Entry - #261550 - PERSISTENT MULLERIAN DUCT SYNDROME, TYPES I AND II; PMDS - OMIM - (MIRROR)

 
ICD+
# 261550

PERSISTENT MULLERIAN DUCT SYNDROME, TYPES I AND II; PMDS


Alternative titles; symbols

PSEUDOHERMAPHRODITISM, MALE INTERNAL
HERNIA UTERI INGUINALE
PERSISTENT OVIDUCT SYNDROME
FEMALE GENITAL DUCTS IN OTHERWISE NORMAL MALE


Phenotype-Gene Relationships

Location Phenotype Phenotype
MIM number 		Inheritance Phenotype
mapping key 		Gene/Locus Gene/Locus
MIM number
12q13.13 Persistent Mullerian duct syndrome, type II 261550 AR 3 AMHR2 600956
19p13.3 Persistent Mullerian duct syndrome, type I 261550 AR 3 AMH 600957
Clinical Synopsis
 

GU
- Bilateral cryptorchidism
- Normal penis
Abdomen
- Inguinal hernias
- Inguinal uterus and fallopian tubes
Lab
- Antimullerian hormone (AMH) defect
- Premature centromeric divisions and hypoploid counts
Inheritance
- Autosomal recessive with male sex limitation
▲ Close

TEXT

A number sign (#) is used with this entry because persistent mullerian duct syndrome (PMDS) is caused by heterozygous mutation in the gene encoding anti-mullerian hormone (AMH; 600957) or in the AMH receptor gene (AMHR; 600956). These 2 forms of persistent mullerian duct syndrome are referred to as type I and type II, respectively.

Description

The persistent mullerian duct syndrome is characterized by the persistence of mullerian derivatives, uterus and tubes, in otherwise normally virilized males (summary by Knebelmann et al., 1991).


Clinical Features

The typical case is that of a male with bilateral cryptorchidism and inguinal hernias but normal male external genitalia otherwise. At the time of hernia repair, a uterus and fallopian tubes are found in the inguinal canal. The gonads are testes (Nilson, 1939).

Harbison et al. (1991) reported a patient with PMDS who was born to healthy unrelated New York parents of Italian descent. A right inguinal hernia was noted at the age of 1 month. Surgery on the 79th day of life revealed that both gonads were within the right hernia sac. Attached to each gonad was an unremarkable epididymis, vas deferens, and fallopian tube. Between the fallopian tubes was what appeared to be an infantile uterus. No serum anti-mullerian hormone could be detected by enzyme-linked immunosorbent assay.


Pathogenesis

The AMH hormone, also known as mullerian inhibiting substance (MIS), is a glycoprotein homodimer produced by Sertoli cells not only during the period when it is responsible for regression of the mullerian ducts but also in late pregnancy, after birth, and even, although at a much reduced rate, in adulthood. In the female, low amounts of AMH are released into the follicular fluid by mature granulosa cells. (Sertoli cells, which produce AMH, require the presence of a Y chromosome; presumably it is the Sertoli cell alone that requires the presence of testis-determining factor (TDF). The Sertoli cell population in an XX/XY chimeric mouse is composed entirely of XY cells.) In a case of persistent mullerian duct syndrome, Rangnekar et al. (1990) found that 50% of metaphases showed premature centromeric divisions and hypoploid counts. The formation of sex cords populated by primordial germ cells precedes the differentiation of the gonads. Because granulosa and Sertoli cells both originate from bipotential sex-cord cells and produce MIS, Gustafson et al. (1992) hypothesized that sex-cord tumors might secrete large amounts of this hormone. In a woman with an ovarian sex-cord tumor with annular tubules, a rare tumor with the characteristics of both granulosa and Sertoli cells, they found a markedly elevated serum level of MIS and demonstrated the usefulness of measuring MIS in serum for detection of persistent or recurrent disease.

