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Author: Catherine Keegan, M.D., Ph.D., 2009 License: Unless otherwise noted, this material is made available under the terms of the Creative Commons Attribution – Non-Commercial 3.0 License: http://creativecommons.org/licenses/by-nc/3.0/ We have reviewed this material in accordance with U.S. Copyright Law and have tried to maximize your ability to use, share, and adapt it. The citation key on the following slide provides information about how you may share and adapt this material. Copyright holders of content included in this material should contact [email protected] with any questions, corrections, or clarification regarding the use of content. For more information about how to cite these materials visit http://open.umich.edu/education/about/terms-of-use. Any medical information in this material is intended to inform and educate and is not a tool for self-diagnosis or a replacement for medical evaluation, advice, diagnosis or treatment by a healthcare professional. 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To use this content you should do your own independent analysis to determine whether or not your use will be Fair. Reproductive Embryology Catherine Keegan, M.D., Ph.D. Spring 2009 M1 Embryology Topics • Bladder and ureter development • Genital development • Cases Objectives • Understand the key events during urogenital development • Understand the origin of major structures that comprise the urogenital system • Understand major differences between male and female gonadal development – Both internal and external genitalia • Be familiar with common disorders of sex development and their genetic basis Division of the cloacal region 5 weeks 6 weeks 8 weeks Controversy over existence of “urorectal septum” Carlson. Human Embryology and Developmental Biology. Elsevier, 2004. 3rd. Ed. The prostate develops as an outgrowth of the urogenital sinus epithelium Larsen. Human Embryology. Philadelphia : Churchill Livingstone/Elsevier, 2009. 4th ed. ed Urogenital sinus: prostate, bulbourethral gland Ureteric bud: ureter Mesonephric duct: seminal vesicle, vas deferens Which of the following structures develops from the urogenital sinus? Vas deferens Seminal vesicle Prostate Appendix testicle The bladder trigone develops from which of the following structures? Mullerian ducts Mesonephric ducts Urogenital sinus Ureteric buds Langman. Medical Embriology. Lippincott, 2004. 9th ed. Mesonephric ducts fuse with urogenital sinus and migrate caudally to form the trigone Common excretory duct = name for mesonephric duct distal to ureteric bud Developmental abnormalities of the urogenital sinus Carlson. Human Embryology and Developmental Biology. Elsevier, 2004. 3rd. Ed. Gonadal Development • Sexual determination – Genetic events that bring about male or female gonadal development • Sexual differentiation – All subsequent morphogenetic and physiologic events that establish functional sexuality, sexual dimorphism, and secondary sex characteristics The first 7 weeks of gestation is the indifferent stage Larsen. Human Embryology. Philadelphia : Churchill Livingstone/Elsevier, 2009. 4th ed. ed Source Undetermined Migration of primordial germ cells to urogenital ridges Larsen. Human Embryology. Philadelphia : Churchill Livingstone/Elsevier, 2009. 4th ed. ed Indifferent stage Mesonephric duct = Wollfian duct Paramesonephric duct = Mullerian duct Sexual Determination No MIS No Testosterone Sertoli cells Leydig cells Sexual Differentiation Carlson. Human Embryology and Developmental Biology. Elsevier, 2004. 3rd. Ed. Carlson. Human Embryology and Developmental Biology. Elsevier, 2004. 3rd. Ed. Paramesonephric duct remnants in males Mesonephric duct remnants in females Appendix testis Paroophoron Prostatic utricle Gartner’s cyst Epoophoron Larsen. Human Embryology. Philadelphia : Churchill Livingstone/Elsevier, 2009. 4th ed. ed Formation of uterus and vagina Langman. Medical Embriology. Lippincott, 2004. 9th ed. Paramesonephric (Mullerian) ducts fuse to form uterus and upper 1/3 of vagina In the presence of a structurally normal Y chromosome, the following structures would be expected to develop: • • • • Mullerian derivatives Ovaries Wolffian derivatives Uterus, cervix and upper 1/3 of the vagina Virilization of male genitalia Carlson. Human Embryology and Developmental Biology. Elsevier, 2004. 3rd. Ed. Effects of Testosterone and DHT mediated by Androgen Receptors Male virilization Blue = DHT Brown = Testosterone Carlson. Human Embryology and Developmental Biology. Elsevier, 2004. 3rd. Ed. Formation of external genitalia Carlson. Human Embryology and Developmental Biology. Elsevier, 2004. 