BIOS 30342 Developmental Biology Exam 1 Study Notes 2024 PDF

Summary

This document provides study notes for a developmental biology course, specifically focused on a unit 1 exam in 2024. It covers introduction, mechanisms of development, approaches to studying it, gametogenesis, and fertilization. The detailed information makes it helpful to understand the course content better.

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BIOS 30342 DEVELOPMENTAL BIOLOGY
EXAM 1 STUDY NOTES 2024

UNIT 1 CONTENT INDEX

OVERVIEW INTRODUCTION TO DEVELOPMENTAL BIOLOGY
Making the zygote à embryo à birth of organism à adult sexual maturity
Cell diversification, organization, behavior, recipe, flavoring the recipe = evolution
Reasons to study development
o fascinating scientific crossroads
o medical applications
Historical perspectives
Use of model organisms to study development
Overview of the animal life cycle

LECTURE 1 MECHANISMS OF DEVELOPMENTAL PATTERNING
Pattern formation
Genetic control of development à genomic equivalence & differential gene expression
Development is progressive
o use of fate maps to track destiny
o stages of commitment à specification à determination à differentiation
Modes of development
o mosaic = determinants
o regulative = interactions
Communication during development
o cell-cell signaling
o induction = inducer interacts with responder that is competent to respond

LECTURES 2,3 MAJOR APPROACHES TO STUDYING DEVELOPMENT
Rules of evidence
o correlative
o functional = loss and gain
Staging series
Correlative evidence
o tracking cell fate = stains and genetic labels
o assessing gene expression = RNA, protein & transgenic reporters
Experimental embryology à physical manipulations to test loss and gain of function
Genetic manipulations
o forward genetics à screens for dominant, recessive, and maternal effect genes
o reverse genetics à gene targeting and knockdown strategies

LECTURES 4,5 GAMETOGENESIS & FERTILIZATION
Primordial germ cells
Gametogenesis strategies
o spermatogenesis
o oogenesis
Fertilization & zygote activation in the sea urchin
o acrosomal reaction
o fast and slow block to polyspermy
o jumpstart of metabolism
Fertilization & zygote activation in mammals
o involves similar acrosomal reaction, blocks to polyspermy & metabolism start
o sperm capacitation
INTRODUCTION TO DEVELOPMENTAL BIOLOGY

WHAT IS DEVELOMENTAL BIOLOGY?
Making the zygote à embryo à birth of organism à adult sexual maturity
o gametes are produced and are brought together to make the ZYGOTE = fertilized egg
o 1-cell ZYGOTE à becomes a complex EMBRYO with dozens to hundreds of cells fashioned into
tissues, organs and organ systems
o development does not end with BIRTH/HATCHING event à continues through SEXUAL MATURITY
when gametes can be produced to create a 1-cell ZYGOTE

Questions developmental biologists seek to answer:
o How do cells arising from 1 cell become different from each other?...........CELL DIVERSIFICATION
o How are cells assembled into complex structures like a limb?................... ORGANIZATION
o What activities drive individual cells to make highly organized patterns?... BEHAVIOR
o How are the instructions embedded within the zygote?.............................. RECIPE
o How have changes in developmental programs evolved animal form?...... FLAVORING THE RECIPE

Development is a fascinating scientific crossroads = intersect of life and physical sciences !

Medical applications of developmental biology
o understand congenital birth defects (aka congenital anomaly or malformation) = alterations to
normal events which arise from genetic and/or environmental effects (e.g. infection, maternal health)
o provides insights to fundamental mechanisms of genetics and physiology
o origin of juvenile & adult conditions = developmental gene defects à initiate acquired, chronic diseases
o therapy = regenerative medicine & stem cell technologies to treat diverse medical conditions

HISTORICAL PERSPECTIVES
Humans have been fascinated with the steps of animal and plant development for thousands of years, first
known record dating back to Aristotle in 350 BC in his book detailing variations in how animals are born:
oviparity = from external eggs; viviparity = live birth (placental); ovoviviparity = hatched from internal eggs

Conceptual debate about development before the molecular age:
o EPIGENESIS = concept of generating each animal from scratch
versus
o PREFORMATION = concept that all animals were already generated and were within an original egg or
sperm = envisioned as the homunculus, or little person fashioned inside = Russian nesting doll analogy