The H-Y ('male') antigens were defined originally in the mouse by graft rejection (Eichwald and Silmser, 1955); see histocompatibility Y antigen (426000). The H-Y antigen identified by graft rejection is different from that identified by antibody, the latter being referred to as 'serologic H-Y' or 'serologically detectable male' (SDM) antigen. SDM antibodies are raised by sensitizing female rodents with skin grafts or lymphoid cells from syngeneic males. Typing for SDM is then accomplished by absorption of SDM antibody and testing of the absorbed antibody for residual activity on male cells or cell extracts. There appear to be at least 2 SDM antigens. One is an integral part of the membrane of male cells and one is a soluble factor secreted by the Sertoli cells of the testis. Testis-secreted SDM can sex-reverse ovarian cells, causing them to form tubular structures in slow rotation cultures. These and other similar data implied a role for Sertoli-cell-secreted SDM in the development of the mammalian testis. Muller et al. (1993) presented evidence that testis-secreted H-Y is identical to mullerian inhibiting substance (AMH). Both are released by Sertoli cells; both evidently are encoded by autosomal genes under the control of the Y chromosome; both are found in the mature rat ovary; both induce sex reversal of ovarian cells in vitro; both are implicated in the sex reversal of ovarian cells in vivo; and both react specifically with the same antibodies.


Inheritance

Guell-Gonzalez et al. (1971), Morillo-Cucci and German (1971), and Armendares et al. (1973) described affected brothers. Von Seemen (1927) observed parental consanguinity. Affected sibs and parental consanguinity suggested autosomal recessive inheritance.

Naguib et al. (1989) reported an Arab Bedouin family with 4 affected males, 2 brothers and 2 of their maternal uncles. Superficially the pedigree suggested X-linked recessive inheritance, but the consanguinity of the parents of the maternal uncles suggested autosomal recessive inheritance.

Sloan and Walsh (1976) reported 2 affected half brothers with different fathers, suggesting X-linked recessive inheritance rather than autosomal recessive inheritance with male sex limitation.


Molecular Genetics

Knebelmann et al. (1991) demonstrated a missense mutation in the AMH gene in a patient with AMH-negative persistent mullerian duct syndrome (600957.0001).

PMDS is biologically heterogeneous: in some cases, bioactive AMH is normally expressed by testicular tissue, while in others no AMH is produced. Imbeaud et al. (1994) performed molecular analysis of the AMH gene in 21 patients and their families. In 6 patients with normal serum concentration of AMH, the AMH was normal or contained only polymorphisms and silent mutations, supporting the hypothesis that the condition is due to end-organ resistance. In the 15 remaining patients with low or undetectable levels of serum AMH, 9 novel mutations were discovered. When present in homozygotes or compound heterozygotes, these mutations were associated with the PMDS phenotype, the same mutation never being observed in 2 different families. The first 3 exons of the AMH gene appeared particularly prone to mutation, although they are less GC rich than the last 2 exons and code for the N-terminal part of the AMH protein, which is not in itself essential to bioactivity.

Imbeaud et al. (1995) demonstrated a mutation in the gene encoding the AMH receptor (600956.0001) in a 3-month-old boy of Pakistani extraction. The AMH gene was normal by sequencing and the production of normal AMH was demonstrated by the fact that normal regression of fetal rat mullerian ducts was elicited by coculture with a small fragment of testis from the patient.

Imbeaud et al. (1996) reported results of molecular studies on 38 families with PMDS. They identified the basis of the condition, namely 16 AMH and 16 AMHR mutations in 32 families. Six of the patients were postpubertal and, since AMH production is normally repressed in these patients, determination of the level of AMH was no longer informative. In prepubertal patients, the type of genetic defect leading to PMDS could be predicted from the level of serum AMH, which is very low or undetectable in PMDS type I due to AMH mutations and at the upper limit of normal in receptor type II mutations. AMH mutations were extremely diverse. AMH mutations were identified in 16 families, including 9 previously reported families (Imbeaud et al., 1994). Imbeaud et al. (1996) reported that exon 1 and the 3-prime half of exon 5 of AMH are the main sites of deleterious changes including short deletions and missense mutations. AMH receptor mutations leading to type II PMDS were detected in 16 patients and 10 of these patients had a 27-bp deletion in exon 10 on at least one allele (600956.0002). This deletion was thus implicated in 25% of the PMDS patients analyzed by Imbeaud et al. (1996). This deletion was present in the homozygous state in 4 patients and it was coupled with missense mutations in 7 patients.

