International Journal of
Reproductive Biomedicine
Wed, Apr 24, 2024
[Archive]
Volume 12, Issue 5 (6-2014)
IJRM 2014, 12(5): 351-0 |
Back to browse issues page
Download citation:
BibTeX | RIS | EndNote | Medlars | ProCite | Reference Manager | RefWorks
Send citation to:
BibTeX | RIS | EndNote | Medlars | ProCite | Reference Manager | RefWorks
Send citation to:
Dehghani M, Rossi E, Vetro A, Russo G, Hashemian Z, Zuffardi O. A newborn with ambiguous genitalia and a complex X;Y rearrangement. IJRM 2014; 12 (5) :351-0
URL: http://ijrm.ir/article-1-535-en.html
URL: http://ijrm.ir/article-1-535-en.html
Mohammadreza Dehghani1 
, Elena Rossi1 , Annalisa Vetro2 , Gianni Russo3 , Zahra Hashemian4 , Orsetta Zuffardi * 5
, Elena Rossi1 , Annalisa Vetro2 , Gianni Russo3 , Zahra Hashemian4 , Orsetta Zuffardi * 5
1- Department of Molecular Medicine, University of Pavia, Pavia, Italy
2- Biotechnology Research Laboratories, Fondazione IRCCS Policlinico San Matteo, Pavia, Italy
3- Department of Pediatrics, Endocrine Unit, University Vita-Salute, San Raffaele Hospital, Italy
4- Shahid Sadoughi Hospital, Shahid Sadoughi University of Medical Sciences, Yazd, Iran
5- Department of Molecular Medicine, University of Pavia, Pavia, Italy , zuffardi@unipv.it
2- Biotechnology Research Laboratories, Fondazione IRCCS Policlinico San Matteo, Pavia, Italy
3- Department of Pediatrics, Endocrine Unit, University Vita-Salute, San Raffaele Hospital, Italy
4- Shahid Sadoughi Hospital, Shahid Sadoughi University of Medical Sciences, Yazd, Iran
5- Department of Molecular Medicine, University of Pavia, Pavia, Italy , zuffardi@unipv.it
Keywords: Ambiguous genitalia, 46, XX testicular DSD, Inverted duplication and Xp terminal Deletion(Invdup del), Rearrangement, Array Comparative Genomic Hybridization, FISH.
Full-Text [PDF 244 kb]
(704 Downloads)
| Abstract (HTML) (2692 Views)
Full-Text: (303 Views)
Introduction
In mammals, sex is determined at the early gestation according to the constitution of the sex chromosomes, XY in males and XX in females (1). The Y chromosome is responsible for the development of testis thanks to the SRY gene at distal Yp whose role in sex determination is to initiate testis rather than ovary development from early bipotential gonads (1-3).
Sex development can be divided into two sequential processes: sex determination, in which the undifferentiated gonadal primordium commits to developing into either testes or ovaries; and sex differentiation, in which gonadal hormones act on the internal and external genitalia, resulting in differentiation into sexually dimorphic reproductive structures (1, 4, 5). Disorders of Sexual Development (DSDs) in humans are characterized by a complete or partial mismatch between the genetic sex and the phenotypic sex. Collectively, DSDs occur in at least 1 in 100 live births and include relatively mild forms such as hypospadias (1/500 births) as well as more severe conditions such as ambiguous genitalia (1/4,500 births) and complete sex reversal (46, XY females and 46, XX males; 1 in 20,000 births). Interestingly, DSDs account for 7.5% of all birth defects (2, 6-9).
46, XX testicular DSDs is the new term and classification of XX males or XX sex reversal (10). Based on the person’s phenotype or the genetic cause of 46, XX testicular DSDs, two classification are recognized, the first includes three clinical categories: a) XX males with normal genitalia, b) XX males with ambiguous genitalia, and c) XX true hermaphrodites with ovarian and testicular tissues. XX males can be divided into two molecular categories, according to the presence or absence of the Y-chromosome sequences (12-14). In 46, XX testicular DSD, individuals with two X chromosomes in each cell, which is the pattern that is normally found in females, have a male appearance.
