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Development of Reproductive Anatomy

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Presentation on theme: "Development of Reproductive Anatomy"— Presentation transcript:

1 Development of Reproductive Anatomy
Development of sex organs: overview All the same, until week 7 – then differentiation The internal genitalia The external genitalia Problems Oogenesis

2 Development of sex organs: overview
Sex determination occurs first in the gonads and is followed by appropriate development of the ducts, glands and associated genitalia. In the absence of testis-determining genes, the gonadal primordium develops as an ovary

3 I. All the same, until week 7
Sexually indifferent stage: By 6-7 weeks of fetal life, fetuses of both sexes have two sets of internal ducts, the Mullerian (female) ducts and the Wolffian (male) ducts. Gonad differentiation: female – ovaries

4 Mammalian gonad forms within the developing urogenital system, which itself derives from the intermediate mesoderm. Epithelial structures are shown in red, mesenchymal structures are shown in blue, and the striped region denotes the genital ridge. (WD) Wolffian duct; (MT) mesonephric tubules; (MD) Mullerian duct; (UB) ureteric bud; (CE) coelomic epithelia.

5 A. Development of the internal structures
Gonadal ridge (masses of mesoderm) form buldges on the dorsal abdominal wall just medial to the mesonephros

6 2). Primordial germ cells become associated with finger-like processes produced by proliferation of the mesothelium, the primary sex cords. 3) Further development of the primary sex cords results in differentiation of an outer cortex and inner medulla. The medulla disappears in females and the cortex develops into the ovary.

7 4) The paramesonephric ducts differentiate into
The mesonephric ducts degenerate. The paramesonephric ducts come together in the median plane and fuse into the uterovaginal primordium. The dilated free ends of the tubes open into what will eventually be the peritoneal cavity. The uterovaginal primordium invaginates the dorsal surface of the urogenital sinus to become the epithelium and glands of the uterus. The fallopian tubes form from the unfused portions of the paramesonephric ducts.

8 B. The external genitalia
The external genitalia arise from the same structures in both sexes –

9 At 8 weeks the external structures appear
include a genital tubercle, the genital folds, urethral folds and a Genital tubercle gives rise to the clitoris and the urethral groove persists as the vestibule. The unfused utrethral folds become the labia minora.

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12 Development review two products of the developing testes are needed for normal male development. In the female, absence of androgens permits the external genitalia to remain feminine

13 C. Hormonal imbalance results in variation:
Any interference with the normal pattern of sex hormone production in the embryo If testes do not produce testosterone – XY If testes do not produce AMH, both female and male duct systems form, but the external genitalia are male If XX is exposed to testosterone –

14 Psuedohermaphroditism
Androgen insensitivity syndrome (AIS) If the testes form only partially and the production of androgen and Mullerian inhibitor is incomplete, there will be only partial masculinization of the external genitalia as well as incomplete inhibition of development of the vagina, uterus and Fallopian tubes. If the testes form normally but are enzymatically incapable of completion of testosterone metabolism, there will be failure of complete masculinization of the external structures. However, the inhibition of Mullerian ducts will be normal because of normal production of Mullerian inhibitor, and therefore the upper vagina, uterus and Fallopian tubes may be absent. Congenital adrenal hyperplasia The androgen from the adrenal causes masculinization of the external genitalia, but since there is no Mullerian inhibitor, a normal uterus and vagina will develop

15 Psuedohermaphrodites – individuals with accessory reproductive structures that do not “match” their gonads True hermaphrodites – rare, possess both ovaries and testicular tissue

16 CAH AIS

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19 Genetic imbalance due to nondisjunction
Sex-chromosome differences more frequent than autosomal abnormalities: X inactivation Y contains few functional genes XO – Turner syndrome (female) YO XXX – Trisomy X (female) XXXX XXY – Klinefelter syndrome (male) XYY – Double Y (male)

20 Klinefelter Syndrome Turner Syndrome

21 Production of haploid gametes is essential for sexual reproduction

22 III. Oogenesis A. Differentiation of the ovum
Forms a gamete that contains all the factors needed to initiate and maintain metabolism and development (as compared to simple sperm) Haploid nucleus Cytoplasmic enzymes mRNAs organelles metabolic substrates gametes develop from primordial germ cells that migrate to the somatic gonadal precursors (genital ridges in mammals) same for drosophila, xenopus & zebrafish once the gonad is assembled, germ cells begin active proliferation and become gonial cells.

23 B. Follicle formation In all species except C. elegans, gonadal somatic cells envelop female germ cells to create a follicle Primordial Germ cells destined to become oocytes have already entered meiosis at the time of follicle formation and within the follicle they reach the diplotene stage of PI – here they halt meiosis for a few days to many years, depending on the species Mechanisms of oogenesis differ among taxa because reproduction patterns also vary

24 Synchronous development leads to "cohorts" of eggs which are in the same stage of development, which reach maturity at the same time, and which are spent all at once. Hence, synchroneous gonad development is a cyclical affair: The gonad grows in size and mass during the ripening of the eggs until a distinct spawning event occurs which sets the gonad back to the initial conditions of the cycle In the gonads of species with asynchronous development we will not find "cohorts" of eggs being in the same stage of development, but there are eggs of any develop-mental stage at any time. These species show no distinct spawning times, but more or less continuous spawning all year round.

25 1). In Drosophila, asymmetric cell division gives rise to the oocyte
Cystoblast undergoes 4 mitotic divisions to give rise to a cyst of 16 germline cells

26 2). Oogenesis in Vertebrates
Cyst phase is confined to early ovarian development and cells in an individual cyst do not differentiate as nurse cells

27 Egg asymmetry it is during oogenesis that the animal-vegetal axis of the egg is specified. as a result of differential intracellular transport, the amount of yolk steadily increases in the vegetal hemisphere

28 Oogenesis in Xenopus Iaevis
Oogonia are found as nests of 16 pearl shaped cells that develop synchronously

29 Growth of oocytes in the frog
Growth of oocytes in the frog. During the first 3 years of life, three cohorts of oocytes are produced. The drawings follow the growth of the first-generation oocytes.

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33 The large cell in the picture above is either the product of the first or second meiotic division that lives. 

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36 Follicular growth stage & antrum formation
Ooctye undergoes increase in # of follicular granulosa cells Cavity forms (antrum) which fills with proteins, hormones & additional molecules Follicle cells secrete growth & differentiation factors

37 The ovarian follicle of mammals. (A) Maturation of the ovarian follicle. When mature, it is often called a Graafian follicle. (B) Scanning electron micrograph of a mature follicle in the rat.

38 Ovulation in the rabbit.


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