An E-box within the MHC IIB gene is bound by MyoD and is required for gene expression in fast muscle.

The myosin heavy chain (MHC) IIB gene is selectively expressed in skeletal muscles, imparting fast contractile kinetics. Why the MHC IIB gene product is expressed in muscles like the tibialis anterior (TA) and not expressed in muscles like the soleus is currently unclear. It is shown here that the mutation of an E-box within the MHC IIB promoter decreased reporter gene activity in the fast-twitch TA muscle 90-fold as compared with the wild-type promoter. Reporter gene expression within the TA required this E-box for activation of a heterologous construct containing upstream regulatory regions of the MHC IIB promoter linked to the basal 70-kDa heat shock protein TATA promoter. Electrophoretic mobility shift assays demonstrated that mutation of the E-box prevented the binding of both MyoD and myogenin to this element. In cotransfected C2C12 myotubes and Hep G2 cells, MyoD preferentially activated the MHC IIB promoter in an E-box-dependent manner, whereas myogenin activated the MHC IIB promoter to a lesser extent, and in an E-box-independent manner. A time course analysis of hindlimb suspension demonstrated that the unweighted soleus muscle activated expression of MyoD mRNA before the de novo expression of MHC IIB mRNA. These data suggest a possible causative role for MyoD in the observed upregulation of MHC IIB in the unweighted soleus muscle.

Androgen insensitivity syndrome: a survey of diagnostic procedures and management in the UK.

OBJECTIVE: A two year survey of androgen insensitivity syndrome (AIS) to assess current diagnostic and management strategies. METHODS: Cases were ascertained by inclusion on the British Paediatric Surveillance Unit monthly report card for 24 months. RESULTS: Fifty one of 139 notifications were confirmed as AIS; 29 cases were complete AIS and 22 cases partial AIS. Seventy six per cent of complete AIS presented with an inguinal hernia, and half the complete AIS patients had an established family history of the disorder. Presentation in the partial AIS group was through ambiguous or undermasculinised genitalia; 59% of partial AIS were raised as male. CONCLUSIONS: The importance of karyotyping girls with inguinal hernias is confirmed, and further attention should be given to genetic counselling for families of complete AIS patients. A large number of cases were misreported as partial AIS, emphasising the importance of undertaking a comprehensive diagnostic evaluation in intersex states. A large percentage of children with partial AIS were raised as boys despite severe genital undermasculinisation, indicating the current lack of validated measures that predict genital response to androgen treatment. The management of AIS is discussed and diagnostic guidelines provided to improve the diagnostic yield in AIS.

Phenotypic diversity in siblings with partial androgen insensitivity syndrome.

The androgen insensitivity syndrome is a heterogeneous disorder with a wide spectrum of phenotypic abnormalities, ranging from complete female to ambiguous forms that more closely resemble males. The primary abnormality is a defective androgen receptor protein due to a mutation of the androgen receptor gene. This prevents normal androgen action and thus leads to impaired virilisation. A point mutation of the androgen receptor gene affecting two siblings with partial androgen insensitivity syndrome is described. One had cliteromegaly and labial fusion and was raised as a girl, whereas the other sibling had micropenis and penoscrotal hypospadias and was raised as a boy. Both were shown to have the arginine 840 to cysteine mutation. The phenotypic variation in this family is thus dependent on factors other than abnormalities of the androgen receptor gene alone.

Wide variation in androgen receptor dysfunction in complete androgen insensitivity syndrome.

Androgen insensitivity syndrome (AIS) is a disorder of male sexual differentiation caused by mutations in the androgen receptor (AR) gene. The partial form (PAIS), associated with varying degrees of receptor dysfunction, presents with a range of undervirilization phenotypes. The complete form (CAIS) is characterized by normal female external appearance at birth. In these cases the receptor is often absent or inactive. However, cases have been described where the mutant receptor concerned has considerable residual activity in in vitro assays. Here we describe the effects of five mutations, Gly750Asp, Leu762Phe, Ala765Thr, Asp864Asn and Leu907Phe, identified in complete androgen insensitivity patients. In vitro assays of mutant androgen receptors expressed in a mammalian cell line showed that the Gly750Asp, Leu762Phe and Ala765Thr mutations cause almost complete loss of androgen-binding activity, suggesting that these residues are critical for ligand binding. However, receptors with Asp864Asn and Leu907Phe, although defective, were capable of considerable binding and transactivation activity. Given that some mutations identified in PAIS patients have a more severe effect on androgen receptor function than two CAIS mutations described here, these results provide further evidence that other factors, including genetic background, can have a significant impact on the phenotype associated with a particular AR mutation.

Androgen insensitivity with mental retardation: a contiguous gene syndrome?