In most cases (80%), individual with this disorder have male external genitalia and, after puberty, develop normal pubic hair and normal penile size, but small testes, gynecomastia, and sterility resulting from azoospermia. Approximately 20% of the 46,XX testicular DSD individuals have ambiguous genitalia at birth ranging from cryptorchidism or hypospadias to a frank ambiguity making difficult gender assignment. In these cases gonads are constituted by ovotestis or mixed gonadal dysgenesis with ovarian-like structures at one side and testis differentiation at the other one.
Although most of the XX DSD subjects suffer from a condition only related to abnormal gonads/genitalia, some of them present with a complex syndrome as it is the case of the palmoplantar hyperkeratosis with squamous cell carcinoma of skin and 46,XX sex reversal (OMIM #610644) due to autosomal recessive mutations in the RSPO1 gene (15). To date, many cases of XX males with or without SRY and apparently with no other Y-chromosome sequences have been reported (14). Approximately 85% of the XX testicular DSD cases are phenotypically male with unambiguous male genitalia at birth and are SRY positive. Most of these individuals and are not diagnosed until that puberty fails to proceed normally (16, 17). Usually they have a shorter-than-average stature (mean height: 168.2 cm, compared to normal mean height: 173.5 cm), gynecomastia, small testes, and azoospermia (18). They rarely present with atypical genitalia (19-22).
The remaining 15% of individuals with XX testicular DSD have ambiguous genitalia and SRY is positive in only a minority of the individuals (16, 23). Here we presented the case of a newborn ascertained because of ambiguous gentalia and some dysmorphic features.
Case report
New born is only child of non-consanguineous couple. The first pregnancy ended in a spontaneous abortion. At birth the proband had normal stature and normal weight with 9/10 Apgar. At clinical examination we found forehead prominence, hypertelorism, saddle nose, thin lips, low set and small ear and bilateral clinodactyly of fifth fingers. The clitoris was hypertrophic and in the inguinal region two small masses were detected. A unic urethral meatus was present below two hypotrophic labia minora. Scrotum-like labia majora and hypospadias were also present. In echosonography gonads were not present in pelvic. The inguinal masses were removed and their histology revealed that they were ovotestes.
PHA-stimulated lymphocytes cultures were set up from peripheral blood from the patient and the parents and the analysis was done on GTG banded metaphases, according to established guidelines. The karyotype was 46, XX with one short arm of the X chromosomes slightly longer. The karyotype of the parents was normal. Array-CGH analysis was performed by using oligonucleotide aCGH platforms (180K SurePrint G3 Human Kit, Agilent Technologies, Santa Clara, CA), as reported elsewhere (23). A 46, XX reference DNA (NA15510, Coriell Cell repositories) was used for all experiments. Changes in DNA copy number at a specific locus were observed as the deviation of the log2ratio value from 0 of at least three consecutive probes, by using Genomic Workbench v. 5.0.14 software (Agilent, ADM-2 algorithm with a threshold of 5). Oligomer positions refer to the Human Genome GRCh37 (hg19) assembly. Array-CGH analysis showed a complex rearrangement with the deletion of the distal Xp of about 10 Mb between Xpter and Xp22.2, and a 19.9Mb duplication of a proximal Xp contiguous region; the Xp region between 10227817-15816305 was normal; a 16.8 Mb portion of the Y chromosome was also present consisting in the entire short arm and a part of long arm with breakpoint in Yq11.22 (Figure 1). The final definition was:
92-205-3/%D9%81%D8%B1%D9%85%D9%88%D9%84_1.jpg)
To confirm array-CGH results and demonstrate the inversion of Xp duplicated region, FISH experiments were performed. All BAC probes used were selected according to the UCSC Human Genome Browser and were obtained from the human library RPC1-11. Alphoid probes were kindly provided by Mariano Rocchi (http://www.biologia.uniba. it/rmc/). X-inactivation analysis was performed according to Allen et al (24). Fluorescent in situ hybridization (FISH) confirmed the Xp deletion, demonstrated that the portion of the Y was translocated to the tip of the abnormal chromosome X and does not contain SRY and that the duplicated portion of chromosome X was inverted (Figure 2 and 3). Altogether, the abnormal chromosome was a dicentric one with the centromere of the Y chromosome apparently inactivated.