Lang-Muritano et al. (2001) reported 2 brothers with bilateral cryptorchidism in whom the diagnosis of persistent mullerian duct syndrome was made on the basis of laparoscopic evidence of uterus and tubes, undetectable plasma levels of AMH, and homozygosity for a 23-bp insertion in exon 5 of the AMH gene (600957.0004).


REFERENCES

  1. Armendares, S., Buentello, L., Frenk, S. Two male sibs with uterus and fallopian tubes: a rare probably inherited disorder. Clin. Genet. 4: 291-296, 1973. [PubMed: 4148776, related citations] [Full Text]

  2. Beheshti, M., Churchill, B. M., Hardy, B. E., Bailey, J. D., Weksberg, R., Rogan, G. F. Familial persistent mullerian duct syndrome. J. Urol. 131: 968-969, 1984. [PubMed: 6708239, related citations] [Full Text]

  3. Brook, C. G. D., Wagner, H., Zachmann, M., Prader, A., Armendares, S., Frenk, S., Aleman, P., Najjar, S. S., Slim, M. S., Genton, N., Bozic, C. Familial occurrence of persistent mullerian structures in otherwise normal males. Brit. Med. J. 1: 771-773, 1973. [PubMed: 4144375, related citations] [Full Text]

  4. Burgoyne, P. S., Buehr, M., Koopman, P., Rossant, J., McLaren, A. Cell-autonomous action of the testis-determining gene: Sertoli cells are exclusively XY in XX-XY chimaeric mouse testes. Development 102: 443-450, 1988. [PubMed: 3166423, related citations] [Full Text]

  5. Eichwald, E. J., Silmser, C. R. Skin. Transplant. Bull. 2: 148-149, 1955. [PubMed: 12334405, related citations]

  6. Guell-Gonzalez, J. R., Paramino-Ruibal, A., Delgado-Morales, B. Pseudohermafroditismo masculino con genitales interos bisexuales: reporte de 2 hermanos. Rev. Cuba Pediat. 43: 579-586, 1971.

  7. Gustafson, M. L., Lee, M. M., Scully, R. E., Moncure, A. C., Hirakawa, T., Goodman, A., Muntz, H. G., Donahoe, P. K., MacLaughlin, D. T., Fuller, A. F., Jr. Mullerian inhibiting substance as a marker for ovarian sex-cord tumor. New Eng. J. Med. 326: 466-471, 1992. [PubMed: 1732773, related citations] [Full Text]

  8. Harbison, M. D., Magid, M. L. S., Josso, N., Mininberg, D. T., New, M. I. Anti-mullerian hormone in three intersex conditions. Ann. Genet. 34: 226-232, 1991. [PubMed: 1809231, related citations]

  9. Imbeaud, S., Belville, C., Messika-Zeitoun, L., Rey, R., di Clemente, N., Josso, N., Picard, J.-Y. A 27 base-pair deletion of the anti-mullerian type II receptor gene is the most common cause of the persistent mullerian duct syndrome. Hum. Molec. Genet. 5: 1269-1277, 1996. [PubMed: 8872466, related citations] [Full Text]

  10. Imbeaud, S., Carre-Eusebe, D., Rey, R., Belville, C., Josso, N., Picard, J.-Y. Molecular genetics of the persistent mullerian duct syndrome: a study of 19 families. Hum. Molec. Genet. 3: 125-131, 1994. [PubMed: 8162013, related citations] [Full Text]