We present data to suggest the existence of a mental retardation (MR) locus at Xq11.2-q12 between DXS1 and DXS905, identified in two subjects with complete androgen insensitivity syndrome (CAIS) and MR. Androgen insensitivity syndrome is a disorder of male sexual differentiation caused by a defect in the androgen receptor (AR) gene (Xq11-q12). Two subjects with CAIS resulting from a complete deletion of the AR gene have previously been reported, one of whom also has MR. We have identified another mentally retarded person with a complete deletion of the AR gene. The deletion in the two patients with CAIS and MR extends past the AR gene and includes several marker loci both proximal and distal to the AR gene, the limits of the deletions being DXS1 and DXS905. The deletions in the CAIS patients who do not have MR do not include any of the markers outside the AR gene itself. These data suggest that located close to the AR gene is a gene which is implicated in non-specific MR.

Functional analysis of six androgen receptor mutations identified in patients with partial androgen insensitivity syndrome.

Partial androgen insensitivity syndrome (PAIS) is caused by defects in the androgen receptor gene and presents with a wide range of undervirilization phenotypes. We studied the consequences of six androgen receptor ligand-binding domain mutations on receptor function in transfected cells. The mutations, Met742Ile, Met780Ile, Gln798Glu, Arg840Cys, Arg855His and Ile869Met, were identified in PAIS patients with phenotypes representing the full spectrum seen in this condition. In all cases the androgen receptor was found to be defective, suggesting that the mutation is the cause of the clinical phenotype. The Gln798Glu mutation is exceptional in that it did not cause an androgen-binding defect in our system, although the mutant receptor was defective in transactivation assays. This mutation may affect an aspect of binding not tested, or may be part of a functional subdomain of the ligand-binding domain involved in transactivation. Overall we found milder mutations to be associated with milder clinical phenotypes. There is also clear evidence that phenotype is not solely dependent on androgen receptor function. Some of the mutant receptors were able to respond to high doses of androgen in vitro, suggesting that patients carrying these mutations may be the best candidates for androgen therapy. One such mutation is Ile869Met. A patient carrying this mutation has virilized spontaneously at puberty, so in vivo evidence agrees with the experimental result. Thus a more complete understanding of the functional consequences of androgen receptor mutations may provide a more rational basis for gender assignment in PAIS.

Genetic counselling in complete androgen insensitivity syndrome: trinucleotide repeat polymorphisms, single-strand conformation polymorphism and direct detection of two novel mutations in the androgen receptor gene.

OBJECTIVE: Androgen insensitivity syndrome is a disorder of male sexual development which results in varying degrees of undervirilization in 46XY individuals with functional testes. In the most severe form, complete androgen insensitivity syndrome (CAIS), patients have a normal female appearance. Although CAIS is not life-threatening, affected individuals are infertile and require counselling, gonadectomy, hormone therapy, and sometimes vaginoplasty. Many families therefore request genetic counselling. Defects in the androgen receptor gene account for most if not all cases of CAIS. The purpose of this study was to evaluate the use of the polyglutamine and polyglycine trinucleotide repeat polymorphisms in the first exon of the androgen receptor gene for carrier status determination in three CAIS families. In two of these families novel mutations in the androgen receptor gene were subsequently identified which allowed confirmation of carrier status and also a prenatal diagnosis to be made in one family. PATIENTS: Three CAIS families were studied. The index cases all presented with a clinical phenotype typical of CAIS. MEASUREMENTS: Family members were typed initially for the polyglutamine repeat. In one family this was not informative and the polyglycine repeat was therefore studied. In this and one further family, the androgen receptor gene was sequenced to identify the mutation causing the CAIS. RESULTS: On the basis of information from trinucleotide repeat analysis carrier status could be assessed in each family. In one family, evidence for somatic instability of the polyglutamine repeat was found. In the same family, a novel mutation in the androgen receptor gene, which substituted valine for leucine 881, was identified. Other family members were subsequently typed for the mutation and a prenatal diagnosis was performed. A novel mutation was also identified in a second family substituting the glycine codon at position 371 with a stop codon. Other family members were typed for this mutation. CONCLUSIONS: Both the polyglutamine and polyglycine repeat polymorphisms are useful for the genetic counselling of complete androgen insensitivity syndrome families. In some cases, however, where the family history is limited, more precise information can be provided only once the androgen receptor mutation causing the complete androgen insensitivity syndrome has been identified.

Effects of a fast-track closing on a nursing facility population.

Sixty-nine patients in a nursing facility were subjected to sudden, forced relocation to other nursing facilities when the facility they were in failed to meet conditions for participation in the Medicaid program. A retrospective study was conducted to examine the effects one year after transfer. Comparisons between those returned following recertification of the facility and those not returned demonstrated dramatic differences; 65 percent of the first group suffered deterioration or death, compared with 19 percent of the second group. Other factors found to be associated with high death rates or worsening of condition one year later were being male, severe physical or mental impairment, and lack of social support. Findings verify that serious adverse effects occur when unprepared patients are suddenly relocated and suggest that return to the facility of origin can mitigate those effects. Implications for policy and practice are discussed.

