Block 1 Review Study Slides PDF

Summary

This document provides study slides for a molecular biology and genetics course, covering topics such as cell structures, cell signaling, and the cell cycle.

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Block 1 Review:
Study Slides
BMS 532 MOLECULAR BIOLOGY AND GENETICS
BLOCK 1 REVIEW SLIDES FOR STUDY ASSISTANCE
Overall Study Aids: An Example of Functional Summaries
Molecule or Activity/Area of Impact If upregulated or activated If downregulated or inactivated
Structure
MAD2 Signal that indicates an MAD2 present = Kinetochore is unattached Attached Kinetochores = GO for
unattached kinetochore The cell should NOT progress THUS if anaphase
(soluble version = upregulated or activated: mitosis will STOP Loss of MAD2 = loss of regulation
unattached) NO MAD2 = mitosis will GO
CDC20 Rate-limiting for APC If available and able to bind APC, cell is GO If unavailable (i.e. bound to MAD2,
activity for anaphase cell will STOP (no anaphase)
THUS more CDC20 or activated CDC20 THUS loss of CDC20 will stall the cell
should make the cell GO
EXCEPTION: Functional MAD2 that can bind
will BLOCK
DREAM Suppress E2F DREAM forms and blocks E2F transcription = No DREAM = potential for E2F-
transcription no G1 to S progression; if more = cell stuck mediated transcription
in G1 Loss of DREAM = potential for S
phase
Arp2/3 Actin nucleation and More Arp2/3 = more potential for actin No or less Arp2/3 = less
branching polymerization and branching polymerization and branching =
reduced motility
BCL-2 Suppress apoptosis More BCL-2 = less apoptosis Less BCL-2 = more apoptosis
Review of Cell Structures
Cell Structure Function Additional Considerations

Rough Endoplasmic Reticulum Synthesis and processing of Close association with ribosomes;
proteins needed at plasma important for synthesis of
membrane and for export excreted proteins
Smooth Endoplasmic Reticulum Metabolism and detoxification of Expanded in cells responsible for
exogenous proteins detox or processing of toxins

Golgi Apparatus Processing (sorting and exporting) Impairment or loss would impact
vesicular trafficking
Mitochondrion Energy Required for cellular replication
and maintenance of cell energy
Lysosomes Degradation of material Required for autophagy and
recycling
Vesicles Transport of material Required for movement to and
from plasma membrane and
between organelles
Vesicular Trafficking
Definitions
◦ Anterograde: rER to Golgi to plasma membrane
◦ Retrograde: backward (plasma membrane back toward organelles or to lysosome; Golgi to rER)

Compare and Contrast
Anterograde Retrograde
Kinesin Dynein
COPI, COPII, Clathrin COPI
**the only coating that would enable
movement in both directions would be
COPI
Microtubules Microtubules
 Minimal Threshold Model

G1 to S During S G2 to M During M
Cyclin E/CDK2 Cyclin E/CDK2 Cyclin A/CDK1 or Cyclin B/CDK1
CDK2
Hochegger et al 2008,
Nature Reviews
Overview of Regulation
Players that PROMOTE division/proliferation
◦ CDK activity regulated by cyclin availability
◦ E2F transcription
◦ Hyperphosphorylation (Rb and others)

Players that SUPPRESS division/STOP division
◦ p21
◦ DREAM
◦ Hypophosphorylation
◦ Lack of CDK activity due to lack of cyclins
7
Mitosis Summary
Stage Details Additional information
Prophase Chromosome condensation and spindle General stage at which cytoskeletal issues
formation would stall the cell; stage of chromosome
condensation
Prometaphase Chromosomes begin to associate with Variable and frequently not included in the list
spindle fibers of stages; associated with the movement of
centrosomes and nuclear envelope
breakdown
Metaphase Alignment of chromosomes at Checkpoint prior to chromosome segregation;
metaphase plate (equator) role of Anaphase promoting complex
Anaphase Separation of chromosomes Breakdown of cohesion precipitates sister
chromatid separation
Telophase Chromosome arrival at the poles Nuclear envelope reforms and chromosomes
decondense; failures in cytokinesis would stall
the cell here
Cytokinesis Division of cytoplasm Requires actin, myosin, and microtubules
Meiosis Summary
Stage Details
Prophase I Chromosome condensation, nuclear envelope breakdown; beginning of chromosome
association with spindle fibers; Crossing-over
Metaphase I Alignment of chromosomes on metaphase plate; entirely random but enables segregation
of homologous chromosomes
Anaphase I Separation/segregation of homologous chromosomes in duplicated form
Telophase I Chromosomes arrive at poles; breakdown of spindles; (variable decondensation and
nuclear envelope reformation); daughter cells include 1 copy of each duplicated chrom.
Interkinesis Space between division phases; spectrum of consequences with some cells entirely
decondensing chromosomes and reforming the nucleus and others skipping this entirely
Prophase II Resembles prophase and prophase I; new spindles are required
Metaphase II Chromosome alignment on metaphase plate randomly
Anaphase II Sister chromatid separation
Telophase II Chromosomes arrive at poles; reform nuclear envelope and decondense
Cytokinesis Identical to mitosis except daughter cells are haploid with 1 copy of each chromosome
Contractile Ring Formation
The players in focal adhesion
formation are responsible for creating
contractile forces and the contractile
ring is a type of contractile force
Positioning of the ring is determined
by signals or activity of microtubules
◦ Concentration of signals and responses
determining location of contractile ring
◦ Past divisions can influence positioning
 Division of Cytoplasm: Cytokinesis
In typical somatic mitosis, the division is nearly perfectly in
half with each daughter cell receiving half the cytoplasmic
contents
In embryogenesis, asymmetrical cell divisions are possible
enabling concentration of materials into one of the two
daughter cells generating concentration gradients