  11. Imbeaud, S., Faure, E., Lamarre, I., Mattei, M.-G., di Clemente, N., Tizard, R., Carre-Eusebe, D., Belville, C., Tragethon, L., Tonkin, C., Nelson, J., McAuliffe, M., Bidart, J.-M., Lababidi, A., Josso, N., Cate, R. L., Picard, J.-V. Insensitivity to anti-mullerian hormone due to a mutation in the human anti-mullerian hormone receptor. Nature Genet. 11: 382-388, 1995. [PubMed: 7493017, related citations] [Full Text]

  12. Knebelmann, B., Boussin, L., Guerrier, D., Legeai, L., Kahn, A., Josso, N., Picard, J.-Y. Anti-mullerian hormone Bruxelles: a nonsense mutation associated with the persistent mullerian duct syndrome. Proc. Nat. Acad. Sci. 88: 3767-3771, 1991. [PubMed: 2023927, related citations] [Full Text]

  13. Lang-Muritano, M., Biason-Lauber, A., Gitzelmann, C., Belville, C., Picard, Y., Schoenle, E. J. A novel mutation in the anti-mullerian hormone gene as cause of persistent mullerian duct syndrome. Europ. J. Pediat. 160: 652-654, 2001. [PubMed: 11760020, related citations] [Full Text]

  14. Morillo-Cucci, G., German, J. Males with a uterus and fallopian tubes, a rare disorder of sexual development. Birth Defects Orig. Art. Ser. VII(6): 229-231, 1971.

  15. Muller, U., Wachtel, S. S., Jaswaney, V. L., Goldberg, E. H. H-Y (SDM) antibody specifically binds mullerian inhibiting substance. Hum. Genet. 91: 515-518, 1993. [PubMed: 7686131, related citations] [Full Text]

  16. Naguib, K. K., Teebi, A. S., Farag, T. I., Al-Awadi, S. A., El-Khalifa, M. Y., Mahfouz, E.-S. Familial uterine hernia syndrome: report of an Arab family with four affected males. Am. J. Med. Genet. 33: 180-181, 1989. [PubMed: 2764027, related citations] [Full Text]

  17. Nilson, O. Hernia uteri inguinalis beins Manne. Acta Chir. Scand. 83: 231-249, 1939.

  18. Picard, J.-Y., Benarous, R., Guerrier, D., Josso, N., Kahn, A. Cloning and expression of cDNA for anti-mullerian hormone. Proc. Nat. Acad. Sci. 83: 5464-5468, 1986. [PubMed: 2426698, related citations] [Full Text]

  19. Rangnekar, G. V., Loya, B. M., Goswami, L. K., Sengupta, L. K. Premature centromeric divisions and prominent telomeres in a patient with persistent mullerian duct syndrome. Clin. Genet. 37: 69-73, 1990. [PubMed: 1967991, related citations] [Full Text]

  20. Sloan, W. R., Walsh, P. C. Familial persistent mullerian duct syndrome. J. Urol. 115: 459-461, 1976. [PubMed: 4634, related citations] [Full Text]

  21. Von Seemen, H. Pseudohermaphroditismus masculinus internus-kryptochismus-Hernia inguinalis congenita. Bruns' Beitr. Klin. Chir. 141: 370-379, 1927.


Contributors:
Ada Hamosh - updated : 1/30/2002
Moyra Smith - updated : 10/9/1996
Creation Date:
Victor A. McKusick : 6/4/1986
Edit History:
carol : 06/04/2022
carol : 11/12/2013
carol : 11/12/2013
wwang : 7/16/2010
terry : 9/25/2008
terry : 6/2/2004
terry : 1/30/2002
carol : 8/25/2000
carol : 5/24/1999
mark : 10/9/1996
mark : 10/9/1996
carol : 6/28/1996
mark : 12/14/1995
mark : 12/12/1995
terry : 12/4/1995
mark : 8/21/1995
carol : 12/22/1994
mimadm : 3/11/1994
carol : 12/13/1993
carol : 11/10/1993
carol : 4/2/1993

