Human fertilization

The acrosome reaction for a sea urchin, a similar process. Note that the picture shows several stages of one and the same spermatozoon - only one penetrates the ovum
Illustration depicting ovulation and fertilization.

Human fertilization is the union of a human egg and sperm, usually occurring in the ampulla of the fallopian tube. The result of this union is the production of a zygote cell, or fertilized egg, initiating prenatal development. Scientists discovered the dynamics of human fertilization in the nineteenth century.[1]

The process of fertilization involves a sperm fusing with an ovum. The most common sequence begins with ejaculation during copulation, follows with ovulation, and finishes with fertilization. Various exceptions to this sequence are possible, including artificial insemination, in vitro fertilization, external ejaculation without copulation, or copulation shortly after ovulation.[2][3][4] Upon encountering the secondary oocyte, the acrosome of the sperm produces enzymes which allow it to burrow through the outer jelly coat of the egg. The sperm plasma then fuses with the egg's plasma membrane, the sperm head disconnects from its flagellum and the egg travels down the Fallopian tube to reach the uterus.

In vitro fertilization (IVF) is a process by which egg cells are fertilized by sperm outside the womb, in vitro.

Anatomy

Corona radiata

The sperm binds through the corona radiata, a layer of follicle cells on the outside of the secondary oocyte. Fertilization occurs when the nucleus of both a sperm and an egg fuse to form a diploid cell, known as zygote. The successful fusion of gametes forms a new organism.

Cone of attraction and perivitelline membrane

Where the spermatozoon is about to pierce, the yolk (ooplasm) is drawn out into a conical elevation, termed the cone of attraction or reception cone. Once the spermatozoon has entered, the peripheral portion of the yolk changes into a membrane, the perivitelline membrane, which prevents the passage of additional spermatozoa.[5]

Sperm preparation

Further information: Acrosome reaction

At the beginning of the process, the sperm undergoes a series of changes, as freshly ejaculated sperm is unable or poorly able to fertilize.[6] The sperm must undergo capacitation in the female's reproductive tract over several hours, which increases its motility and destabilizes its membrane, preparing it for the acrosome reaction, the enzymatic penetration of the egg's tough membrane, the zona pellucida, which surrounds the oocyte.

Zona pellucida

After binding to the corona radiata the sperm reaches the zona pellucida, which is an extra-cellular matrix of glycoproteins. A special complementary molecule on the surface of the sperm head binds to a ZP3 glycoprotein in the zona pellucida. This binding triggers the acrosome to burst, releasing enzymes that help the sperm get through the zona pellucida.

Some sperm cells consume their acrosome prematurely on the surface of the egg cell, facilitating the penetration by other sperm cells. As a population, sperm cells have on average 50% genome similarity so the premature acrosomal reactions aid fertilization by a member of the same cohort.[7] It may be regarded as a mechanism of kin selection.

Recent studies have shown that the egg is not passive during this process.[8][9]

Cortical reaction

Once the sperm cells find their way past the zona pellucida, the cortical reaction occurs. Cortical granules inside the secondary oocyte fuse with the plasma membrane of the cell, causing enzymes inside these granules to be expelled by exocytosis to the zona pellucida. This in turn causes the glyco-proteins in the zona pellucida to cross-link with each other — i.e. the enzymes cause the ZP2 to hydrolyse into ZP2f — making the whole matrix hard and impermeable to sperm. This prevents fertilization of an egg by more than one sperm. The cortical reaction and acrosome reaction are both essential to ensure that only one sperm will fertilize an egg.[10]

Fusion

Fertilization and implantation in humans.

After the sperm enters the cytoplasm of the oocyte (also called ovocyte), the tail and the outer coating of the sperm disintegrate and the cortical reaction takes place, preventing other sperm from fertilizing the same egg. The oocyte now undergoes its second meiotic division producing the haploid ovum and releasing a polar body. The sperm nucleus then fuses with the ovum, enabling fusion of their genetic material.

Cell membranes

The cell membranes of the secondary oocyte and sperm fuse.

Transformations

In preparation for the fusion of their genetic material both the oocyte and the sperm undergo transformations as a reaction to the fusion of cell membranes.

The oocyte completes its second meiotic division. This results in a mature ovum. The nucleus of the oocyte is called a pronucleus in this process, to distinguish it from the nuclei that are the result of fertilization.

The sperm's tail and mitochondria degenerate with the formation of the male pronucleus. This is why all mitochondria in humans are of maternal origin. Still, a considerable amount of RNA from the sperm is delivered to the resulting embryo and likely influences embryo development and the phenotype of the offspring.[11]

Replication

The pronuclei migrate toward the center of the oocyte, rapidly replicating their DNA as they do so to prepare the zygote for its first mitotic division.[12]

Mitosis

Usually 23 chromosomes from spermatozoon and 23 chromosomes from egg cell fuse (half of spermatozoons carry X chromosome and the other half Y chromosome[13]). Their membranes dissolve, leaving no barriers between the male and female chromosomes. During this dissolution, a mitotic spindle forms between them. The spindle captures the chromosomes before they disperse in the egg cytoplasm. Upon subsequently undergoing mitosis (which includes pulling of chromatids towards centrioles in anaphase) the cell gathers genetic material from the male and female together. Thus, the first mitosis of the union of sperm and oocyte is the actual fusion of their chromosomes.[12] During this process also crossing-over occurs.[14]

Each of the two daughter cells resulting from that mitosis has one replica of each chromatid that was replicated in the previous stage. Thus, they are genetically identical.