Critical advances in thought from 1800’s onward:
o cell theory = notion that cells are the building block of the body
o discovery of germ layers = separate embryonic zones of ectoderm, mesoderm, endoderm
o nature of inheritance = nuclear = DNA = passage of hereditary material through gametes
o genetic basis of development = precise DNA sequences direct cell identity & behavior

USE OF MODEL ORGANISMS TO STUDY DEVELOPMENT
Invertebrate and vertebrate species provide clues about the basis of human development

PHYLOTYPIC STAGE = period of time when vertebrate embryos share a high resemblance
o basis is the shared genetic program of development
o common features:
§ distinct embryonic axis = discernible head-tail character
§ neural tube = prefigures the central nervous system & runs length of embryo axis
§ notochord = feature of chordate species
§ somites = transitory blocks of mesoderm that prefigure musculoskeletal system
OVERVIEW OF THE ANIMAL LIFE CYCLE
GAMETOGENESIS
o produce gametes by meiosis = reductive division of inherited material = chromosomes of DNA
o gametes are highly specialized = produced by differentiation
§ their unique features enable proper gamete joining & species recognition
§ features also support normal zygote development

FERTILIZATION
o steps involved with getting the GAMETES fuse à ZYGOTE !

CLEAVAGE
o early rounds of zygote division
o rapidly partition the ZYGOTE à BLASTULA = ball of cells
o turn 1 cell in several hundred that are used to start making layers of the body
o creation of a BLASTOCOEL à hollow cavity filled with watery fluid used during gastrulation
o REGIONAL SPECIFICATION à spatial organization will be performed to create body plan

GASTRULATION
o reorganize BLASTULA à GASTRULA
§ move cells around to actually construct the body plan and then progressively refine it
§ body plan = emergence of anterior-posterior and dorsal-ventral axes, e.g. head-trunk-tail
o partitioning of fates into 4 distinct lineages:
§ 3 GERM LAYERS = ECTODERM, MESODERM, ENDOGERM
§ reproductive GERM CELL lineage = PRIMORDIAL GERM CELLS

CELL LINEAGE DEFINITIONS
§ ECTODERM = outer layer
Þ Examples: make skin, nervous system, neural crest (contributes to all 3 germ layers)
Þ Note: the nervous system & neural crest become internalized (we will study this in unit 2)
§ MESODERM = middle layer
Þ Examples: make muscle, bone, blood, kidney, heart, limbs
§ ENDODERM = innermost layer
Þ Examples: make primitive gut tube, gut accessory organs, derivatives like the lungs
§ GERM CELL LINEAGE = segregated to a special location (typically posterior) until gonads form
Þ can make either gamete depending on gonad destination (see Lecture 4 notes, this unit)

ORGANOGENESIS
o body plan of layers à now make subsets of cells into organs! “germ layersà organs” via
MORPHOGENESIS and GROWTH = involving cell proliferation and regulated cell death/pruning

Examples over developmental time from early to later stages: (we will see these in units 2-4 !)
§ NEURULATION = make central nervous system and disperse neural crest throughout the body to
make peripheral nervous system and contributions to all the germ layers
§ establish LEFT-RIGHT axis
§ CARDIOVASCULAR = make the heart, blood, blood vessels to oxygenate growing fetus
§ emergence of UROGENITAL, GASTROINTESTINAL, & RESPIRATORY systems

HATCHING à BIRTH EVENT
o emergence from embryonic membrane(s), egg, or uterus

PROGRESSION TO SEXUAL MATURITY
o may involve METAMORPHOSIS
o emergence of secondary sex characteristics and the sequence of complex hormonal changes will initiate
gametogenesis and release of gametes during mating ritual or coitus
LECTURE 1. MECHANISMS OF DEVELOPMENTAL PATTERNING

PATTERN FORMATION
PATTERNING = mechanisms that create the embryonic form
o involves a stepwise series of choices that direct cells from the ZYGOTE TOTIPOTENT STATE to the
final destination = DIFFERENTIATED STATE = possess unique structure & physiological function
Examples
§ establishing the body plan à defining the axes (anterior-posterior, dorsal-ventral, left-right)
§ allocation of cells to the germ layers and germ cell lineage
o differentiation is a gradual process that transpires typically over many cell divisions

