen insensitivity syndrome are based on a relatively small population size, thus are known to be imprecise. [5] CAIS is estimated to occur in one of every 20,400 46,XY births. [96] A nationwide survey in the Netherlands based on patients with genetic confirmation of the diagnosis estimates that the minimal incidence of CAIS is one in 99,000. [56] The incidence of PAIS is estimated to be one in 130,000. [97] Due to its subtle presentation, MAIS is not typically investigated except in the case of male infertility, [70] thus its true prevalence is unknown. [11]

Controversy

Preimplantation genetic diagnosis

Preimplantation genetic diagnosis (PGD or PIGD) refers to genetic profiling of embryos prior to implantation (as a form of embryo profiling), and sometimes even of oocytes prior to fertilization. When used to screen for a specific genetic sequence, its main advantage is that it avoids selective pregnancy termination, as the method makes it highly likely that a selected embryo will be free of the condition under consideration. [98]

In the UK, AIS appears on a list of serious genetic diseases that may be screened for via PGD. [99] Some ethicists, clinicians, and intersex advocates have argued that screening embryos to specifically exclude intersex traits is based on social and cultural norms as opposed to medical necessity. [100] [101] [102]

History

Recorded descriptions of the effects of AIS date back hundreds of years, although significant understanding of its underlying histopathology did not occur until the 1950s. [5] The taxonomy and nomenclature associated with androgen insensitivity went through a significant evolution that paralleled this understanding.[ citation needed ]

Timeline of major milestones

Early terminology

The first descriptions of the effects of AIS appeared in the medical literature as individual case reports or as part of a comprehensive description of intersex physicalities. In 1839, Scottish obstetrician Sir James Young Simpson published one such description [112] in an exhaustive study of intersexuality that has been credited with advancing the medical community's understanding of the subject. [113] Simpson's system of taxonomy, however, was far from the first; taxonomies or descriptions for the classification of intersexuality were developed by Italian physician and physicist Fortuné Affaitati in 1549, [114] [115] French surgeon Ambroise Paré in 1573, [113] [116] French physician and sexology pioneer Nicolas Venette in 1687 (under the pseudonym Vénitien Salocini), [117] [118] and French zoologist Isidore Geoffroy Saint-Hilaire in 1832. [119] All five of these authors used the colloquial term "hermaphrodite" as the foundation of their taxonomies, although Simpson himself questioned the propriety of the word in his publication. [112] Use of the word "hermaphrodite" in the medical literature has persisted to this day, [120] [121] although its propriety is still in question. An alternative system of nomenclature has been recently suggested, [122] but the subject of exactly which word or words should be used in its place still one of much debate. [90] [123] [124] [125] [126]

"Pudenda pseudo-hermaphroditi ovini." Illustration of ambiguous genitalia from Frederik Ruysch's Thesaurus Anitomicus Octavius, 1709. Pudenda pseudohermaphroditi.jpg
"Pudenda pseudo-hermaphroditi ovini." Illustration of ambiguous genitalia from Frederik Ruysch's Thesaurus Anitomicus Octavius, 1709.

Pseudohermaphroditism

"Pseudohermaphroditism" has, until very recently, [122] been the term used in the medical literature to describe the condition of an individual whose gonads do not match the expected external genitalia in of their sex. For example, 46,XY individuals who have a female phenotype, but also have testes instead of ovaries—a group that includes all individuals with CAIS, as well as some individuals with PAIS—are classified as having "male pseudohermaphroditism", while individuals with both an ovary and a testis (or at least one ovotestis) are classified as having "true hermaphroditism". [121] [122] Use of the word in the medical literature antedates the discovery of the chromosome, thus its definition has not always taken karyotype into account when determining an individual's sex. Previous definitions of "pseudohermaphroditism" relied on perceived inconsistencies between the internal and external organs; the "true" sex of an individual was determined by the internal organs, and the external organs determined the "perceived" sex of an individual. [112] [119]

German-Swiss pathologist Edwin Klebs is sometimes noted for using the word "pseudohermaphroditism" in his taxonomy of intersexuality in 1876, [128] although the word is clearly not his invention as is sometimes reported; the history of the word "pseudohermaphrodite" and the corresponding desire to separate "true" hermaphrodites from "false", "spurious", or "pseudo" hermaphrodites, dates back to at least 1709, when Dutch anatomist Frederik Ruysch used it in a publication describing a subject with testes and a mostly female phenotype. [127] "Pseudohermaphrodite" also appeared in the Acta Eruditorum later that same year, in a review of Ruysch's work. [129] Also some evidence indicates the word was already being used by the German and French medical community long before Klebs used it; German physiologist Johannes Peter Müller equated "pseudohermaphroditism" with a subclass of hermaphroditism from Saint-Hilaire's taxonomy in a publication dated 1834, [130] and by the 1840s "pseudohermaphroditism" was appearing in several French and German publications, including dictionaries. [131] [132] [133] [134]