3rd. Ed. Formation of the urethra Carlson. Human Embryology and Developmental Biology. Elsevier, 2004. 3rd. Ed. Hypospadias Carlson. Human Embryology and Developmental Biology. Elsevier, 2004. 3rd. Ed. meatus Normal midline raphe Raphe off center J. Park J. Park Developmental anomalies of the uterus Carlson. Human Embryology and Developmental Biology. Elsevier, 2004. 3rd. Ed. Testicular descent 3rd month 2nd month Requires Insl3 term 7th month Carlson. Human Embryology and Developmental Biology. Elsevier, 2004. 3rd. Ed. The testicles descend to the level of internal inguinal ring by which time point during gestation? Sixth week Third month Sixth month Ninth month Disorders of Sex Development: Terminology • Sex reversal (Determination) – 46, XX males – 46, XY females – Complete gonadal dysgenesis • Ambiguous genitalia (Differentiation) – Partial gonadal dysgenesis – True hermaphrodites • Both testicular and ovarian tissue – Pseudohermaphrodites • Phenotype of external genitalia is inconsistent with gonadal sex • Gene-based approach • DSD consensus statement SRY Source Undetermined • Primary sex determining gene on Y chromosome – Located near pseudoautosomal region • Transcription factor – DNA-binding and DNA-bending HMG box – Thought to activate SOX9 expression • Translocation of SRY causes 46 XX males and 46 XY females – 80% of XX males are SRY positive • 15% of patients with complete gonadal dysgenesis have SRY mutations – Most in HMG box SRY translocation Pairing of X and Y chromosomes in pseudoautosomal region during meiosis Rare crossing over causes translocation of SRY to X chromosome: XY females or XX males Source Undetermined SOX9 Source Undetermined • SRY-related protein – SRY-box = SOX – Multiple family members • Strongly expressed in male gonads, expression downregulated in females • Activates male specific genes (MIS) • Human mutations in SOX9 cause campomelic dysplasia – XY sex reversal and skeletal dysplasia Which of the following is not true of the SRY (the Sex-determining Region of the Ychromosome) gene? It is a transcription factor that activates malespecific gene expression. A translocation of the SRY gene to the X chromosome during paternal meiosis or a mutation in the SRY gene are both mechanisms that can lead to complete male-to-female sex reversal (46, XY female). It is located on the short arm of the Y chromosome near the pseudoautosomal region. It causes regression of the mesonephric (Wolffian) ducts. Genes that regulate Sexual Differentiation • • • • Androgen receptor (AR) MIS/MIS-receptor 5 a-reductase Steroidogenic enzymes – P450c21 (21-hydroxylase) – Congenital adrenal hyperplasia • Adrenal insufficiency • Virilization of female fetus Androgen Receptor • Nuclear hormone receptor modulates effects of androgens • Mutations cause Complete or Partial Androgen Insensitivity Syndrome • XY sex reversal with female external genitalia and normal testes • Normal production of MIS causes Mullerian duct regression • Lack of virilization due to inability of AR to bind testosterone 5 a-reductase deficiency • Enzyme required to convert Testosterone to Dihydrotestosterone • Elevated Testosterone:DHT ratio • DHT is more potent—higher affinity for AR • Deficiency causes ambiguous genitalia in males • Lack of virilization of male fetus • Normal production of MIS causes regression of Mullerian structures Congenital adrenal hyperplasia J. Park • Enzymatic defect in steroidogenesis • Autosomal recessive • Virilization of female fetus due to production of androgenic hormones • Testes absent • Normal Mullerian structures internally • These patients can present with life threatening adrenal crisis and salt wasting! Persistent Müllerian Duct syndrome • • • • • Normal male genitalia Presence of uterus and fallopian tubes Usually undergo virilization at puberty Mutation in MIS (50%) Mutation in MIS-receptor (50%) A patient with a mutation in the Androgen Receptor gene causing complete loss of function would be expected to have which of the following: • • • • Testicles Cervix Fallopian tubes Completely virilized male external genitalia This patient with 5-alpha-reductase deficiency has the following features except: Seminal vesicle Vas deferens Fallopian tubes Testicles J. Park Severe perineal hypospadias This patient with 5-alpha-reductase deficiency has the following features except: Severe perineal hypospadias Seminal vesicle Vas deferens Fallopian tubes Testicles J. Park Derived under the influence of testosterone Testicles produce MIS causing regression of Mullerian duct structures Developmental Sex Disorders • Nomenclature – Moving away from terms such as “intersex” and “hermaphrodite” – DSD • Congenital conditions