# 261550

PERSISTENT MULLERIAN DUCT SYNDROME, TYPES I AND II; PMDS


Alternative titles; symbols

PSEUDOHERMAPHRODITISM, MALE INTERNAL
HERNIA UTERI INGUINALE
PERSISTENT OVIDUCT SYNDROME
FEMALE GENITAL DUCTS IN OTHERWISE NORMAL MALE


SNOMEDCT: 702358005;   ORPHA: 2856;   DO: 0050791;  


Phenotype-Gene Relationships

Location Phenotype Phenotype
MIM number 		Inheritance Phenotype
mapping key 		Gene/Locus Gene/Locus
MIM number
12q13.13 Persistent Mullerian duct syndrome, type II 261550 Autosomal recessive 3 AMHR2 600956
19p13.3 Persistent Mullerian duct syndrome, type I 261550 Autosomal recessive 3 AMH 600957

TEXT

A number sign (#) is used with this entry because persistent mullerian duct syndrome (PMDS) is caused by heterozygous mutation in the gene encoding anti-mullerian hormone (AMH; 600957) or in the AMH receptor gene (AMHR; 600956). These 2 forms of persistent mullerian duct syndrome are referred to as type I and type II, respectively.

Description

The persistent mullerian duct syndrome is characterized by the persistence of mullerian derivatives, uterus and tubes, in otherwise normally virilized males (summary by Knebelmann et al., 1991).


Clinical Features

The typical case is that of a male with bilateral cryptorchidism and inguinal hernias but normal male external genitalia otherwise. At the time of hernia repair, a uterus and fallopian tubes are found in the inguinal canal. The gonads are testes (Nilson, 1939).

Harbison et al. (1991) reported a patient with PMDS who was born to healthy unrelated New York parents of Italian descent. A right inguinal hernia was noted at the age of 1 month. Surgery on the 79th day of life revealed that both gonads were within the right hernia sac. Attached to each gonad was an unremarkable epididymis, vas deferens, and fallopian tube. Between the fallopian tubes was what appeared to be an infantile uterus. No serum anti-mullerian hormone could be detected by enzyme-linked immunosorbent assay.


Pathogenesis

The AMH hormone, also known as mullerian inhibiting substance (MIS), is a glycoprotein homodimer produced by Sertoli cells not only during the period when it is responsible for regression of the mullerian ducts but also in late pregnancy, after birth, and even, although at a much reduced rate, in adulthood. In the female, low amounts of AMH are released into the follicular fluid by mature granulosa cells. (Sertoli cells, which produce AMH, require the presence of a Y chromosome; presumably it is the Sertoli cell alone that requires the presence of testis-determining factor (TDF). The Sertoli cell population in an XX/XY chimeric mouse is composed entirely of XY cells.) In a case of persistent mullerian duct syndrome, Rangnekar et al. (1990) found that 50% of metaphases showed premature centromeric divisions and hypoploid counts. The formation of sex cords populated by primordial germ cells precedes the differentiation of the gonads. Because granulosa and Sertoli cells both originate from bipotential sex-cord cells and produce MIS, Gustafson et al. (1992) hypothesized that sex-cord tumors might secrete large amounts of this hormone. In a woman with an ovarian sex-cord tumor with annular tubules, a rare tumor with the characteristics of both granulosa and Sertoli cells, they found a markedly elevated serum level of MIS and demonstrated the usefulness of measuring MIS in serum for detection of persistent or recurrent disease.