Testicular feminization

In 1953, American gynecologist John Morris provided the first full description of what he called "testicular feminization syndrome" based on 82 cases compiled from the medical literature, including two of his own patients. [5] [3] [135] The term "testicular feminization" was coined to reflect Morris' observation that the testicles in these patients produced a hormone that had a feminizing effect on the body, a phenomenon now understood to be due to the inaction of androgens, and subsequent aromatization of testosterone into estrogen. [5] A few years before Morris published his landmark paper, Lawson Wilkins had shown through experiment that unresponsiveness of the target cell to the action of androgenic hormones was a cause of "male pseudohermaphroditism". [80] [103] Wilkins' work, which clearly demonstrated the lack of a therapeutic effect when 46,XY patients were treated with androgens, caused a gradual shift in nomenclature from "testicular feminization" to "androgen resistance". [70]

Other names

A distinct name has been given to many of the various presentations of AIS, such as Reifenstein syndrome (1947), [136] Goldberg-Maxwell syndrome (1948), [137] Morris' syndrome (1953), [135] Gilbert-Dreyfus syndrome (1957), [138] Lub's syndrome (1959), [139] "incomplete testicular feminization" (1963), [140] Rosewater syndrome (1965), [141] and Aiman's syndrome (1979). [142] Since it was not understood that these different presentations were all caused by the same set of mutations in the androgen receptor gene, a unique name was given to each new combination of symptoms, resulting in a complicated stratification of seemingly disparate disorders. [80] [143]

Over the last 60 years, as reports of strikingly different phenotypes were reported to occur even among members of the same family, and as steady progress was made towards the understanding of the underlying molecular pathogenesis of AIS, these disorders were found to be different phenotypic expressions of one syndrome caused by molecular defects in the androgen receptor gene. [5] [12] [80] [143]

AIS is now the accepted terminology for the syndromes resulting from unresponsiveness of the target cell to the action of androgenic hormones. [5] CAIS encompasses the phenotypes previously described by "testicular feminization", Morris' syndrome, and Goldberg-Maxwell syndrome; [5] [144] PAIS includes Reifenstein syndrome, Gilbert-Dreyfus syndrome, Lub's syndrome, "incomplete testicular feminization", and Rosewater syndrome; [143] [145] [146] and MAIS includes Aiman's syndrome. [147]

The more virilized phenotypes of AIS have sometimes been described as "undervirilized male syndrome", "infertile male syndrome", "undervirilized fertile male syndrome", etc., before evidence was reported that these conditions were caused by mutations in the AR gene. [148] These diagnoses were used to describe a variety of mild defects in virilization; as a result, the phenotypes of some men who have been diagnosed as such are better described by PAIS (e.g. micropenis, hypospadias, and undescended testes), while others are better described by MAIS (e.g. isolated male infertility or gynecomastia). [5] [148] [53] [146] [149] [150]

Society and culture

In the film Orchids, My Intersex Adventure , Phoebe Hart and her sister Bonnie Hart, both women with CAIS, documented their exploration of AIS and other intersex issues. [151]

Recording artist Dalea is a Hispanic-American Activist who is public about her CAIS. She has given interviews about her condition [152] [153] and founded Girl Comet, a non-profit diversity awareness and inspiration initiative. [154]

In 2017, fashion model Hanne Gaby Odiele disclosed that they were born with androgen insensitivity syndrome. As a child, they underwent medical procedures relating to the condition, [155] which they said took place without their or their parents' informed consent. [156] They were told about their intersex condition weeks before beginning their modelling career. [156]

In the 1991 Japanese horror novel Ring and its sequels, by Koji Suzuki (later adapted into Japanese, Korean, and American films), the central antagonist Sadako has this syndrome, as revealed by Dr Nagao when confronted by Ryuji and Asakawa. [157] Sadako's condition is referred to by the earlier name "testicular feminisation syndrome".