X chromosome inactivation studies revealed that the derivative X was inactivated in all the 96 metaphases analyzed (data not shown).
92-205-3/Figure_1.jpg)
Figure 1. oligonucleotide aCGH platforms (180K SurePrint G3 Human Kit, Agilent Technologies, Santa Clara, CA) showed a complex rearrangement with the deletion of the distal Xp of about 10 Mb between Xpter and Xp22.2, and a 19.9Mb duplication of a proximal Xp contiguous region; the Xp region between 10227817-15816305 was normal; a 16.8 Mb portion of the Y chromosome was also present consisting in the entire short arm and a part of long arm with breakpoint in Yq11.22.
92-205-3/Figure_2.jpg)
Figure 2. a: FISH analysis with BAC RP11-294K6 (6,503,905-6,527,019 Mb) confirmed the Xp22.33p22.3 deletion identified by array-CGH. b: FISH analysis with BAC RP11-639O7, covering the SRY gene, demonstrated that the portion of the Y chromosome translocated to the tip of the abnormal chromosome X contains the SRY gene. The short arrows indicate the derivative X. In the box above a cut out of chromosomes X is shown; on the right the derivative X.
92-205-3/Figure_3.jpg)
Figure 3. a: FISH analysis with alphoid probes specific for chromosome X (red) and for chromosome Y (green) showed that the Y centromere has clearly detached signals suggesting its inactivation. b: FISH analysis with BACs within the Xp duplicated region demonstrated that the duplication is inverted : RP11-124B4 (green) in Xp22 at 14,955,137-15,105,389 Mb and RP11-171N17 (red) in Xp22 at 21,969,414-22,248,218 Mb. The short arrow indicates the derivative X.
Discussion
Approximately 20% of the 46, XX testicular DSD individuals have ambiguous genitalia at birth ranging from cryptorchidism or hypospadias to a frank ambiguity making difficult gender assignment. In these cases gonads are constituted by ovotestis or mixed gonadal digenesis with ovarian-like structures at one side and testis differentiation at the other one. Here we presented a case with ambiguous genitalia at birth and inguinal mass with histology of ovotestis after surgery.
In most of the XX males SRY is transposed to the tip of Xp as a consequence of a recurrent Xp;Yp translocation arising predominantly by non-allelic homologous recombination between of PRKX and PRKY in a particular Y chromosome background consisting in a polymorphic cryptic inversion (25, 26). In our case, the SRY gene is indeed located at the end of one X chromosome but the rearrangement is completely different and much more complex leading to a classical inv dup del (Xp) in which the absence of the short arm telomere has been repaired the acquirement of a portion of the Y chromosome containing its centromere (27, 28). As a result, the rearranged chromosome was dicentric although the Y centromere appears inactivated according to the finding of two alphoid spots always detached (Figure 2a). We may speculate that originally the dicentric was unstable with loss of the Y chromosome portion in some cells. This hypothesis might explain the presence in the proband of ambigous genitalia otherwise incomprehensible. This rearrangement is sporadic and therefore this condition doesn’t have recurrent risk.
Our proband is a newborn and so far presents minor dysmorphic signs as forehead prominence, hypertelorism, saddle nose, thin lips, low set and small ear and bilateral clinodactyly of 5th fingers. It seems likely that the deleted and duplicated portions of the X chromosome are responsible for them. The finding of the preferential inactivation of the abnormal X as stated in blood cells should avoid severe pathogenic consequences. This bodes well that the proband won’t develop a real medical condition. Certainly, although part of distal Xp is deleted, the proband should not have short stature being the two PAR regions containing the SHOX1 fully preserved.