The H-Y ('male') antigens were defined originally in the mouse by graft rejection (Eichwald and Silmser, 1955); see histocompatibility Y antigen (426000). The H-Y antigen identified by graft rejection is different from that identified by antibody, the latter being referred to as 'serologic H-Y' or 'serologically detectable male' (SDM) antigen. SDM antibodies are raised by sensitizing female rodents with skin grafts or lymphoid cells from syngeneic males. Typing for SDM is then accomplished by absorption of SDM antibody and testing of the absorbed antibody for residual activity on male cells or cell extracts. There appear to be at least 2 SDM antigens. One is an integral part of the membrane of male cells and one is a soluble factor secreted by the Sertoli cells of the testis. Testis-secreted SDM can sex-reverse ovarian cells, causing them to form tubular structures in slow rotation cultures. These and other similar data implied a role for Sertoli-cell-secreted SDM in the development of the mammalian testis. Muller et al. (1993) presented evidence that testis-secreted H-Y is identical to mullerian inhibiting substance (AMH). Both are released by Sertoli cells; both evidently are encoded by autosomal genes under the control of the Y chromosome; both are found in the mature rat ovary; both induce sex reversal of ovarian cells in vitro; both are implicated in the sex reversal of ovarian cells in vivo; and both react specifically with the same antibodies.


Inheritance

Guell-Gonzalez et al. (1971), Morillo-Cucci and German (1971), and Armendares et al. (1973) described affected brothers. Von Seemen (1927) observed parental consanguinity. Affected sibs and parental consanguinity suggested autosomal recessive inheritance.

Naguib et al. (1989) reported an Arab Bedouin family with 4 affected males, 2 brothers and 2 of their maternal uncles. Superficially the pedigree suggested X-linked recessive inheritance, but the consanguinity of the parents of the maternal uncles suggested autosomal recessive inheritance.

Sloan and Walsh (1976) reported 2 affected half brothers with different fathers, suggesting X-linked recessive inheritance rather than autosomal recessive inheritance with male sex limitation.


Molecular Genetics

Knebelmann et al. (1991) demonstrated a missense mutation in the AMH gene in a patient with AMH-negative persistent mullerian duct syndrome (600957.0001).

PMDS is biologically heterogeneous: in some cases, bioactive AMH is normally expressed by testicular tissue, while in others no AMH is produced. Imbeaud et al. (1994) performed molecular analysis of the AMH gene in 21 patients and their families. In 6 patients with normal serum concentration of AMH, the AMH was normal or contained only polymorphisms and silent mutations, supporting the hypothesis that the condition is due to end-organ resistance. In the 15 remaining patients with low or undetectable levels of serum AMH, 9 novel mutations were discovered. When present in homozygotes or compound heterozygotes, these mutations were associated with the PMDS phenotype, the same mutation never being observed in 2 different families. The first 3 exons of the AMH gene appeared particularly prone to mutation, although they are less GC rich than the last 2 exons and code for the N-terminal part of the AMH protein, which is not in itself essential to bioactivity.

Imbeaud et al. (1995) demonstrated a mutation in the gene encoding the AMH receptor (600956.0001) in a 3-month-old boy of Pakistani extraction. The AMH gene was normal by sequencing and the production of normal AMH was demonstrated by the fact that normal regression of fetal rat mullerian ducts was elicited by coculture with a small fragment of testis from the patient.

Imbeaud et al. (1996) reported results of molecular studies on 38 families with PMDS. They identified the basis of the condition, namely 16 AMH and 16 AMHR mutations in 32 families. Six of the patients were postpubertal and, since AMH production is normally repressed in these patients, determination of the level of AMH was no longer informative. In prepubertal patients, the type of genetic defect leading to PMDS could be predicted from the level of serum AMH, which is very low or undetectable in PMDS type I due to AMH mutations and at the upper limit of normal in receptor type II mutations. AMH mutations were extremely diverse. AMH mutations were identified in 16 families, including 9 previously reported families (Imbeaud et al., 1994). Imbeaud et al. (1996) reported that exon 1 and the 3-prime half of exon 5 of AMH are the main sites of deleterious changes including short deletions and missense mutations. AMH receptor mutations leading to type II PMDS were detected in 16 patients and 10 of these patients had a 27-bp deletion in exon 10 on at least one allele (600956.0002). This deletion was thus implicated in 25% of the PMDS patients analyzed by Imbeaud et al. (1996). This deletion was present in the homozygous state in 4 patients and it was coupled with missense mutations in 7 patients.