FUNDAMENTAL CONCEPTS
o STEM CELL = precursor = unspecialized = immature = traits of the zygote for example
versus
o DIFFERENTIATED CELL = mature = “terminally differentiated” = choice to become is finalized
§ exhibit unique traits = size, shape, color, motile, stationary, mesenchymal, epithelial, resting
membrane potential, organelles, molecular components like RNA and protein
§ animals are comprised of several hundred (e.g. range of 100-250, or more)
§ differentiated state is stable
§ terminal = end of development path = last stop = only options left are to function or die
o POTENCY = all the fates possible for a cell
§ development is a process of potency restriction = limiting what a cell can become
§ totipotent à pluripotent à multipotent à sometimes as specific as unipotent

GENETIC CONTROL OF DEVELOPMENT
GENOMIC EQUIVALENCE = most cells contain the same (complete) set of genetic materials
DIFFERENTIAL GENE EXPRESSION = different cells express different sets of genes
o HOUSEKEEPING = for fundamental cell processes = e.g. proteins that make nuclear envelope
o SIGNATURE = enable cell to perform discrete, unique set of physiological functions
o cells share expression of housekeeping genes and are different due to signature gene expression
o gene expression is regulated at 5 major levels:
§ transcription, RNA processing, RNA transport, translation, protein modification
§ transcriptional regulation is extremely important
o regulatory or control regions dictate gene expression and are bound by transcription factor proteins
§ promoters = near gene coding region
§ enhancers = distant from gene coding region

DEVELOPMENT IS PROGRESSIVE
FATE MAPS = track destiny of cells over time
Examples
o make a map of the blastula à what do each of the blastomere cells become?
o make a map of the gastrula à what do each of the germ layers become?

STAGES OF COMMITMENT
o SPECIFICATION = are cells capable of becoming their fate in a neutral environment?
§ Example: test by culturing cells in saline/simple culture medium
o DETERMINATION = are cells capable of becoming their fate in a non-neutral environment?
§ Example: test by culturing cells in another region of the embryo = expose to other proteins
o DIFFERENTIATION = executing identity = exhibit final differential gene expression profile
o POTENCY IS TYPICALLY GREATER THAN FATE = cells can do more than what they are normally
triggered to do during embryogenesis
§ along the continuum of commitment, cells are groomed to adopt a unique differentiated identify
§ but cell types across the germ layers share many characteristics, and thus cells can be made
into many related cell types depending on the context they find themselves in!
MODES OF DEVELOPMENT
o MOSAIC = cells operate independently to self-differentiate = direct themselves without inputs from other
cells or the environment
§ molecular determinants = e.g. certain mRNAs, proteins à specify or determine cell identity
o REGULATIVE = cross-talk between cells and/or their environment direct differentiation
§ interactions dictate changes in gene expression & cellular activities based on cell signaling
o most embryos display both modes during different times of development

COMMUNICATION DURING DEVELOPMENT
o CELL-CELL SIGNALING
§ diffusible signal docks on receiving cell
§ cells make direct contact with one another to relay messages

o INDUCTIVE INTERACTIONS = cell signaling events that direct commitment and differentiation
§ INDUCER = source of directions
§ RESPONDER = receiver of directions
§ COMPETENCE = ability to respond
Examples
Þ depend on the expression of a membrane receptor
Þ depend on the expression of a particular transcription factor

LECTURES 2 & 3. MAJOR APPROACHES TO STUDYING DEVELOPMENT

RULES OF EVIDENCE
CORRELATIVE = implicates the involvement of a factor in a process
Example: gene transcript expression correlates with formation of a particular organ

FUNCTIONAL
o LOSS OF FUNCTION = When a factor is removed, what happens? Is the factor NECESSARY for a process?
Example: interfere with normal expression of a gene à prevent creation of a normal gene product

o GAIN OF FUNCTION = When a factor is added, what happens? Is the factor SUFFICIENT for a process?
Example: addition of transcripts to a group of cells à addition of protein where it would not normally be

STAGING SERIES
DOCUMENTATION OF TIME & SEQUENCE OF DEVELOPMENTAL EVENTS FOR A GIVEN SPECIES
o each model organism has an atlas based on different time intervals, e.g. hours, days
o the atlas could be based on physical features of the embryo, e.g. number of somites at a given time,
time organs appear, or pigmentation pattern