The androgen receptor gene mutations database.

The androgen receptor gene mutations database is a comprehensive listing of mutations published in journals and meetings proceedings. The majority of mutations are point mutations identified in patients with androgen insensitivity syndrome. Information is included regarding the phenotype, the nature and location of the mutations, as well as the effects of the mutations on the androgen binding activity of the receptor. The current version of the database contains 149 entries, of which 114 are unique mutations. The database is available from EMBL (NetServ@EMBL-Heidelberg.DE) or as a Macintosh Filemaker file (mc33001@musica.mcgill.ca).

Androgen insensitivity syndrome.

In a relatively short period of time, understanding of the fundamental causes of androgen insensitivity syndromes has improved dramatically. This has been brought about by the combination of several disciplines, including endocrinology, genetics, developmental and molecular biology. Mutations can be identified in the androgen receptor gene in suspected cases of AIS, and their functional consequences examined in various in-vitro systems. This information can then be correlated with the clinical presentation of the patient, and is beginning to provide an explanation for the highly variable clinical presentation of AIS. It is to be hoped that this information will also help to predict the likely outcome of androgen therapy in infants with PAIS and an intersex phenotype. More speculatively, functional studies may also lead to novel strategies for the treatment of patients. This would then be of enormous benefit to both patient and parents. Furthermore, the identification of a mutation allows precise information for genetic counselling of families affected by AIS. However, many questions still remain to challenge clinicians and scientists alike. These include the risk of testicular malignancy in patients with AIS and currently there is no worldwide consensus on the stage at which testes should be removed from patients reared as female. There are also significant challenges in patient counselling. Although there is greater understanding of the molecular defects that cause AIS, there are several examples of patients with a similar degree of receptor dysfunction, or even the same mutation, but whose phenotypes are widely different. Other factors must therefore contribute to the clinical presentation of AIS, although these have not been identified. Finally, there are the mutations in patients with Kennedy's disease. The consequences of the mutations are unexplained and are a clear indication that there is still a great deal to discover about the function and biology of androgen receptors.

Mutational screening of the Wilms's tumour gene, WT1, in males with genital abnormalities.

Several lines of evidence suggest that the Wilms's tumour susceptibility gene, WT1, has an important role in genital as well as kidney development. WT1 is expressed in developing kidney and genital tissues. Furthermore, mutations in WT1 have been detected in patients with the Denys-Drash syndrome (DDS), which is characterised by nephropathy, genital abnormalities, and Wilms's tumour. It is possible that WT1 mutations may cause genital abnormalities in the absence of kidney dysfunction. We tested this hypothesis by screening the WT1 gene for mutation in 12 46,XY patients with various forms of genital abnormality. Using single strand conformation polymorphism (SSCP) we did not detect any WT1 mutations in these patients. However, in addition to the 12 patients, three DDS patients were also analysed using SSCP, and in all three cases heterozygous WT1 mutations were found which would be predicted to disrupt the DNA binding activity of WT1 protein. These results support the notion that DDS results from a dominant WT1 mutation. However, WT1 mutations are unlikely to be a common cause of male genital abnormalities when these are not associated with kidney abnormalities.

Phenotypic variation and detection of carrier status in the partial androgen insensitivity syndrome.

The partial androgen insensitivity syndrome occurs in 46,XY subjects with phenotypes ranging from perineoscrotal hypospadias with cryptorchidism and micropenis (mild undervirilisation) to clitoromegaly and partial labial fusion (marked undervirilisation). Within an affected family, wide variation in the degree of genital ambiguity between individuals can be seen. Two cousins of a previously reported subject who had severe genital ambiguity and partial androgen insensitivity were investigated. Neither of the cousins had genital abnormalities as marked as the index case, who also had qualitatively abnormal androgen binding and two mutations of the androgen receptor gene. Despite marked phenotypic differences between the index case and his cousins, similar androgen binding and the same androgen receptor mutations were shown in the cousins. Furthermore, one of the androgen receptor gene mutations has been shown in the mother and sister of one of the boys indicating that they are carriers. Thus phenotypic variation in families affected by partial androgen insensitivity is dependent on factors other than abnormalities of the androgen receptor gene alone. Although carrier status in partial androgen insensitivity can be determined, the severity of genital abnormalities in an affected offspring cannot be reliably predicted.

Mutations of the androgen receptor gene identified in perineal hypospadias.