Lang-Muritano et al. (2001) reported 2 brothers with bilateral cryptorchidism in whom the diagnosis of persistent mullerian duct syndrome was made on the basis of laparoscopic evidence of uterus and tubes, undetectable plasma levels of AMH, and homozygosity for a 23-bp insertion in exon 5 of the AMH gene (600957.0004).


See Also:

Beheshti et al. (1984); Brook et al. (1973); Burgoyne et al. (1988); Picard et al. (1986)

REFERENCES

  1. Armendares, S., Buentello, L., Frenk, S. Two male sibs with uterus and fallopian tubes: a rare probably inherited disorder. Clin. Genet. 4: 291-296, 1973. [PubMed: 4148776] [Full Text: https://doi.org/10.1111/j.1399-0004.1973.tb01160.x]

  2. Beheshti, M., Churchill, B. M., Hardy, B. E., Bailey, J. D., Weksberg, R., Rogan, G. F. Familial persistent mullerian duct syndrome. J. Urol. 131: 968-969, 1984. [PubMed: 6708239] [Full Text: https://doi.org/10.1016/s0022-5347(17)50733-8]

  3. Brook, C. G. D., Wagner, H., Zachmann, M., Prader, A., Armendares, S., Frenk, S., Aleman, P., Najjar, S. S., Slim, M. S., Genton, N., Bozic, C. Familial occurrence of persistent mullerian structures in otherwise normal males. Brit. Med. J. 1: 771-773, 1973. [PubMed: 4144375] [Full Text: https://doi.org/10.1136/bmj.1.5856.771]

  4. Burgoyne, P. S., Buehr, M., Koopman, P., Rossant, J., McLaren, A. Cell-autonomous action of the testis-determining gene: Sertoli cells are exclusively XY in XX-XY chimaeric mouse testes. Development 102: 443-450, 1988. [PubMed: 3166423] [Full Text: https://doi.org/10.1242/dev.102.2.443]

  5. Eichwald, E. J., Silmser, C. R. Skin. Transplant. Bull. 2: 148-149, 1955. [PubMed: 12334405]

  6. Guell-Gonzalez, J. R., Paramino-Ruibal, A., Delgado-Morales, B. Pseudohermafroditismo masculino con genitales interos bisexuales: reporte de 2 hermanos. Rev. Cuba Pediat. 43: 579-586, 1971.

  7. Gustafson, M. L., Lee, M. M., Scully, R. E., Moncure, A. C., Hirakawa, T., Goodman, A., Muntz, H. G., Donahoe, P. K., MacLaughlin, D. T., Fuller, A. F., Jr. Mullerian inhibiting substance as a marker for ovarian sex-cord tumor. New Eng. J. Med. 326: 466-471, 1992. [PubMed: 1732773] [Full Text: https://doi.org/10.1056/NEJM199202133260707]

  8. Harbison, M. D., Magid, M. L. S., Josso, N., Mininberg, D. T., New, M. I. Anti-mullerian hormone in three intersex conditions. Ann. Genet. 34: 226-232, 1991. [PubMed: 1809231]

  9. Imbeaud, S., Belville, C., Messika-Zeitoun, L., Rey, R., di Clemente, N., Josso, N., Picard, J.-Y. A 27 base-pair deletion of the anti-mullerian type II receptor gene is the most common cause of the persistent mullerian duct syndrome. Hum. Molec. Genet. 5: 1269-1277, 1996. [PubMed: 8872466] [Full Text: https://doi.org/10.1093/hmg/5.9.1269]

  10. Imbeaud, S., Carre-Eusebe, D., Rey, R., Belville, C., Josso, N., Picard, J.-Y. Molecular genetics of the persistent mullerian duct syndrome: a study of 19 families. Hum. Molec. Genet. 3: 125-131, 1994. [PubMed: 8162013] [Full Text: https://doi.org/10.1093/hmg/3.1.125]

