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Genital Ducts (genital + duct)

Distribution by Scientific Domains
Life Sciences75%

Selected Abstracts

Mating of Xenos vesparum (Rossi) (Strepsiptera, Insecta) revisited

JOURNAL OF MORPHOLOGY, Issue 3 2005
L. Beani
Abstract The controversial mating of the strepsipteran Xenos vesparum was studied to investigate the possible sperm routes for fertilization. The female, which is a neotenic permanent endoparasite of Polistes wasps, extrudes only its anterior region, the "cephalothorax," from the host abdomen. This region has an opening where both mating and larval escape occur. Observations with scanning and transmission electron microscopy revealed spermatozoa not only in the hemocoel, but also in the "ventral canal" (an extragenital duct peculiar to strepsipteran females) and in the "genital ducts" (ectodermal invaginations connecting the ventral canal to the hemocoel) of recently mated females. Xenos vesparum spermatozoa can reach the oocytes either through the hemocoel as a result of a hypodermic insemination, or by moving along the extragenital ducts, which are later used by first instar larvae to escape. The hypothesis of hypodermic insemination is reconsidered in the light of behavioral and ultrastructural evidence. J. Morphol. © 2005 Wiley-Liss, Inc. [source]

Development of the genital ducts and external genitalia in the early human embryo

JOURNAL OF OBSTETRICS AND GYNAECOLOGY RESEARCH (ELECTRONIC), Issue 5 2010
Yasmin Sajjad
Abstract The course of development of the human genital tract is undifferentiated to the 9th week of development. At this time two symmetrical paired ducts known as the mesonephric (MD) and paramesonephric ducts (PMD) are present, which together with the urogenital sinus provide the tissue sources for internal and external genital development. Normal differentiation of the bipotential external genitalia and reproductive ducts are dependent upon the presence or absence of certain hormones. Masculinization of the internal and external genitalia during fetal development depends on the existence of two discrete testicular hormones. Testosterone secreted from Leydig cells induces the differentiation of the mesonephric ducts into the epididymis, vasa deferentia and seminal vesicles, whereas anti-Müllerian hormone (AMH) produced by Sertoli cells induces the regression of the paramesonephric ducts. The absence of AMH action in early fetal life results in the formation of the fallopian tubes, uterus and upper third of the vagina. In some target tissues, testosterone is converted to dihydrotestosterone, which is responsible for the masculinization of the urogenital sinus and external genitalia. [source]

Expression and Distribution of Intermediate-filament Proteins and Laminin during the Development of the Bovine Müllerian Duct

ANATOMIA, HISTOLOGIA, EMBRYOLOGIA, Issue 3 2008
R. A.-M.
Summary The expression pattern of several intermediate-filament proteins (vimentin, cytokeratin 8, 18 and19) and the basal lamina component laminin was investigated in the Wolffian and the Müllerian ducts of bovine embryos and fetuses. The material studied comprised sexually undifferentiated stages [crown-rump length (CRL) 0.9 cm/1.0 cm/1.2 cm/1.9 cm/2.5 cm] and female stages (CRL 3.0 cm/4.2 cm/5.1 cm). Laminin could be demonstrated in the basal lamina of the developing Wolffian and Müllerian duct as well as in the stroma surrounding the Müllerian duct. The intermediate-filament protein vimentin was expressed in the mesothelium of the funnel field and in the epithelium of the Müllerian duct in all studied specimens, whereas the epithelial cells of the Wolffian duct only showed vimentin expression from a CRL of 2.2 cm onwards. In the cranial part of the Müllerian ducts only a few cells stained with pan-cytokeratin antibodies, whereas mesothelium and epithelium of the Wolffian duct showed as distinct immunostaining in all investigated stages. Both genital ducts showed no immunostaining with the antibody against cytokeratin 19 at any time of development. We conclude from our immunohistochemical results that the epithelial cells of the Wollfian duct do not contribute cells to the developing Müllerian duct. [source]

The Biology of the Development of the Genital Organs.

ANATOMIA, HISTOLOGIA, EMBRYOLOGIA, Issue 2005
A Multimedia Teaching Program
In my presentation, I review the sexual differentiation from the genetic sex until the appearance of the external genitalia and the developmental anomalies to use an animated cartoon. The first critical stage of sexual differentiation occurs at the moment of fertilization, when the genetic sex of the zygote is determined by the nature of the sex chromosome contributed by the sperm. Although an XY zygote is destined to become a male, no distinctive differences between the early development of male and female embryos have been noted. This is accomplished after migration of the primordial germ cell into the early gonad. Because of the early commonality of genital structures, anomalies are the result of abnormal retention or loss of appropriate genital structures. Therefore, most genital anomalies are some form of intersex. During the early differentiation of the gonads, while the mesonephros is still the dominant excretory organ, the gonads arise as ridge like thickenings (gonadal ridge) on its ventromedial face. Differentiation of the indifferent gonads into ovaries or testes occurs after the arrival of the primordial germ cells. The primordial germ cells arise from the endodermal cells of the yolk. The principal function of the Y chromosome is to direct the differentiation of the presented indifferent gonad into a testis from the sixth week, while two X chromosome are presented the ovaries start to develop, from the 12th week. The next and most obvious phase in sexual differentiation of the embryo is the differentiation of the somatic sex. The early embryo develops a dual set of potential genital ducts, one is the original mesonephric (Wolff ) ducts, which persists after degeneration of the mesonephros as an excretory organ, and the another is newly formed pair of ducts called the paramesonephric (Müllerian) ducts. Under the influence of testosterone secreted by the testes, the mesonephric ducts develop into the duct system through which the spermatozoa are conveyed from the testes to the urethra. The potentially female paramesonephric ducts regress under the influence of another product of the embryonic testes, the Müllerian inhibitory factor, a glycoprotein secreted by the Sertoli cells. In genetically female embryos, neither testosterone nor Müllerian inhibitory factor are secreted by the gonads. In the absence of testosterone the mesonephric ducts regress and lack of Müllerian inhibitory factor permits the paramesonephric ducts to develop into oviducts, the uterus and part of the vagina. The next stage is the development of the external genitalia. In very young embryos, a vaguely outlined elevation known as the genital eminence can be seen in the midline, just cephalic to the proctodeal depression. This is soon differentiated into a central prominence (genital tubercle) closely flanked by a pair of folds (genital folds) extending toward the proctodeum. Somewhat farther to either side are rounded elevation known as the genital swellings. From this common starting point the external genitalia of both sex differentiate. If the individual is to develop into a male the genital tubercle, under the influence of dihydrotestosterone, becomes greatly elongated to form the penis and the genital swellings become enlarged to form the scrotal pouches. During the growth of the penis a groove develops along the entire length of its caudal face and is continuous with the slit-like opening of the urogenital sinus. This groove later becomes closed over by a ventral fusion of the genital folds, establishing the penile portion of the urethra. The portion of the urogenital sinus between the neck of the bladder and the original opening of the urogenital sinus becomes the prostetic urethra. In the female, the genital tubercle becomes the clitoris, the genital folds become the labia minora, and the genital swellings become the labia majora. The urethra in the female is derived from the urogenital sinus, being homologous with the prostatic portion of the male urethra. [source]