In season 2, episode 13 ("Skin Deep") of the TV series House, the main patient's cancerous testicle is mistaken for an ovary due to the patient's undiscovered CAIS. [158] The episode has been criticized for its medical inaccuracy as well as its stigmatizing and offensive portrayal of CAIS. [159]

In season 2 of the MTV series Faking It, a character has CAIS. The character, Lauren Cooper, played by Bailey De Young, was the first intersex series regular on American television. [160] [161]

In season 8, episode 11 ("Delko for the Defense") of the TV series CSI: Miami, the primary suspect has AIS which gets him off a rape charge.[ citation needed ]

In series 8, episode 5 of Call the Midwife , a woman discovers that she has AIS. She attends a cervical smear and brings up that she has never had a period, and is concerned about having children as she is about to be married. She is then diagnosed with "testicular feminisation syndrome", the old term for AIS. [162]

People with AIS

People with Complete androgen insensitivity syndrome

People with Partial androgen insensitivity syndrome

See also

Related Research Articles

<span class="mw-page-title-main">Lipoid congenital adrenal hyperplasia</span> Medical condition

Lipoid congenital adrenal hyperplasia is an endocrine disorder that is an uncommon and potentially lethal form of congenital adrenal hyperplasia (CAH). It arises from defects in the earliest stages of steroid hormone synthesis: the transport of cholesterol into the mitochondria and the conversion of cholesterol to pregnenolone—the first step in the synthesis of all steroid hormones. Lipoid CAH causes mineralocorticoid deficiency in affected infants and children. Male infants are severely undervirilized causing their external genitalia to look feminine. The adrenals are large and filled with lipid globules derived from cholesterol.

<span class="mw-page-title-main">Sex-determining region Y protein</span> Protein that initiates male sex determination in therian mammals

Sex-determining region Y protein (SRY), or testis-determining factor (TDF), is a DNA-binding protein encoded by the SRY gene that is responsible for the initiation of male sex determination in therian mammals. SRY is an intronless sex-determining gene on the Y chromosome. Mutations in this gene lead to a range of disorders of sex development with varying effects on an individual's phenotype and genotype.

<span class="mw-page-title-main">Sex hormone-binding globulin</span> Human glycoprotein that binds to androgens and estrogens

Sex hormone-binding globulin (SHBG) or sex steroid-binding globulin (SSBG) is a glycoprotein that binds to androgens and estrogens. When produced by the Sertoli cells in the seminiferous tubules of the testis, it is called androgen-binding protein (ABP).

Isolated hypogonadotropic hypogonadism (IHH), also called idiopathic or congenital hypogonadotropic hypogonadism (CHH), as well as isolated or congenital gonadotropin-releasing hormone deficiency (IGD), is a condition which results in a small subset of cases of hypogonadotropic hypogonadism (HH) due to deficiency in or insensitivity to gonadotropin-releasing hormone (GnRH) where the function and anatomy of the anterior pituitary is otherwise normal and secondary causes of HH are not present.

<span class="mw-page-title-main">Partial androgen insensitivity syndrome</span> Medical condition

Partial androgen insensitivity syndrome (PAIS) is a condition that results in the partial inability of the cell to respond to androgens. It is an X linked recessive condition. The partial unresponsiveness of the cell to the presence of androgenic hormones impairs the masculinization of male genitalia in the developing fetus, as well as the development of male secondary sexual characteristics at puberty, but does not significantly impair female genital or sexual development. As such, the insensitivity to androgens is clinically significant only when it occurs in individuals with a Y chromosome. Clinical features include ambiguous genitalia at birth and primary amenhorrhoea with clitoromegaly with inguinal masses. Müllerian structures are not present in the individual.

<span class="mw-page-title-main">Estrogen insensitivity syndrome</span> Medical condition

Estrogen insensitivity syndrome (EIS), or estrogen resistance, is a form of congenital estrogen deficiency or hypoestrogenism which is caused by a defective estrogen receptor (ER) – specifically, the estrogen receptor alpha (ERα) – that results in an inability of estrogen to mediate its biological effects in the body. Congenital estrogen deficiency can alternatively be caused by a defect in aromatase, the enzyme responsible for the biosynthesis of estrogens, a condition which is referred to as aromatase deficiency and is similar in symptomatology to EIS.

<span class="mw-page-title-main">Disorders of sex development</span> Medical conditions involving the development of the reproductive system

Disorders of sex development (DSDs), also known as differences in sex development or variations in sex characteristics (VSC), are congenital conditions affecting the reproductive system, in which development of chromosomal, gonadal, or anatomical sex is atypical. DSDs is a clinical term used in some medical settings for what are otherwise referred to as intersex traits. The term was first introduced in 2006 and has not been without controversy.