in which development of chromosomal, gonadal, or anatomic sex is atypical – 46, XY DSD • Gonadal dysgenesis (SRY mutations) • AIS (partial or complete) • Androgen synthesis defects (5-alpha reductase def.) – 46, XX DSD • Androgen excess (most common 21-hydroxylase CAH) – Sex chromosome DSD • Turner, Klinefelter, mosaic karyotypes DSD counseling • • • • Multidisciplinary Care Team Gender assignment What to say to the parents To operate or not to operate? – Is surgery cosmetic? – Risk of malignancy depends on diagnosis • Psychosocial care – Gender identity – Gender role – Sexual orientation • Disclosure – To other family members – To the child • Support Groups DSD counseling • Gender assignment must be avoided before expert evaluation in newborns • Evaluation and long-term management must be performed at a center with an experienced multidisciplinary team • All individuals should receive a gender assignment • Open communication with patients and families is essential; encourage participation in decisionmaking • Patient and family concerns should be respected and addressed in strict confidence Cases Patient #1 • Prenatal ultrasound: – Oligohydramnios – Cardiac abnormality--heart felt to be enlarged – Fetus thought to be female • IUGR, neonatal hypoglycemia and thrombocytopenia that resolved • No cardiac abnormality found postnatally • Ambiguous genitalia: – – – – Bifid scrotum with palpable gonads Small phallic structure with urethral opening at base No uterus, no cervix Endocrine work-up: Normal testosterone, DHT, normal 17-OHP • Family history noncontributory Questions • Based on the findings, what would you expect the karyotype to be? • What tentative diagnosis would fit these features? • What gender would you assign to this baby? Patient #2 • Ambiguous genitalia noted at birth – Prenatal ultrasound female gender • No other medical problems • Family history noncontributory • Primarily female phenotype – – – – Enlarged labia majora with palpable gonads Clitoral tissue Vaginal opening visualized Absent uterus by ultrasound • Endocrine work-up: – Normal 17-hydroxyprogesterone – Normal testosterone and T:DHT ratio – MIS in normal range for male Questions • Based on the findings, what would you expect the karyotype to be? • What tentative diagnosis would fit these features? • What gender would you assign to this baby? Patient #3 • 16 year old woman with primary amenorrhea • Some breast and pubic hair development • Pelvic ultrasound: – Small uterus (prepubertal), left ovary not identified, right ovary “normal” • Pelvic MRI: – Similar findings, but slightly enlarged right ovary relative to size of uterus • Karyotype 46, XY “SRY+” • Medical history otherwise unremarkable • Family history noncontributory. Younger sister began menses at age 13 Questions • What additional work-up would you perform? • Is there anything concerning about her history or physical exam findings? Additional Source Information for more information see: http://open.umich.edu/wiki/CitationPolicy Slide 6: Carlson. Human Embryology and Developmental Biology. Elsevier, 2004. 3rd. Ed. Slide 7: Larsen. Human Embryology. Philadelphia : Churchill Livingstone/Elsevier, 2009. 4th ed. Ed Slide 9: Langman. Medical Embriology. Lippincott, 2004. 9th ed. Slide 10: Carlson. Human Embryology and Developmental Biology. Elsevier, 2004. 3rd. Ed. Slide 12: Larsen. Human Embryology. Philadelphia : Churchill Livingstone/Elsevier, 2009. 4th ed. Ed Slide 13: Source Undetermined; Larsen. Human Embryology. Philadelphia : Churchill Livingstone/Elsevier, 2009. 4th ed. Ed Slide 14: Carlson. Human Embryology and Developmental Biology. Elsevier, 2004. 3rd. Ed. Slide 15: Carlson. Human Embryology and Developmental Biology. Elsevier, 2004. 3rd. Ed. Slide 16: Larsen. Human Embryology. Philadelphia : Churchill Livingstone/Elsevier, 2009. 4th ed. Ed Slide 17: Langman. Medical Embriology. Lippincott, 2004. 9th ed. Slide 19: Carlson. Human Embryology and Developmental Biology. Elsevier, 2004. 3rd. Ed. Slide 20: Carlson. Human Embryology and Developmental Biology. Elsevier, 2004. 3rd. Ed. Slide 21: Carlson. Human Embryology and Developmental Biology. Elsevier, 2004. 3rd. Ed. Slide 22: Carlson. Human Embryology and Developmental Biology. Elsevier, 2004. 3rd. Ed. Slide 23: Carlson. Human Embryology and Developmental Biology. Elsevier, 2004. 3rd. Ed.; John Park (Both images) Slide 24: Carlson. Human Embryology and Developmental Biology. Elsevier, 2004. 3rd. Ed. Slide 25: Carlson. Human Embryology and Developmental Biology. Elsevier, 2004. 3rd. Ed. Slide 28: Source Undetermined Slide 29: Source Undetermined Slide 30: Source Undetermined Slide 35: John Park Slide 38: John Park Slide 39: John Park