COLLECTION OF CORRELATIVE EVICENCE
TRACKING CELL FATE = mark the origin of a cell and its destiny at later time points
o NATURAL FATE MAPPING = pigment(s) in an embryo
o VITAL DYES = non-toxic chemical transferred to the embryo
Examples:
§ Nile blue sulfate, India ink, neutral red, Bismark brown, Janus green
§ diI or diO = modern fluorescent molecules that associates with cell membrane
o AUTORADIOGRAPHY = introduce radioactive substance to cells
o GENETIC FATE MAPPING = cells with genetic differences that can be distinguished with antibodies,
genotyping (PCR, sequencing) or morphological characteristics
Example:
§ CHIMERAS = exchange cells from related species, such as quail and chick
 ASSESSING GENE EXPRESSION
o mRNA TRANSCRIPTS
Examples
§ RT-PCR = reverse transcriptase PCR = assess presence of an mRNA transcript & quantify it
§ WISH = whole mount in situ hybridization = visualize mRNA transcripts “in place” = spatial 3D
o PROTEINS
Example
§ immunohistochemistry = antibody staining = see location of proteins in spatial 3D
o TRANSGENIC REPORTERS
Example
§ use a tissue specific promoter to drive expression of a visual marker or stainable gene product
§ need to have isolated DNA sequence for a control region that drives expression in particular cell
group at particular developmental times
§ use control region to drive expression of a reporter gene whose product is easy to stain or see
in real time, like green fluorescent protein

EXPERIMENTAL EMBRYOLOGY
PHYSICAL MANIPULATIONS TO TEST LOSS AND GAIN OF FUNCTION
o SURGICAL PROCEDURES TO TRANSPLANT, ABLATE OR PUT BARRIERS BETWEEN TISSUES
Examples
§ transplant of dorsal blastopore lip at gastrula stage in amphibian embryo à twinned axis
§ Gurdon’s in vitro experiments with animal caps and vegetal caps à to assess features of
mesoderm induction like the proximity of the vegetal signal, whether it can cross a piece of filter
paper, and the effect of different amounts of vegetal cells on a given amount of animal cap
§ Gurdon’s discovery of the “COMMUNITY EFFECT” = a critical mass of vegetal cells were
necessary to induce mesoderm formation à indicates interactions amongst a group of cells
§ role of the apical ectodermal ridge (AER) in vertebrate limb development = removal of the
thin layer of ectoderm leads to stunted limb outgrowth from the trunk à indicates signal(s) from
the ectoderm are necessary for full appendage growth
§ modern microinjection methods à example of how researchers manually deliver molecules
to the 1 cell stage embryo to interrogate gene function à may deliver copies of mRNA, protein,
DNA or agents to manipulate gene expression like blocking mRNA expression or protein activity

GENETIC MANIPULATIONS
observations of “SPONTANEOUS” aka random/naturally occurring genetic mutants à lead to systematic
efforts to create & study mutations that alter developmental events
genetic manipulation = manipulate model organism at the level of inherited DNA
Examples
§ introduce mutations randomly by altering nucleotides in the chromosomes
§ introduce a DNA sequence (construct) engineered in the lab that can change gene expression
(e.g. encode a truncated protein due to introduction of a premature stop codon)
o each model organism has different amenabilities to genetic manipulations
o desirable traits would include:
§ breed rapidly = short generation time
§ large brood size = number of offspring
§ able to maintain large colony in lab environment = such as size of animal
§ knowledge of genome

FORWARD GENETICS
o basic strategy: generate animal colony harboring HERITABLE mutations à search for animals with
phenotype of interest à identify the responsible genetic defect = lesion
o MUTAGEN = agent used to change chromosome
Examples
§ chemical = alkylating agents = introduce single base (point) mutations in chromosomes
§ electromagnetic radiation = x-ray, gamma ray = introduces large anomalies in chromosomes
(deletions, translocations, inversions)
§ DNA insertion = retroviruses, transposable elements
 o SCREEN FOR DOMINANT GENES à mutate F0 adult and breed to wild-type partner à each F1
individual carries 1 possible heritable mutation (based on the amount of mutagen they were exposed to)
à examine F1 offspring to screen for mutations that alter a developmental process à dominant alleles
will display a phenotype with 1 copy of the allele
§ rapid screen because only breeding 1 generation
§ dominant mutations à typically strong phenotypes à will embryo survive to pass on allele?

