Introduction Developmental Periods Divided into: A: Prenatal B: Postnatal A: Prenatal terminology Oocyte: ovum produced by the ovary. When mature called 2dry oocyte or mature oocyte. Sperm: male germ cell produced by the testis Zygote: Result of union between the oocyte and sperm during fertilization Cleavage: Series of divisons taht occur in the zygote resulting in formation of balastomeres Morula: Solid mass of blastomeres Blastocyst: appearnce of a fluid filled cavity in the morula changes it into blasytocyst Implantation: the processof entering of the zygote into the endometrium of the utrus Gastrula: The appearance of three germinal layers in the blastocyst Primordium: The first trace of an organ or stucture (beginning of first indication). Embryo: The concepetus betwee 3-8 weeks of gestation Fetus: Conception between 9 weeks to birth
Abortion (Miscarriage): Premature expulsion of the concepetus from the uterus before it is viable ie before 20 weeks. After that it is called pemature birth. Types of abortion: Threatened, accidental, spontaneous, habitual (expulsion of non viable embryo in in three or more cosecutive pregnancies), complete, criminal (illegal), induced ( either elective or therapeutic). Trimester: One third length of pregnancy B: Postnatal period Infancy: first year of age : less than one month is called neonate or newborn Childhood: From 13 months to puberty Puberty: Occurs between years in males and years in females Adolescence: years; from the appearance of pubertal development until attainment of physical, mental and emotional maturity. Adulthood: Attainment of full maturity years.
Abbreviation Description State A resting phase where the cell has left the cycle and has stopped dividing. G0 Gap 0 Quiescent Cells increase in size in Gap 1. The G1 checkpoint control mechanism ensures that everything is ready for DNA synthesis. G1Gap 1 INTER DNA replication occurs during this phase S Synthesis PH During the gap between DNA synthesis and mitosis, the cell will continue to grow. The G2 checkpoint control mechanism ensures that everything is ready to enter the M (mitosis) phase and divide G2 Gap2 ASE Cell growth stops at this stage and cellular energy is focused on the orderly division into two daughter cells. A checkpoint in the middle of mitosis (Metaphase Checkpoint) ensures that the cell is ready to complete cell division. M Mitosis Cell division
Primordial Germ Cells Development begins with fertilization, the process by which the male gamete, the sperm, and the female gamete, the oocyte, unite to give rise to a zygote. Gametes are derived from primordial germ cells (PGCs) that are formed in the epiblast during the second week and that move to the wall of the yolk sac. During the fourth week these cells begin to migrate from the yolk sac toward the developing gonads, where they arrive by the end of the fifth week. Mitotic divisions increase their number during their migration and also when they arrive in the gonad. In preparation for fertilization, germ cells undergo gametogenesis, which includes meiosis, to reduce the number of chromosomes and cytodifferentiation to complete their maturation
Mitosis Before mitosis cells replicate their DNA. With onset of mitosis the chromosomes start to coil, condense and contract- Prophase. Chromosomes formed of parallel subunits- chromatids- joined at the centromere – prometaphase. During metaphase chromosomes line up in the equatorial plane, joined by microtubules from the centromere to the centriole, the mitotic spindles. Anaphase: Centomere of each cell divides and chromtids migrate to opposite poles of the spindle. Telophase: Cytoplasm divides and each daughter cell receives half of all double chr. material maintaining the same number of chromosomes as the mother cell.
Meiosis Meiosis needs two cell divisions (M1 and M2) to reduce the no. of chromosomes to haploid of 23 chromosomes. Cells replicate their DNA so that each of the 46 chromosome is duplicated into sister chromatids. Homologus chromosomes then align in pairs- called synapsis. Interchange of chromatid sgments between homologous pairs take place. Points of interchange are temporarily united and form a X-like structure called chiasma.
In metaphase1 homologous chromatids separate in two daughter cells each having half the No of chromosomes.
In metaphase 11 the centromeres divide and homologous chromatids separate into four daughter cells each having the haploid number of chromosomes.
Chromosomal Abnormalities May be numerical, structural or due to gene mutation A: Numerical: Aneuploid It is called Trisomy if there is one extra chromosome or Monosomy if one chr omosome is missing. It might occur in mitosis or meiosis. When occurs in meiosis it is called Nondisjunction. When occurs during mitosis (mitotic disjunction) or mosaism with some cells having abnormal chromosme number and others having normal number. Sometimes chromosomes break and pieces of one chromosme attach to another. Such translocations may be balanced or unbalanced eg Down’s syndrome. Trisomy 21 (Down’s Syndrome): Features: Growth retardation, mental retardation., craniofacial abnormalities, upwrad slanting eyes and low set ears. They are prone to leukemia, infection and thyroid dysfunctions. Incidence: 1: 2000 at 25 years, 1: 300 at 35 and 1: 100 above 40 years.
- Trisomy 18: Mental retardation, congenital heart defects, musculoskeletal deformities. Incidence 1: Trisomy 13: Mental retardation, holoprosencephaly, congenital heart defects, cleft lip and palate. Incidence: 1; Klinefelter syndrome: Occurs only in males. Discovered at puberty. Cells have 47 chr with a sex chr complement of XXY type and a sex chromatin Barr Body. Features are sterility, testicular atrophy, hyalinization of the seminiferous tubules and gynecomastia. Incidence: 1: 500 males. - Turner syndrome: Cells have 45 chromosome (Monosomy 45) and have female appearance. Features: gonadal dysgenesis, short stature, webbed neck, musculoskeletal abnormalities and lymphedema.
B: Structural chromosomal abnormalities Breakage of chromosomes result in deletion of parts of a chr.0mosome. - Cri-du-chat syndrome: due to deletion of the short arm of chr 5. Features: Cat-like cry, microcephaly, mental retardation and CHD. Microdeletion of the long arm of chr 15 (on the maternal chr) results in Angelman syndrome. Children are mentally retarded, cannot speak and exibit poor motor development. If the defect is inherited on the paternal chr it results in Prader- Willi syndrome charact by hypotonia, obesity, mental retardation, hypogonadism and cryptorchidism C: Gene mutation: genes usually occur as pairs (allels) except XY chr in males. So that there are two doses for each genetic determinant; one from the father and from the mother. If mutation affect a single dose it is dominant. If it occurs in both doses or on the X chr on the male it is recessive. This type of inheritance is called Mendelian Recessive Type. Gene mutations can cause inborn errors of metabolism eg phenyketonuria, galactosemia.