Hypospadias is a common urological abnormality and may occur in simple (glandular or penile) or severe forms (perineal). Perineal hypospadias often occurs in association with other genital abnormalities, such as bilateral cryptorchidism and micropenis, and may be the result of partial androgen insensitivity. We have investigated the androgen binding status and androgen receptor gene of boys from two unrelated families. The first pair of brothers had partial androgen insensitivity with perineal hypospadias, bilateral cryptorchidism, and micropenis, while the other boys had isolated perineal hypospadias. Qualitative androgen binding defects were shown in both sets of brothers and different point mutations of the androgen receptor gene were found in the two families. These findings suggest that the genital abnormalities in the affected brothers result from defects in the androgen receptor. Furthermore, severe familial hypospadias may be a previously unrecognised part of the phenotypic spectrum of the partial androgen insensitivity syndrome. This study provides valuable information for the genetic counselling of families affected by this X linked genital abnormality.

Androgen receptor gene mutations identified by SSCP in fourteen subjects with androgen insensitivity syndrome.

The androgen insensitivity syndrome (AIS) is a disorder of male sexual development resulting in a wide range of clinical phenotypes. AIS is classified into two phenotypic forms: complete (CAIS) and partial (PAIS). To determine the molecular basis of the phenotypic diversity in AIS, we have studied 27 subjects (13 CAIS, 14 PAIS), spanning the full range of AIS phenotypes. We report the results of a mutation screen of the androgen receptor gene. The coding regions of the gene were amplified by the polymerase chain reaction and screened for single strand conformation polymorphisms to identify mutations. This was followed by DNA sequencing of putative mutant segments. Androgen receptor gene mutations were identified in nine CAIS and five PAIS subjects. Two of the CAIS mutations in exon A resulted in frameshifts. A third CAIS mutation resulted in the deletion of a single amino acid from the ligand binding domain of the receptor. All other mutations caused single amino acid substitutions in the ligand binding domain. These results suggest that mutations affecting the ligand binding domain of the androgen receptor are the most frequent cause of AIS, although some cases of PAIS may be the result of other, as yet undefined, genetic lesions.

Role of the androgen receptor in male sexual differentiation.

The two androgens responsible for all aspects of male sexual differentiation are testosterone and dihydrotestosterone. The action of both these steroids is mediated by a specific intracellular receptor, the androgen receptor, which is a member of the nuclear receptor superfamily. The androgen receptor gene has been cloned and is located on the X chromosome at Xq11-12. Mutations of this gene have been found in subjects with both complete and partial androgen insensitivity. In a study of 27 subjects with the androgen insensitivity syndrome, we have identified mutations in 14, using a rapid mutation screening assay. The same technique has also been used to determine carrier status in an affected family. We have also identified a mutation in two brothers who show perineal hypospadias as the only evidence of undervirilisation. Familial severe hypospadias should therefore be included as part of the phenotypic spectrum of partial androgen insensitivity. The study of naturally occurring mutations of the androgen receptor gene is providing further information on the function of the androgen receptor and its role in normal male sexual differentiation.

Male pseudohermaphroditism: clinical management, diagnosis and treatment.

Male pseudohermaphroditism (MPH) is a disorder of sexual differentiation whereby the external genitalia are at variance with a male karyotype and the presence of testes. Abnormalities of Leydig cell function are an important cause of MPH, but postnatal age must be considered when interpreting the testosterone response when HCG stimulation is used as a diagnostic test. Androgen insensitivity is also a common cause of MPH; the specific defect in androgen receptor function is currently the subject of intense study, using a combination of biochemical assays and molecular analysis of the androgen receptor gene. The treatment of MPH is influenced by genital tissue responsiveness to androgens and the technical complexity of reconstructive surgical procedures. There is a need for information on the outcome of MPH treatment regarding pubertal development, sexual performance and fertility.

Linear order of new and established DNA markers around the fragile site at Xq27.3.

We have used recombinant clones derived from microdissection of the fragile X region to characterize breakpoints around the fragile site at Xq27.3. So far, no microdissection markers derived from Xq28 material have been found, thus allowing a rapid screening for clones surrounding the fragile site by their presence in a somatic cell hybrid containing Xq27.2-Xqter. A total of 43 new DNA markers from Xq27 have been sublocalized within this chromosome band. Of these new DNA markers, 5 lie in an interval defined as containing the fragile X region. The saturation of Xq27 with DNA markers by microdissection demonstrates the power of this technique and provides the resources for generating a complete physical map of the region.

Mapping of a cerebellar degeneration related protein and DXS304 around the fragile site.

We have localized the gene encoding a cerebellar degeneration related (CDR) protein to a region proximal to the fragile site close to DXS98 and DXS105. This gene is polymorphic with the enzyme RsaI and therefore also provides a new genetic marker in this region. We have refined the localization of the locus DXS304 distal to the breakpoint in a patient suffering from Hunter disease. This confirms the localization of DXS304 distal to the fragile site previously suggested by linkage studies and localizes the fragile X mutation to a relatively small region between the Hunter breakpoint and the breakpoint in another hybrid B17.