o SCREEN FOR RECESSIVE GENES à mutate F0 adult and breed to wild-type partner à each F1
individual carries 1 possible heritable mutation (based on the amount of mutagen they were exposed to)
à breed the F1 to a wild-type partner à raise the F2 offspring in order to create a family with multiple
carriers à intercross the F2 adults and look at their F3 offspring to screen for mutations that alter a
developmental process à if you mate two F2 carriers: offspring are 25% wild-type; 50% heterozygote;
and 25% homozygous with a phenotype due to inheritance of 2 copies of the recessive allele
§ homozygous recessive state may be embryonic lethal = many genes are necessary for
multiple developmental events = are PLEIOTROPIC = multiple functions
§ homozygous recessive state may not show a phenotype because of REDUNDANCY = genes
and pathways that have overlapping, redundant functions
§ homozygous recessive state may not show a phenotype because of MATERNAL EFFECT =
the F2 mom is a heterozygous carrier of the recessive allele
Examples
§ F3 screen for body plan alterations in the fruit fly, Drosophila melanogaster = invertebrate =
insect revealed genes needed to make a proper pattern of body segments
§ F3 screens for developmental alterations in the zebrafish, Danio rerio = vertebrate = teleost fish
revealed genes needed for gastrulation, body plan, organogenesis

o SCREEN FOR MATERNAL EFFECT GENES à maternal production of oocytes involves addition of
many materials to the differentiating gamete à to identify these genetically encoded agents, need to
look at offspring of a mother who harbors two mutant alleles à in a recessive screen strategy (above)
the F3 homozygous mutant offspring are raised à F3 adults are mated and the offspring examined.
§ If the F3 homozygous female harbors a maternal effect gene and is mated to a wild-type male,
all the embryos will show a phenotype due to the lack of maternal contribution to the oocyte.
§ Researchers also examine the combined result of homozygous defects in the zygotic AND
maternal genomes by mating the F3 homozygous female to an F3 heterozygous male. In this
cross, half of the embryos are heterozygous for the recessive allele and have no maternal
contribution; other half are homozygous for the recessive allele and have no maternal contribution.

REVERSE GENETICS
o GENE TARGETING = modify the DNA = creation of designer or specific mutations
§ KNOCK OUT = remove code and obliterate gene function
§ KNOCK IN = switch sequence to introduce alternative gene code

o performed by
Þ HOMOLOGOUS RECOMBINATION = exchange or swap a region of DNA to modify
chromosomes in embryonic stem (ES) cells which are obtained from the inner cell mass
of the mouse blastocyst = ES cells are pluripotent and retain the ability to make all cell
types of the embryo
Þ introduce the modified ES cells into a wild-type blastocyst à CHIMERA will possess a
mixture of wild-type and modified cells and thus a mixed genotype
Þ if the modified cells contribute to the germ lineage of the CHIMERA, then offspring of
the chimera will be heterozygous for the modified, mutant gene and can be bred to obtain
homozygous mutants
Þ when homozygous state is embryonic lethal, researchers turn to making CONDITIONAL or
tissue specific knockouts in order to disrupt gene in a specific location at a specific time
Þ we will revisit conditional alleles later in the course
§ gene editing = use of CRISPR/Cas9 system to target a specific sequence *details not discussed

o GENE KNOCKDOWN = use of a transient method = various approaches available in different models
Example
§ morpholino in zebrafish = *details not discussed
LECTURES 4 & 5. GAMETOGENESIS & FERTILIZATION

PRIMORDIAL GERM CELLS (PGCs) = GERM STEM CELLS
BIOPOTENTIAL PRECURSORS that are set aside early in development
o if come to reside in testis à produce sperm
o if come to reside in ovary à produce eggs
o exhibit self-renewal and divide by MITOSIS
o when they differentiate à offspring switch to MEIOSIS = REDUCTIVE DIVISION = halve PLOIDY number

PGCs undergo migration
o in mammals, reside in the posterior of the early embryo (epiblast)
o migrate into the ENDODERM = region of the early gastrointestinal tract precursors
o travel to reach the GENITAL RIDGE = bilateral gonad rudiment
o expanding tissue mass located medial to the primitive kidney structures
o genitourinary systems form in close proximity and interchange or repurpose some parts over time

postulated cascade of gonad formation involves transcription factors followed by hormones
o hormones will dictate genesis of the gonad & accessory plumbing
o XX genotype à express estrogen
§ promotes Müllerian duct survival à become oviduct
§ primitive renal tube, Wolffian duct, will degenerate
§ drives formation of the uterus, cervix, vagina from surrounding mesoderm
o XY genotype à 2 hormones
§ AMH = anti-Müllerian hormone à induces degeneration of the Müllerian duct
§ testosterone à blocks Wolffian duct degeneration à become the epididymis & vas deferens
§ also directs scrotum and penis formation

