Introductory Biology II: Embryology

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Embryology
Candice Young
Karteikarten von Candice Young, aktualisiert more than 1 year ago
Candice Young
Erstellt von Candice Young vor mehr als 7 Jahre
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End result of spermatogenesis four non-identical sperm cells produced
End result of oogenesis 1 large ovum produced and 3 non-functional polar bodies
Fertilization oocyte undergoes meiosis, sperm cell fuses with ovum to form a zygote
Cleavage lots of RAPID cell divisions in zygote, very little growth or transcription, reduction of cytoplasmic volume, axes form
Blastula hollow ball of cells resulting from cleavage
Gastrulation make 3 distinct "germ" layers (endoderm, mesoderm, ectoderm) in Blastula, results in primitive gut formation
Gastrula 3 layered embryo
ectoderm forms nervous system and outer layers of skin
endoderm forms digestive tract. respiratory tract, and digestive organs
mesoderm forms kidneys, heart, muscles, bones
Animal pole vs vegetal pole Animal pole divides faster; dark brown coloring in Xenopus laevis; later are the ectoderm axis
Cell movements during gastrulation a lo of cells rush in from the outside and the rest spread themselves out (epiboly) thinly in an stretched out layer
Molecular basis of gastrulation changes in cell adhesion
fate maps tracking cells in time and space; show where each tissues of germ layer originally came from; do NOT inform us about when states of cell determination occur
Roux's experiment experimented by killing one frog blastomere cell at two cell-stage and observing the other's development concluded that blastomeres at the earliest stage have a predetermined fate and only a half embryo can form
Driesch's experiment separated sea urchin cells at two-cell stage and observed growth of a small but otherwise normal larvae revealed that at two (and four) cell stages, individual blastomeres are totipotent
totipotency the capacity for a cell to give rise to any embryonic cell type
Horstadius' tier experiments separate cells at 8 cell stage --> get a ciliated blastula and a vegetalized blob reveals how cells lose totipotency and become committed to a developmental fate as development proceeds
John Gurdon's experiments take adult frog skin cell and tadpole gut epithelial cell, destroy nuclei, and transfer nucleus into unfertilized eggs --> tadpoles develop shows that genetic information is not lost as cells differentiate
Regulative Development Model early embryos have a capacity for regulation; have developmental plasticity
Asymmetric Division Sister cells can be born differently despite having the same genetic information
Symmetric Division Sister cells with the same genetic information become different as a result of different neighbors acting on them
How do cells know which genes to express? the combination of internal information from asymmetrical distribution & external information from cell-cell signaling
How animal-vegetal axis is determined (in Xenopus) Determined maternally; egg radially symmetric before fertilization & there is differential localization of maternal mRNAs
How dorsal ventral axis is determined (in Xenopus) determined by where the sperm enters --> makes the cortex rotate 30 degrees
Induction cell-cell interactions cause special tissues to develop
Spemann's separation experiment divided two cells with a baby hair, one half could grow own embryo BUT plane of division is crucial
The Organizer cluster of cells in developing amphibian embryo that induce development of central nervous system; crucial discovery to concept of induction
dorsal lip of the blastopore cells that are COMMITTED to invaginate into the blastula, "the Spemann organizer," formed by the gray crescent region of an egg
Results of dorsal lip transplant continued to be committed to its "fate" --> initiated a second gastrulation in surrounding tissue and two embryos/axes form via induction
B-catenin protein that can induce changes in cell fates based on where it accumulates; can form new dorsal regions when injected
Specification when the mesoderm is under the ectoderm, tissue is specified to become the nervous system BUT if moved it could become something else NOT irreversible!
Determination when cells will produce the determined cell types and will not be altered by inducers to become completely different IRREVERSIBLE
Involuting Marginal Zone cells on the dorsal lip of the blastopore in developing Xenopus eggs, move to the interior via invagination and become the mesoderm
Neurula What the embryo is called after gastrulation leads to the formation of the neural fold --> notochord
What's in a human sperm cell? Haploid nucleus, centriole (forms spindles during division), mitochondria, acrosome enzymes (to digest egg coat)
What's in a human egg cell? Egg cytoplasm: nutritive proteins, ribosomes & tRNA, **mRNAs**, morphogenetic factors, protective chemicals, egg cortex (cortical granules) Vitelline membrane to attract and activate sperm + regulate ion flow
Egg-sperm recognition Exocytosis of sperm's acrosomal vesicle, bindin coats sperm actin filaments and binds sperm to vitelline envelope, sperm passes through and membranes fuse
Fast block to polyspermy Depolarization of egg electric potential due to influx of Na+ means no more sperm can fuse
Slow block to polyspermy cortical granules cleave links between vitelline membrane and plasma membrane, stimulated by increase in intracellular Ca2+ from sperm fusion
Follicle Stimulating Hormone (FSH) produced by pituitary gland, controls production of oocytes in women and sperm in men; stimulates production of estrogen in women
Corpus luteum involved in production of progesterone, left behind after egg leaves in ovulation, maintains uterine lining (endometrium)
Luteinizing hormone hormone that triggers ovulation and development of corpus luteum
where does fertilization (as well as the first cleavage) occur? in the fallopian tube/OVIDUCT
first ball of cells after cleavage in humans the morula
human chorionic gonadotrophin (hCG) hormone secreted by specialized cells that maintains the corpus luteum after implantation
Implantation human blastula is implanted into endometrium, trophoblast outer layer forms placenta so direct nutrient exchange can occur
chorionic gonadotropin hormone secreted by trophoblast and chorion that maintains corpus luteum after implantation
The Four Extra-embryonic Membranes 1) Chorion 2) Amnion 3) Yolk Sac 4) Allantois
Chorion trophoblast, surrounds everything
Amnion cushions embryo and prevents desiccation; is fluid filled
Yolk sac forms blood cells that migrate into the embryo, doesn't actually contain yolk
Allantois develops from archenteron (gut) outgrowth, becomes a part of the umbilical cord
First Trimester three germ layers --> limb buds --> developed enough to be called an embryo (non-self) --> limb elongation --> organs are in place --> hCG levels drop and CL begins to disentegrate
Second Trimester progesterone production --> general growth --> bone development --> heart beating --> vernix (skin) covering
Third trimester weight increase --> eyelids split --> lungs mature --> hearing develops --> uterine cavity full
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