Fertilization age

Fertilization is the event most commonly used to mark the zero point in descriptions of prenatal development of the embryo or fetus. The resultant age is known as fertilization age, fertilizational age, embryonic age, fetal age or (intrauterine) developmental (IUD)[15] age.

Gestational age, in contrast, takes the beginning of the last menstrual period (LMP) as the zero point. By convention, gestational age is calculated by adding 14 days to fertilization age and vice versa.[16] In fact, however, fertilization usually occurs within a day of ovulation, which, in turn, occurs on average 14.6 days after the beginning of the preceding menstruation (LMP).[17] There is also considerable variability in this interval, with a 95% prediction interval of the ovulation of 9 to 20 days after menstruation even for an average woman who has a mean LMP-to-ovulation time of 14.6.[18] In a reference group representing all women, the 95% prediction interval of the LMP-to-ovulation is 8.2 to 20.5 days.[17]

Fertilization age is sometimes used postnatally (after birth) as well to estimate various risk factors. For example, it is a better predictor than postnatal age for risk of intraventricular hemorrhage in premature babies treated with extracorporeal membrane oxygenation.[19]

Diseases

Various disorders can arise from defects in the fertilization process.

However, some researchers have found that in rare pairs of fraternal twins, their origin might have been from the fertilization of one egg cell from the mother and eight sperm cells from the father. This possibility has been investigated by computer simulations of the fertilization process.

See also

References

  1. Garrison, Fielding. An Introduction to the History of Medicine, pages 566-567 (Saunders 1921).
  2. http://www.goaskalice.columbia.edu/0116.html
  3. http://www.americanpregnancy.org/preventingpregnancy/pregnancyfaqmyths.html
  4. Lawyers Guide to Forensic Medicine SBN 978-1-85941-159-9 By Bernard Knight - Page 188 "Pregnancy is well known to occur from such external ejaculation ..."
  5. "Fertilization of the Ovum". Gray's Anatomy. Retrieved 2010-10-16.
  6. "Fertilization". Retrieved 28 July 2010.
  7. Angier, Natalie (2007-06-12). "Sleek, Fast and Focused: The Cells That Make Dad Dad". The New York Times.
  8. Suzanne Wymelenberg, Science and Babies, National Academy Press, page 17
  9. Richard E. Jones and Kristin H. Lopez, Human Reproductive Biology, Third Edition, Elsevier, 2006, page 238
  10. "Fertilization: The Cortical Reaction". Boundless. Boundless. Retrieved 14 March 2013.
  11. Jodar, M.; Selvaraju, S.; Sendler, E.; Diamond, M. P.; Krawetz, S. A.; for the Reproductive Medicine Networks (2013). "The presence, role and clinical use of spermatozoal RNAs". Human Reproduction Update. 19 (6): 604–624. doi:10.1093/humupd/dmt031. PMC 3796946Freely accessible. PMID 23856356.
  12. 1 2 Marieb, Elaine M. Human Anatomy and Physiology, 5th ed. pp. 1119-1122 (2001). ISBN 0-8053-4989-8
  13. https://www.genderselectionauthority.com/blog/five-facts-about-xx-or-xy
  14. http://www.cccbiotechnology.com/RC/AB/BC/Genetic_Recombination.php
  15. Wagner F, Erdösová B, Kylarová D (December 2004). "Degradation phase of apoptosis during the early stages of human metanephros development". Biomed Pap Med Fac Univ Palacky Olomouc Czech Repub. 148 (2): 255–6. doi:10.5507/bp.2004.054. PMID 15744391.
  16. Robinson, H. P.; Fleming, J. E. E. (1975). "A Critical Evaluation of Sonar "crown-Rump Length" Measurements". BJOG: an International Journal of Obstetrics and Gynaecology. 82 (9): 702–710. doi:10.1111/j.1471-0528.1975.tb00710.x.
  17. 1 2 Geirsson RT (May 1991). "Ultrasound instead of last menstrual period as the basis of gestational age assignment". Ultrasound Obstet Gynecol. 1 (3): 212–9. doi:10.1046/j.1469-0705.1991.01030212.x. PMID 12797075.
  18. Derived from a standard deviation in this interval of 2.6, as given in: Fehring RJ, Schneider M, Raviele K (2006). "Variability in the phases of the menstrual cycle". J Obstet Gynecol Neonatal Nurs. 35 (3): 376–84. doi:10.1111/j.1552-6909.2006.00051.x. PMID 16700687.
  19. Alan H. Jobe, MD, PhD. Post-fertilizational age and IVH in ECMO patients. RadiologySource Volume 145, Issue 2, Page A2 (August 2004). PII: S0022-3476(04)00583-9. doi:10.1016/j.jpeds.2004.07.010.

External links

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