In mammals, sex is determined at the early gestation according to the constitution of the sex chromosomes, XY in males and XX in females (1). The Y chromosome is responsible for the development of testis thanks to the SRY gene at distal Yp whose role in sex determination is to initiate testis rather than ovary development from early bipotential gonads (1-3).
Sex development can be divided into two sequential processes: sex determination, in which the undifferentiated gonadal primordium commits to developing into either testes or ovaries; and sex differentiation, in which gonadal hormones act on the internal and external genitalia, resulting in differentiation into sexually dimorphic reproductive structures (1, 4, 5). Disorders of Sexual Development (DSDs) in humans are characterized by a complete or partial mismatch between the genetic sex and the phenotypic sex. Collectively, DSDs occur in at least 1 in 100 live births and include relatively mild forms such as hypospadias (1/500 births) as well as more severe conditions such as ambiguous genitalia (1/4,500 births) and complete sex reversal (46, XY females and 46, XX males; 1 in 20,000 births). Interestingly, DSDs account for 7.5% of all birth defects (2, 6-9).
46, XX testicular DSDs is the new term and classification of XX males or XX sex reversal (10). Based on the person’s phenotype or the genetic cause of 46, XX testicular DSDs, two classification are recognized, the first includes three clinical categories: a) XX males with normal genitalia, b) XX males with ambiguous genitalia, and c) XX true hermaphrodites with ovarian and testicular tissues. XX males can be divided into two molecular categories, according to the presence or absence of the Y-chromosome sequences (12-14). In 46, XX testicular DSD, individuals with two X chromosomes in each cell, which is the pattern that is normally found in females, have a male appearance.
In most cases (80%), individual with this disorder have male external genitalia and, after puberty, develop normal pubic hair and normal penile size, but small testes, gynecomastia, and sterility resulting from azoospermia. Approximately 20% of the 46,XX testicular DSD individuals have ambiguous genitalia at birth ranging from cryptorchidism or hypospadias to a frank ambiguity making difficult gender assignment. In these cases gonads are constituted by ovotestis or mixed gonadal dysgenesis with ovarian-like structures at one side and testis differentiation at the other one.
Although most of the XX DSD subjects suffer from a condition only related to abnormal gonads/genitalia, some of them present with a complex syndrome as it is the case of the palmoplantar hyperkeratosis with squamous cell carcinoma of skin and 46,XX sex reversal (OMIM #610644) due to autosomal recessive mutations in the RSPO1 gene (15). To date, many cases of XX males with or without SRY and apparently with no other Y-chromosome sequences have been reported (14). Approximately 85% of the XX testicular DSD cases are phenotypically male with unambiguous male genitalia at birth and are SRY positive. Most of these individuals and are not diagnosed until that puberty fails to proceed normally (16, 17). Usually they have a shorter-than-average stature (mean height: 168.2 cm, compared to normal mean height: 173.5 cm), gynecomastia, small testes, and azoospermia (18). They rarely present with atypical genitalia (19-22).
The remaining 15% of individuals with XX testicular DSD have ambiguous genitalia and SRY is positive in only a minority of the individuals (16, 23). Here we presented the case of a newborn ascertained because of ambiguous gentalia and some dysmorphic features.
Case report
New born is only child of non-consanguineous couple. The first pregnancy ended in a spontaneous abortion. At birth the proband had normal stature and normal weight with 9/10 Apgar. At clinical examination we found forehead prominence, hypertelorism, saddle nose, thin lips, low set and small ear and bilateral clinodactyly of fifth fingers. The clitoris was hypertrophic and in the inguinal region two small masses were detected. A unic urethral meatus was present below two hypotrophic labia minora. Scrotum-like labia majora and hypospadias were also present. In echosonography gonads were not present in pelvic. The inguinal masses were removed and their histology revealed that they were ovotestes.
