Lecture #1 Flashcards
Give the 4 fundamental developmental processes within embryology & define each.
-Cell division = growth
-Patterning = how cells know from the genome what to become
-Cell differentiation = SCs & progenitors turn into specific cell types - cell specialisation
-Morphogenesis = development of the forms in living organisms
What is oogenesis?
Growth process in which the primary egg cell (or ovum) becomes a mature ovum
–> oogonia develop from primordial germ cells in the forming ovaries
When does oogenesis begin in embryology?
-Before birth - week 8 of life in utero - in the ovaries of the unborn embryo
-Then is paused/suspended until puberty & ovulation - arrest @ prophase I of meiosis
-Is then paused again @ metaphase II until fertilisation
What is fertilisation?
= Union of a sperm nucleus, of paternal origin (haploid), with an egg nucleus, of maternal origin (haploid), to form the primary nucleus of an embryo - a zygote (diploid)
-Accomplishes both the recombination of genetic material
-Initiates events that begin embryonic development
Where does fertilisation occur?
Ampulla of the oviduct
–> ampullary-isthmic junction - ovum & sperm transported simultaneously to this junction of fallopian tube
–> so fertilisation occurs in ampullary region of fallopian tube or oviduct
Oviducts = fallopian tubes
What is involved in the process of fertilisation?
-Sperm must find way to egg
-Sperm & egg must contact, recognize one another, & fuse
-After sperm-egg fusion -> intracellular signalling cascade occurs in egg = two major consequences:
1 = allows egg to regulate sperm entry so only 1 sperm can fuse with egg = prevents polyspermy
2 = “wakes up” the metabolically quiescent egg so it can resume meiosis & begin embryonic development –> = egg activation
*Sperm must undergo sperm capacitation in female reproductive tract = modifies sperm - so can fertilise egg
–> sperm which successfully undergo capacitation = capacitated sperm
What are capacitated sperm then able to do?
Fertilise the egg
What stages are involved in sperm capacitation?
- Altered memb fluidity due to removal of cholesterol from sperm memb
- Removal of prots & carbs from memb - may otherwise block sites that bind to egg
- Change in memb pot that may permit Ca2+ to enter sperm = to facilitate acrosome reaction*** (MOST IMPORTANT STAGE WE NEED TO KNOW!)
- Phosphorylation of numerous proteins
What 3 barriers must sperm breach in order to penetrate the egg?
- Expanded cumulus (cumulus cell matrix = mostly hyaluronic acid - so v. acidic)
- Zona pellucida
- Plasma membrane of egg (= oolemma)
–> egg is surrounded by its expanded cumulus cells in the ampulla of oviduct
Explain the acrosome reaction.
Ca2+ dependent event
-Sperm plasma memb fuses w/ outer acrosomal memb to release the contents of the acrosomal vesicle
-Lytic enzymes are released from acrosomal vesicle –> digest zona pellucida - so sperm can contact plasma memb of egg
*Acrosomal reaction occurs whilst sperm is in contact w/ cumulus cells - & can be enhanced by binding to zona pellucida prots
What day of the menstrual cycle does fertilisation typically occur?
Day 15 or 16
What is the morula?
Ball of cells resulting from cleavage (cell division) of zygote
-Image of morula = bottom right
When (days) is the morula formed?
2 days after fertilisation -> here embryo is in oviduct/fallopian tube still
How many cells are in the morula?
16 cells
When (days) does the morula become a blastocyst?
Days 3-5 after fertilisation -> here embryo has entered uterus
How does the blastocyst form?
-Outer cells of morula become tightly adhesive to each other & start to transport fluid into embryonic mass
-This fluid transport forms a cavity = blastocyst
–> hollowing out of morula by morphogenic reorganisation
What is the blastocyst composed of - what 2 subpopulations of cells?
-(Eccentric) inner cell mass = embryoblast -> contacts endometrium to facilitate implantation & formation of placenta
-Outer - ep-like layer of trophoblasts = trophectoderm -> forms embryo itself
–> this layer immediately adjacent to inner cell mass is called embryonic pole = this is where blastocyst attaches to uterine endometrium (implantation)
-Primitive endoderm (mentioned as a component too in slides!)