<span class="mw-page-title-main">HESX1</span> Protein-coding gene in the species Homo sapiens

Homeobox expressed in ES cells 1, also known as homeobox protein ANF, is a homeobox protein that in humans is encoded by the HESX1 gene.

<span class="mw-page-title-main">GNRHR</span> Protein-coding gene in the species Homo sapiens

Gonadotropin-releasing hormone receptor is a protein that in humans is encoded by the GNRHR gene.

<span class="mw-page-title-main">SRD5A2</span> Protein-coding gene in the species Homo sapiens

The human gene SRD5A2 encodes the 3-oxo-5α-steroid 4-dehydrogenase 2 enzyme, also known as 5α-reductase type 2 (5αR2), one of three isozymes of 5α-reductase.

<span class="mw-page-title-main">Thyroid hormone receptor beta</span> Protein-coding gene in the species Homo sapiens

Thyroid hormone receptor beta (TR-beta) also known as nuclear receptor subfamily 1, group A, member 2 (NR1A2), is a nuclear receptor protein that in humans is encoded by the THRB gene.

<span class="mw-page-title-main">Relaxin/insulin-like family peptide receptor 2</span> Protein-coding gene in the species Homo sapiens

Relaxin/insulin-like family peptide receptor 2, also known as RXFP2, is a human G-protein coupled receptor.

<span class="mw-page-title-main">FSHB</span> Protein-coding gene in the species Homo sapiens

Follitropin subunit beta also known as follicle-stimulating hormone beta subunit (FSH-B) is a protein that in humans is encoded by the FSHB gene. Alternative splicing results in two transcript variants encoding the same protein.

<span class="mw-page-title-main">PROP1</span> Human gene

Homeobox protein prophet of PIT-1 is a protein that in humans is encoded by the PROP1 gene.

<span class="mw-page-title-main">Luteinizing hormone beta polypeptide</span> Protein-coding gene in the species Homo sapiens

Luteinizing hormone subunit beta also known as lutropin subunit beta or LHβ is a polypeptide that in association with an alpha subunit common to all gonadotropin hormones forms the reproductive signaling molecule luteinizing hormone. In humans it is encoded by the LHB gene.

<span class="mw-page-title-main">Aromatase deficiency</span> Medical condition

Aromatase deficiency is a rare condition characterized by extremely low levels or complete absence of the enzyme aromatase activity in the body. It is an autosomal recessive disease resulting from various mutations of gene CYP19 (P450arom) which can lead to ambiguous genitalia and delayed puberty in females, continued linear growth into adulthood and osteoporosis in males and virilization in pregnant mothers. As of 2020, fewer than 15 cases have been identified in genetically male individuals and at least 30 cases in genetically female individuals.

<span class="mw-page-title-main">Complete androgen insensitivity syndrome</span> Medical condition

Complete androgen insensitivity syndrome (CAIS) is an AIS condition that results in the complete inability of the cell to respond to androgens. As such, the insensitivity to androgens is only clinically significant when it occurs in individuals who are exposed to significant amounts of testosterone at some point in their lives. The unresponsiveness of the cell to the presence of androgenic hormones prevents the masculinization of male genitalia in the developing fetus, as well as the development of male secondary sexual characteristics at puberty, but does allow, without significant impairment, female genital and sexual development in those with the condition.

<span class="mw-page-title-main">Mild androgen insensitivity syndrome</span> Medical condition

Mild androgen insensitivity syndrome (MAIS) is a condition that results in a mild impairment of the cell's ability to respond to androgens. The degree of impairment is sufficient to impair spermatogenesis and / or the development of secondary sexual characteristics at puberty in males, but does not affect genital differentiation or development. Female genital and sexual development is not significantly affected by the insensitivity to androgens; as such, MAIS is only diagnosed in males. The clinical phenotype associated with MAIS is a normal male habitus with mild spermatogenic defect and / or reduced secondary terminal hair.

<span class="mw-page-title-main">Leydig cell hypoplasia</span> Medical condition

Leydig cell hypoplasia (LCH), also known as Leydig cell agenesis, is a rare autosomal recessive genetic and endocrine syndrome affecting an estimated 1 in 1,000,000 individuals with XY chromosomes. It is characterized by an inability of the body to respond to luteinizing hormone (LH), a gonadotropin which is normally responsible for signaling Leydig cells of the testicles to produce testosterone and other androgen sex hormones. The condition manifests itself as pseudohermaphroditism, hypergonadotropic hypogonadism, reduced or absent puberty, and infertility.

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