Polarity in cells can be generated via asymmetrical cell
division
This enables the development of cells that are unique in
materials and gene expression
◦ Part of morphogenesis and specialization of cell types

Berricka et al 2014 Rose and Gonczy 2014
Oogenesis
Oogenesis is a complex process with much
remaining poorly defined or understood
During oogenesis of humans prenatally there is a
large loss of cells
◦ Selection methods are unknown and remain of
significant interest in fertility studies
Overall, during oogenesis, there are 2 distinct
pauses in meiosis
◦ 1. pre-puberty the process arrests at prophase I of
meiosis
◦ 2. after-puberty but before fertilization the cell
arrests at metaphase II
Ovulation leads to release of the arrest oocyte
where meiosis can continue in conjunction with
fertilization
Linking this block to human disease and
the next block…
Variation at the genetic level that impacts cellular behavior and function is the basis of human
disease
Proteins exhibit their effects and consequences of their activities are observed at the cellular
level
Changes in signaling, growth, differentiation, or apoptosis:
◦ Pathogenic if the variation increases growth or reduces differentiation or apoptosis
◦ Benign if changes do not alter overall cellular activity or tissue behavior
◦ Unclear/Uncertain if the link has not yet been established or the consequence not yet fully understood
LO1, LO2

Necrosis vs. Apoptosis
NECROSIS Apoptosis
Harmful to NOT harmful
neighboring to neighboring
cells due to cells due to
leakage of controlled
cellular management
contents Activity of
Changes in DNA nucleases
ions, destroys DNA
osmolarity, in an
and pH organized
Can begin with fashion
signaling and Can be
mitochondria triggered and
but ends will involve
differently mitochondria
to carefully
deal with cell
contents
LO1, LO2

More on Autophagy
Macroautophagy General Stages
Upstream Signal
Membrane Nucleation
Elongation and closure of autophagosome
Fusion with lysosome
Degradation and Release of Contents
 Actin vs Microtubules
ACTIN MICROTUBULES

1. Polymerization of actin monomers requires 1. Polymerization of alpha-beta tubulin
ATP hydrolysis dimers via GTP hydrolysis
2. Initiation and nucleation via Arp2/3 (also 2. Requires APC to associate with focal
needed for branching); APC helps with adhesions and ACF-7 for crosslinking with
polymerization of actin filaments actin; extend TOWARD periphery in
movement
3. Generates protrusive forces and resists
compressive forces 3. Generates contractile forces and plays a
key role in defining polarity
4. Helps generate and maintain cell geometry
◦ Role in structural integrity 4. Also plays a role in cell geometry
(organization matches geometry)
**Alterations of actin and especially actin associated
**Alterations in tubulin impact migration and structural
proteins most profoundly impact motility and migration
development
LO5
The 4 Pillars of Cellular Migration in
Embryogenesis
Polarization
◦ Gives directionality to the movement
◦ Defines front from back (**Microtubules play a role here)
Protrusion
◦ Actual start of movement/migration
◦ Involves leading edge and polymerization of actin (**Actin will typically be BRANCHED as a network in
mesenchymal migration and lamellipodia; PROTRUSIVE FORCES HERE)
Adhesion
◦ Attachment to surrounding matrix via integrins and formation of focal adhesions
◦ Gives cell pushing off force (**APC attachment of microtubules at focal adhesions plays a role here;
CONTRACTILE FORCES HERE)
Retraction
◦ Release of adhesions at the rear to enable forward movement (Movement/Forward Momentum due to
release of CONTRACTILE force)
LO1, LO2

Signaling Pathway Basics
Post-translational modifications of proteins are critical to the function and activity of signaling
pathways

Termination
Initiation Propagation
and Reset

Receptor dimerization Signal Mediators Recycle receptor
and Degrade proteins
autophosphorylation Build new proteins
for next activity
Each step in a pathway can serve as a point for regulation of the pathway
◦ Enzymes represent a key means of controlling the rate and progression of the reactions
19
Cell Signaling OVERVIEW
Pathway leads to growth (mitogenic)
Pathway leads to death (apoptotic)
Pathway leads to movement (migration or motility)
Pathway leads to specialization (role in development or differentiation)
Pathway triggers more than 1 activity (typical for growth stimulatory in development or
embryogenesis)

All of the activities discussed in the block are linked to the activity of cell signaling!
General MAP Kinase Signaling
Kinase signaling involves changes in
phosphorylation along a pathway
Multiple kinases are involved with specificity
for the next kinase in the pathway
Often exhibit overlap and cross-talk with other MAP = mitogen
pathways activated protein

Growth factor signaling is a form of MAP
kinase signaling

ALL MITOGENIC SIGNALING IS GROWTH
STIMULATORY!!

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The pathways…
Using your general knowledge of signaling and given a pathway, you should be able to:
◦ Explain what “upstream effectors” are and how they initiate a signal
◦ Determine what component would generate the described change to a signaling pathway
◦ Identify mediators and regulators
◦ Explain effects if a change to a mediator or regulator occurs
◦ Explain what changes could counteract a specific change
◦ Determine/define how “downstream effects” are generated (role of transcription factors)
◦ Explain the role of domains in signaling and the consequence of losing domains