  11. Imbeaud, S., Faure, E., Lamarre, I., Mattei, M.-G., di Clemente, N., Tizard, R., Carre-Eusebe, D., Belville, C., Tragethon, L., Tonkin, C., Nelson, J., McAuliffe, M., Bidart, J.-M., Lababidi, A., Josso, N., Cate, R. L., Picard, J.-V. Insensitivity to anti-mullerian hormone due to a mutation in the human anti-mullerian hormone receptor. Nature Genet. 11: 382-388, 1995. [PubMed: 7493017] [Full Text: https://doi.org/10.1038/ng1295-382]

  12. Knebelmann, B., Boussin, L., Guerrier, D., Legeai, L., Kahn, A., Josso, N., Picard, J.-Y. Anti-mullerian hormone Bruxelles: a nonsense mutation associated with the persistent mullerian duct syndrome. Proc. Nat. Acad. Sci. 88: 3767-3771, 1991. [PubMed: 2023927] [Full Text: https://doi.org/10.1073/pnas.88.9.3767]

  13. Lang-Muritano, M., Biason-Lauber, A., Gitzelmann, C., Belville, C., Picard, Y., Schoenle, E. J. A novel mutation in the anti-mullerian hormone gene as cause of persistent mullerian duct syndrome. Europ. J. Pediat. 160: 652-654, 2001. [PubMed: 11760020] [Full Text: https://doi.org/10.1007/s004310100840]

  14. Morillo-Cucci, G., German, J. Males with a uterus and fallopian tubes, a rare disorder of sexual development. Birth Defects Orig. Art. Ser. VII(6): 229-231, 1971.

  15. Muller, U., Wachtel, S. S., Jaswaney, V. L., Goldberg, E. H. H-Y (SDM) antibody specifically binds mullerian inhibiting substance. Hum. Genet. 91: 515-518, 1993. [PubMed: 7686131] [Full Text: https://doi.org/10.1007/BF00217786]

  16. Naguib, K. K., Teebi, A. S., Farag, T. I., Al-Awadi, S. A., El-Khalifa, M. Y., Mahfouz, E.-S. Familial uterine hernia syndrome: report of an Arab family with four affected males. Am. J. Med. Genet. 33: 180-181, 1989. [PubMed: 2764027] [Full Text: https://doi.org/10.1002/ajmg.1320330208]

  17. Nilson, O. Hernia uteri inguinalis beins Manne. Acta Chir. Scand. 83: 231-249, 1939.

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Contributors:
Ada Hamosh - updated : 1/30/2002
Moyra Smith - updated : 10/9/1996

Creation Date:
Victor A. McKusick : 6/4/1986

Edit History:
carol : 06/04/2022
carol : 11/12/2013
carol : 11/12/2013
wwang : 7/16/2010
terry : 9/25/2008
terry : 6/2/2004
terry : 1/30/2002
carol : 8/25/2000
carol : 5/24/1999
mark : 10/9/1996
mark : 10/9/1996
carol : 6/28/1996
mark : 12/14/1995
mark : 12/12/1995
terry : 12/4/1995
mark : 8/21/1995
carol : 12/22/1994
mimadm : 3/11/1994
carol : 12/13/1993
carol : 11/10/1993
carol : 4/2/1993



NOTE: OMIM is intended for use primarily by physicians and other professionals concerned with genetic disorders, by genetics researchers, and by advanced students in science and medicine. While the OMIM database is open to the public, users seeking information about a personal medical or genetic condition are urged to consult with a qualified physician for diagnosis and for answers to personal questions.
OMIM® and Online Mendelian Inheritance in Man® are registered trademarks of the Johns Hopkins University.
Copyright® 1966-2024 Johns Hopkins University.

NOTE: OMIM is intended for use primarily by physicians and other professionals concerned with genetic disorders, by genetics researchers, and by advanced students in science and medicine. While the OMIM database is open to the public, users seeking information about a personal medical or genetic condition are urged to consult with a qualified physician for diagnosis and for answers to personal questions.
OMIM® and Online Mendelian Inheritance in Man® are registered trademarks of the Johns Hopkins University.
Copyright® 1966-2024 Johns Hopkins University.
Printed: Nov. 17, 2024