GAMETOGENESIS STRATEGIES (focus on mammalian gonads & structures)
prepare the nuclear material and make particular cytoplasmic components and organelles
tenets of successful fertilization = ensure fidelity = PREVENT MISTAKES
o proper ploidy number = chromosomes copied & segregated during meiosis
§ pair duplicated homologous chromosomes in first division, when recombination is possible
§ separating sister chromatids in second division
o identify correct partner gamete = compatible = usually the same species

SPERMATOGENESIS = differentiate to make small shuttle that carries the DNA
o within testis, sperm housed in SEMINIFEROUS TUBULES = specialized tunnels
o supported by SERTOLI CELLS = resemble a jigsaw puzzle piece in shape
§ wraps PGCs and their offspring and makes protective blood-testes barrier
§ phagocytoses the RESIDUAL BODY = cytoplasm jettisoned from the mature sperm cell

o steps in sperm production: PGC = spermatogonia that divide by MITOSIS à when they initiate
MEIOSIS the offspring are termed primary spermatocytes (4n) that divide to make à secondary
spermatocytes (2n) that divide to make à spermatid (1n) à finish differentiation into the sperm
§ divisions of the spermatogonia and spermatocytes connect cells = CYTOPLASMIC BRIDGES
§ PGCs at basement membrane (basal lamina) of the seminiferous tubule and offspring are
distributed in layers approaching the lumen
§ sperm production is regulated through influence of hormones

o features of the mature sperm = organized into 3 regions, the head-midpiece-tail
§ CONDENSED NUCLEUS mostly packed with PROTAMINES à some packing with histones
and those regions are more accessible to cell machinery
§ ACROSOMAL VESICLE = Golgi derivative = contains digestive enzymes to make path to egg
§ centriole which organizes the FLAGELLUM = tail
§ MITOCHONDRIA in midpiece provide ATP for dynein ATPase motor protein in the flagellum
 OOGENESIS = differentiate to make a cell capable of supporting zygotic life & embryo form
o eggs are HUGE cells
§ house all the materials necessary for beginning development and early growth
§ animals that develop ex utero will contain more materials than those that develop in utero
§ receive help in differentiation from many other cells, such as local neighbors and distant
organs like the liver
o features of the mature egg
§ NUCLEUS
Þ nucleus is not condensed = may be at any stage of MEIOSIS at the time of fertilization
Þ will be in NUCLEAR ARREST = suspended animation at time of fertilization
Þ species vary with regard to whether PGCs = OOGONIA divide mitotically throughout life
Þ in humans, millions of oogonia are made and degenerate during gestation, then continue to
decline in number as we age
Þ meiosis will conserve cytoplasm = put nuclear material into small POLAR BODIES
§ CYTOPLASM
Þ generate a massive, complex cytoplasm with materials that support
Þ cell metabolism (e.g. mitochondria, yolk proteins)
Þ DNA production (e.g. DNA polymerases and nucleotides)
Þ gene expression (RNA polymerases, ribosomes, transfer RNAs, amino acids)
Þ some have innate defense mechanisms
Þ chemicals that block ultraviolet light or distasteful (disincentivize predation)
§ MITOCHONDRIA = truckloads !!! most abundant of any animal cell known to date
§ METABOLIC ARREST = activities like protein synthesis are dormant once the gamete reaches
the stage when it would interact with the sperm = again, this stage varies across animal
species; in mammals it is metaphase II of meiosis II

FERTILIZATION & ZYGOTE ACTIVATION IN THE SEA URCHIN
premier model for fertilization studies
o large eggs that can be seen with a light microscope (compound)
o easily accessible gametes that are released into the water
o large numbers of gametes that have been used to purify proteins and determine identity of factors that
are necessary & sufficient for fertilization

EGG structure = jelly coat, vitelline envelope, cell membrane, cortical granules, cytoplasm and nucleus
o JELLY COAT contains = CHEMOTAXIC PEPTIDES = example of resact, a small peptide that attracts
sperm and physically binds a membrane protein on sperm that triggers opening of Ca++ channels to
induce faster swimming = CHEMOKINESIS
o vitelline envelope & cell membrane contain species-specific proteins used for molecular recognition
o CORTICAL GRANULES = prevent polyspermy and change chemical composition of membranes at time
of fertilization