PHA-stimulated lymphocytes cultures were set up from peripheral blood from the patient and the parents and the analysis was done on GTG banded metaphases, according to established guidelines. The karyotype was 46, XX with one short arm of the X chromosomes slightly longer. The karyotype of the parents was normal. Array-CGH analysis was performed by using oligonucleotide aCGH platforms (180K SurePrint G3 Human Kit, Agilent Technologies, Santa Clara, CA), as reported elsewhere (23). A 46, XX reference DNA (NA15510, Coriell Cell repositories) was used for all experiments. Changes in DNA copy number at a specific locus were observed as the deviation of the log2ratio value from 0 of at least three consecutive probes, by using Genomic Workbench v. 5.0.14 software (Agilent, ADM-2 algorithm with a threshold of 5). Oligomer positions refer to the Human Genome GRCh37 (hg19) assembly. Array-CGH analysis showed a complex rearrangement with the deletion of the distal Xp of about 10 Mb between Xpter and Xp22.2, and a 19.9Mb duplication of a proximal Xp contiguous region; the Xp region between 10227817-15816305 was normal; a 16.8 Mb portion of the Y chromosome was also present consisting in the entire short arm and a part of long arm with breakpoint in Yq11.22 (Figure 1). The final definition was:
To confirm array-CGH results and demonstrate the inversion of Xp duplicated region, FISH experiments were performed. All BAC probes used were selected according to the UCSC Human Genome Browser and were obtained from the human library RPC1-11. Alphoid probes were kindly provided by Mariano Rocchi (http://www.biologia.uniba. it/rmc/). X-inactivation analysis was performed according to Allen et al (24). Fluorescent in situ hybridization (FISH) confirmed the Xp deletion, demonstrated that the portion of the Y was translocated to the tip of the abnormal chromosome X and does not contain SRY and that the duplicated portion of chromosome X was inverted (Figure 2 and 3). Altogether, the abnormal chromosome was a dicentric one with the centromere of the Y chromosome apparently inactivated.
X chromosome inactivation studies revealed that the derivative X was inactivated in all the 96 metaphases analyzed (data not shown).
Figure 1. oligonucleotide aCGH platforms (180K SurePrint G3 Human Kit, Agilent Technologies, Santa Clara, CA) showed a complex rearrangement with the deletion of the distal Xp of about 10 Mb between Xpter and Xp22.2, and a 19.9Mb duplication of a proximal Xp contiguous region; the Xp region between 10227817-15816305 was normal; a 16.8 Mb portion of the Y chromosome was also present consisting in the entire short arm and a part of long arm with breakpoint in Yq11.22.
Figure 2. a: FISH analysis with BAC RP11-294K6 (6,503,905-6,527,019 Mb) confirmed the Xp22.33p22.3 deletion identified by array-CGH. b: FISH analysis with BAC RP11-639O7, covering the SRY gene, demonstrated that the portion of the Y chromosome translocated to the tip of the abnormal chromosome X contains the SRY gene. The short arrows indicate the derivative X. In the box above a cut out of chromosomes X is shown; on the right the derivative X.
Figure 3. a: FISH analysis with alphoid probes specific for chromosome X (red) and for chromosome Y (green) showed that the Y centromere has clearly detached signals suggesting its inactivation. b: FISH analysis with BACs within the Xp duplicated region demonstrated that the duplication is inverted : RP11-124B4 (green) in Xp22 at 14,955,137-15,105,389 Mb and RP11-171N17 (red) in Xp22 at 21,969,414-22,248,218 Mb. The short arrow indicates the derivative X.
Discussion
Approximately 20% of the 46, XX testicular DSD individuals have ambiguous genitalia at birth ranging from cryptorchidism or hypospadias to a frank ambiguity making difficult gender assignment. In these cases gonads are constituted by ovotestis or mixed gonadal digenesis with ovarian-like structures at one side and testis differentiation at the other one. Here we presented a case with ambiguous genitalia at birth and inguinal mass with histology of ovotestis after surgery.