What happens to the blastocyst before implantation?
Blastocyst ‘hatches’ from zona pellucida (protective coating)
When does blastocyst ‘hatching’ occur?
Around day 5 (post-fertilisation)
How does implantation of blastocyst into uterine endometrium occur?
-L-selectin receptors of blastocyst bind to oligosaccharides in uterine wall -> this interaction is stabilised by integrin heterodimers (= cell adhesion molecules
-Trophoblast cells of blastocyst - proliferate & secrete MMPs (Matrix MellaoProteinases)
-MMPs digest ECM (by lysing extracellular prots) & invade endometrium
-So villi of trophoblast can penetrate endometrium - pulling blastocyst (now called embryo) into endometrium until is fully covered by endometrial epithelium
–> SO BLASTOCYST IMPLANTS INTO UTERUS!!!
Summarise the stages from fertilisation to implantation in a diagram - include relevant timings, cell names & locations.
What is an ectopic pregnancy?
Pregnancy that occurs outside uterine cavity - often in fallopian tubes
–> i.e., blastocyst has implanted in incorrect place - not into uterine endometrium
Summarise the order of cells.
-Zygote
-Morula = 16 cells
-Blastula
-Blastocyte
Gastrulation process
-Gastrula
-Embryo?
What occurs during gastrulation?
Gastrulation = process by which bilaminar disc differentiates into trilaminar disc - up of 3 primary germ layers: ectoderm, mesoderm, & endoderm
Day 15
-Bilaminar embryonic disc (epiblast + hypoblast) differentiates throughout week 3 = x3 primary germ layers
-Primitive streak forms near caudal end of bilaminar embryonic disc
-Formation of primitive streak defines the major body axis -> cranial end towards head & caudal end towards tail & left & right sides of embryo
-@ cranial end of embryonic disc - primitive streak expands -> forms primitive node (contains circular depression = primitive pit)
-Primitive pit continues along midline of epiblast towards caudal end of streak - forms primitive groove
-Once formed - epiblast cells migrate inwards into primitive streak - detach from epiblast & split beneath into interior of embryo = invagination
-1st cells to invaginate through primitive groove - invade the hypoblast & displace hypoblast cells
-Hypoblast cells will eventually be replaced by new proximal cell layer = definitive endoderm
Day 16
-Most of hypoblast cells now replaced
-Remaining cells of epiblast now = ectoderm - forms most exterior distal layer
-Some of invaginated epiblast cells remain in space between ectoderm & definitive endoderm -> these cells form mesoderm
-Once definitive endoderm & mesoderm formation = complete - epiblasts cells no longer migrate to primitive streak
-Throughout gastrulation -> ectoderm continues to form from cranial to caudal end of embryo
= 3 distinct primary germ layers throughout embryonic disc
= gastrulation now complete
What does each of the 3 germ layers become/what do they give rise to?
What does the neural crest form in the head?
Musculoskeletal tissues
What do hox genes do?
Specify regions of the body plan of an embryo along the head-tail axis (anterior-posterior axis) of animals
-Different clusters work together to establish the identity of body segments along the head-tail axis
-Towards start of cluster these hox genes act specifically in the development of the head, neck, then middle = thorax/torso/mid-region?, then towards end of the gene cluster - these hox genes act in development of vertebrate limbs (arms, legs or wings)
e.g., Hox6 expresses thoracic vertebrae
–> so these hox genes = TFs (so bind to DNA - have DNA binding region called homeodomain) which ensure the right genes are expressed & the unneeded genes are turned off during development
What happens if a hox gene for lumbar vs thoracic vertebrae is expressed throughput the body axis?
Lumbar = no ribs form
e.g., Hoxa10 expressed throughout body axis = all vertebrae are lumbar
Thoracic = ribs form
e.g., Hoxb6 expressed throughout body axis = all vertebrae are thoracic