FERTILIZATION occurs through the ACROSOMAL REACTION
o sperm contacts jelly and interacts with complex sugars and proteins in this coat
o species match triggers Ca++ influx on sperm à dumps the acrosomal vesicle contents à digest jelly
o sperm extends the ACROSOMAL PROCESS by polymerizing actin to reach out and touch the egg cell
membrane
o specific proteins on sperm cell membrane interact with receptors on the vitelline envelope and egg cell
membrane à competent sites for interaction are not ubiquitous on the egg
o sperm will enter the cell with help from the egg: egg makes fertilization cone and grabs sperm with
microvilli

PREVENTION OF POLYSPERMY
o FAST BLOCK
§ sperm binding to egg cell membrane triggers rapid opening of Na+ gated channels
§ surge of Na+ influx raises resting membrane potential of egg cell from -70 mV to +20 mV
§ positive resting membrane potential deters sperm binding !
 o SLOW BLOCK
§ sperm binding to egg cell membrane ALSO triggers internal signal transduction events
§ tyrosine kinase is activated and activates phospholipase C = a membrane associated enzyme
that splits PIP2 into 2 messengers: IP3 and DAG
§ IP3 travels to the endoplasmic reticulum and opens Ca++ ligand gated channels
§ Ca++ surge in cytoplasm triggers fusion of CORTICAL GRANULES with egg cell membrane
§ release of proteases that cut connections between egg cell membrane and vitelline envelope
§ vitelline membrane lifts off the egg cell and space filled with water à at this time, the vitelline
envelope is now named the FERTILIZATION ENVELOPE
§ fertilization envelope puts critical barrier around egg and is chemically changed (e.g.
peroxidases released by cortical granules) and egg is chemically changed as
well…compatibility with sperm is eliminated

EGG ACTIVATION à JUMPSTART METABOLISM
o Ca++ surge in cytoplasm from the slow block has a second agent, DAG, which targets activation of:
Na+/H+ exchange pump on the egg cell membrane
§ activation of the pump removes H+ ions, thus raising pH to alkaline
§ Ca++ and pH change alter many molecules à triggers onset of DNA replication, protein synthesis
§ proteins are made from maternally deposited transcripts
§ all initial proteins come from the maternal genome !
§ activation of zygotic gene transcription occurs at a later timepoint (varies in species)

o the pronuclei will be brought together using microtubule tracts
§ assisted by sperm: contributes its CENTRIOLE to form the first mitotic spindle in the zygote

FERTILIZATION & ZYGOTE ACTIVATION IN MAMMALS
EGG maturation release = OVULATION
o triggered by ovarian cycle which operates due to a hormonal cascade
o hypothalamus produces gonadotropin releasing hormone, which stimulates the anterior pituitary to
release follicle stimulating hormone (FSH) and luteinizing hormone (LH)
o FSH and LH stimulate the maturation of the primary oocyte within its follicle
o LH surge triggers actual ovulation

EGG structure = cumulus made of cells from follicle that protects the egg à zona pellucida = complex
layer of glycoproteins à cell membrane à cortical granules à cytoplasm and nucleus

FERTILIZATION
o sperm burrows through cumulus through swimming action
o sperm interacts with specific components of the zona pellucida for species match
o upon matching, the acrosomal reaction is triggered to digest path to egg cell membrane
o side of the sperm head makes actual contact with the egg cell membrane
o entire sperm brought inside with microvilli helping à most mitochondria degraded
o as in the sea urchin, a phospholipase C is at work: however, a soluble form enters the egg from the
sperm cell and splits egg PIP2 into 2 messengers: IP3 and DAG
o IP3 travels to the endoplasmic reticulum and opens Ca++ ligand gated channels
o Ca++ surge in cytoplasm triggers fusion of CORTICAL GRANULES
o Ca++ surge & raise in pH cause similar activation of egg metabolism as in sea urchin, initiating cell
cycle, DNA replication and protein synthesis

SPERM CAPACITATION
newly ejaculated sperm are not competent to fertilize an egg
o cells in the oviduct prompt sperm maturation = CAPACITATION
o sperm interacting with the oviduct are exposed to albumin and bicarbonate ions
o bicarbonate ions hyperactivate the flagellum à increased swimming by entry of Ca++ ions
attraction to egg
o THERMOTAXIS = heat gradient in female reproductive tract gives ‘direction’ to the swimming sperm!
o CHEMOTAXIS = progesterone is secreted by the cumulus cells around the egg