In most of the XX males SRY is transposed to the tip of Xp as a consequence of a recurrent Xp;Yp translocation arising predominantly by non-allelic homologous recombination between of PRKX and PRKY in a particular Y chromosome background consisting in a polymorphic cryptic inversion (25, 26). In our case, the SRY gene is indeed located at the end of one X chromosome but the rearrangement is completely different and much more complex leading to a classical inv dup del (Xp) in which the absence of the short arm telomere has been repaired the acquirement of a portion of the Y chromosome containing its centromere (27, 28). As a result, the rearranged chromosome was dicentric although the Y centromere appears inactivated according to the finding of two alphoid spots always detached (Figure 2a). We may speculate that originally the dicentric was unstable with loss of the Y chromosome portion in some cells. This hypothesis might explain the presence in the proband of ambigous genitalia otherwise incomprehensible. This rearrangement is sporadic and therefore this condition doesn’t have recurrent risk.
Our proband is a newborn and so far presents minor dysmorphic signs as forehead prominence, hypertelorism, saddle nose, thin lips, low set and small ear and bilateral clinodactyly of 5th fingers. It seems likely that the deleted and duplicated portions of the X chromosome are responsible for them. The finding of the preferential inactivation of the abnormal X as stated in blood cells should avoid severe pathogenic consequences. This bodes well that the proband won’t develop a real medical condition. Certainly, although part of distal Xp is deleted, the proband should not have short stature being the two PAR regions containing the SHOX1 fully preserved.
Type of Study: Original Article |
References
1. Eggers S, Sinclair A. Mammalian sex determination- insights from humans and mice. Chromosome Res 2012; 20: 215-238. [DOI:10.1007/s10577-012-9274-3]
2. Blakless M CA. How Sexually Dimorphic Are We? Review and Synthesis. Am J Hum Biol 2000; 12: 151-166.
https://doi.org/10.1002/(SICI)1520-6300(200003/04)12:2<151::AID-AJHB1>3.0.CO;2-F [DOI:10.1002/(SICI)1520-6300(200003/04)12:23.0.CO;2-F]
3. Kim Y CB. Balancing the bipotential gonad between alternative organ fates: a new perspective on an old problem. Dev Dyn 2006; 235: 2292-2300. [DOI:10.1002/dvdy.20894]
4. Achermann JCH IA. Williams Textbook of Endocrinology. Saunders, Philadelphia; 2011: 869-934.
5. Rey RAGRP. Normal male sexual differentiation and aetiology of disorders of sex development. Best Pract Res Clin Endocrinol Metab 2011; 25: 221-238. [DOI:10.1016/j.beem.2010.08.013]
6. Achermann JC, Hughes IA. Disorders of Sex Development. Williams Textbook of Endocrinology. 12th Ed. Saunders, Philadelphia; 2011.
7. Temel SG ea. Extended pedigree with multiple cases of XX sex reversal in the absence of SRY and of a mutation at the SOX9 locus. Sex Dev 2007; 1: 24-34. [DOI:10.1159/000096236]
8. Sutton EHJ. Identification of SOX3 as an XX male sex reversal gene in mice and humans. J Clin Invest 2011; 121: 328-341. [DOI:10.1172/JCI42580]
9. Hughes IA HC, Ahmed SF, Lee PA Consensus statement on management of intersex disorders. J Pediatr Urol 2006; 2: 148-162. [DOI:10.1016/j.jpurol.2006.03.004]
10. Abusheikha N, Lass A, Brinsden P. XX males without SRY gene and with infertility. Hum Reprod 2001; 16: 717-718. [DOI:10.1093/humrep/16.4.717]
11. Harley MOaVR. Disorders of sex development: new genes, new concepts. Nat Gene 2013; 9: 79- 91.
12. Zenteno JC, Lopez M, Vera C, Mendez JP, Kofman-Alfaro S. Two SRY-negative XX male brothers without genital ambiguity. Hum Genet 1997; 100: 606-610. [DOI:10.1007/s004390050561]
13. de la Chapelle A. The Y-chromosomal and autosomal testis-determining genes. Development 1987; 101 (Suppl.): 33-38.
14. Faith Y, Dorsey MHH, David R. 46,xx SRY negative as a true hermapherodism. Urology 2009; 73: 529-531. [DOI:10.1016/j.urology.2008.09.050]
15. Parma P, Radi O, Vidal V, Chaboissier MC, Dellambra E, Valentini S, et al. R-spondin1 is essential in sex determination, skin differentiation and malignancy. Nat Genet 2006; 38: 1304-1309. [DOI:10.1038/ng1907]
16. Queipo G, Zenteno JC, Pena R, Nieto K, Radillo A, Dorantes LM, et al. Molecular analysis in true hermaphroditism: demonstration of low-level hidden mosaicism for Y-derived sequences in 46,XX cases. Hum Genet 2002; 111: 278-283. [DOI:10.1007/s00439-002-0772-9]
17. Zenteno-Ruiz JC, Kofman-Alfaro S, Mendez JP. 46,XX sex reversal. Arch Med Res 2001; 32: 559-566. [DOI:10.1016/S0188-4409(01)00322-8]
18. de la Chapelle A. Analytic review: nature and origin of males with XX sex chromosomes. Am J Hum Genet 1972; 24: 71-105.
19. Ferguson-Smith MA, Cooke A, Affara NA, Boyd E, Tolmie JL. Genotype-phenotype correlations in XX males and their bearing on current theories of sex determination. Hum Genet 1990; 84: 198-202. [DOI:10.1007/BF00208942]
20. Boucekkine C, Toublanc JE, Abbas N, Chaabouni S, Ouahid S, Semrouni M, et al. Clinical and anatomical spectrum in XX sex reversed patients. Relationship to the presence of Y specific DNA-sequences. Clin Endocrinol 1994; 40: 733-742. [DOI:10.1111/j.1365-2265.1994.tb02506.x]
21. Ergun-Longmire B, Vinci G, Alonso L, Matthew S, Tansil S, Lin-Su K, et al. Clinical, hormonal and cytogenetic evaluation of 46,XX males and review of the literature. J Pediatric Endocrinol Metab 2005; 18: 739-748. [DOI:10.1515/JPEM.2005.18.8.739]
22. State-specific rates of mental retardation--United States, 1993. MMWR Morbidity and mortality weekly report 1996; 45: 61-65.
23. Kusz K, Kotecki M, Wojda A, Szarras-Czapnik M, Latos-Bielenska A, Warenik-Szymankiewicz A, et al. Incomplete masculinisation of XX subjects carrying the SRY gene on an inactive X chromosome. J Med Genet 1999; 36: 452-456.
24. Jobling MA. A selective difference between human Y-chromosomal DNA haplotypes. Current Biol 1998; 8: 4. [DOI:10.1016/S0960-9822(98)00020-7]
25. Rosser ZH, Balaresque P, Jobling MA. Gene conversion between the X chromosome and the male-specific region of the Y chromosome at a translocation hotspot. Am J Hum Genet 2009; 85: 130-134. [DOI:10.1016/j.ajhg.2009.06.009]
26. Bonaglia MC, Giorda R, Massagli A, Galluzzi R, Ciccone R, Zuffardi O. A familial inverted duplication/deletion of 2p25.1-25.3 provides new clues on the genesis of inverted duplications. Eur J Hum Genet 2009; 17: 179-186. [DOI:10.1038/ejhg.2008.160]
27. Zuffardi O, Bonaglia M, Ciccone R, Giorda R. Inverted duplications deletions: underdiagnosed rearrangements? Clin Genet 2009; 75: 505-513. [DOI:10.1111/j.1399-0004.2009.01187.x]
Send email to the article author
| Rights and permissions | |
 |
This work is licensed under a Creative Commons Attribution-NonCommercial 4.0 International License. |
