Comprehensive Study Notes PDF

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This document contains comprehensive study notes covering topics such as cell biology, including modules on SGLT inhibitors, resting potential, and muscle contraction, among other concepts. It likely serves as a study aid for biology students.

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Comprehensive Study Notes
Module 4
SGLT Inhibitor: Used to treat type 2 diabetes.

GLUT2: Low affinity (usually), active (usually out of cell).

GLUT2: Facilitates glucose release into the blood or brings it inside the cell.

Module 5
Resting Potential: Refers only to excitable cells.

Effectively impermeable due to potassium (K+) leaking out, causing sodium (Na+) channels
to remain closed.

Saltatory Conduction: Depolarization jumps from one node of Ranvier to the next along a
myelinated axon.

Ca2+ ATPase: Pumps calcium ions back into the sarcoplasmic reticulum.

Transmitter-gated channels convert chemical signals into electrical signals.

Neurotransmitters facilitate ion channels, and the voltage sensitivity of these channels
affects membrane potential.

Module 7
A-type Lamin: Encoded by LMNA gene.

Two types of nuclear lamin: A and B.

EDMD (Emery-Dreifuss Muscular Dystrophy): Affects skeletal and cardiac muscles, leading
to bradycardia and heart failure.

Hutchinson-Gilford Progeria Syndrome (HGPS): Affects pediatric patients and is associated
with early aging.

Module 8: Actin Polymerization
Nucleation: Slow formation of actin filaments, leading to a steady state where both ends
grow at the same rate.

Hydrolysis: Conversion of ATP-bound actin (T-form) to ADP-bound actin (D-form),
promoting depolymerization.
Actin-Related Protein (ARP): Catalyzes polymerization at the minus end to allow elongation
at the plus end.

Critical Concentration (Cc): If actin concentration is lower than Cc, no growth occurs. If
higher than Cc, growth occurs.

Steady State: Both ends of the actin filament remain balanced.

Dissociation Constant (Kd): High Kd corresponds to high free energy, which destabilizes the
filament.

Module 8: Accessory Proteins & Microtubules
Accessory Proteins: Link filaments to other cellular components.

Tubulin Dynamics: Alpha-tubulin does not break down (- end), but beta-tubulin undergoes
hydrolysis (+ end).

Dynamic Instability: Microtubules grow and shrink rapidly.

Treadmilling: Actin filaments add subunits at one end while removing from the other.

Catastrophe: Rapid shrinkage of microtubules, followed by rescue when growth resumes.

F-Actin: Filamentous actin that arranges from head to toe. G-Actin: Globular actin subunits.

Module 9
Profilin: Moves actin from the thymosin pool to the plus end, promoting filament growth.

Cofilin: Disassembles old actin filaments (ADP-bound) to allow new actin to form.

Stathmin: Reduces the rate of elongation.

Gelsolin: Facilitates actin filament dynamics by binding to the plus end and promoting
depolymerization.

Intermediate Filaments: Non-polar structures that provide structural support to cells.

Vimentin-Like Proteins: Provide support to muscle cells by stabilizing intermediate
filaments.

Microtubule-Severing Proteins: Disassemble microtubules and promote the formation of
new ones.

Tropomodulin: Caps the minus end of actin filaments, preventing disassembly and
stabilizing the filament.
Module 10: Motor Proteins
Kinesin: Responsible for anterograde transport (toward the plus end) and is ATP-
dependent.

Dynein: Responsible for retrograde transport (toward the minus end) and is the largest and
fastest motor protein.

Troponin: Binds to calcium (Ca2+), allowing myosin to bind to actin by moving tropomyosin
out of the way.

Power Stroke: Occurs when myosin releases ADP and phosphate, causing muscle
contraction.

Myosin: Has speed but lacks processivity, unlike kinesin and dynein which are processive.

Rigor State: Myosin is tightly bound to actin without any attached nucleotide, causing a
locked conformation.

Skeletal Muscle Fibers: Composed of large cells formed by the fusion of multiple precursor
cells.

ATP Hydrolysis: Causes the myosin head to enter a cocked conformation, ready for the next
movement.

Action Potential: Prompts the opening of T-tubules, essential for nerve and muscle cell
activation.

Module 10 (Continued)
KRPs (Kinesin-Related Proteins): Dependent on ATP for movement. The release of ATP
causes movement.

M Line: Attaches to Myosin II.

Kinesin Tail: Determines the cargo being transported.

Module 11: Dynein and Cell Movement
Dynein: Bending action in flagella and cilia, responsible for retrograde transport.

Axoneme: Structure involved in flagella/cilia movement, dynein "bridges" facilitate sliding.

Basal Bodies: Found on the cell surface, anchor cilia and flagella.

Cell Movement Structures
Lamellipodia (2D Movement): Involved in cell movement. Lamellum is the more stable
region behind the lamellipodia.
Filopodia (1D Sensing): Involved in cell migration, neural outgrowth, and wound healing.

Kinesin and Dynein
Kinesin: Transports cargo toward the axon (anterograde).

Dynein: Transports cargo toward the cell body (retrograde).

Microtubule Dynamics
Dynamic Instability: Rapid growth and shrinkage of microtubules.

Platelet Activation: Involves severing, uncapping, elongation, recapping, and cross-linking of
filaments.

Gelsolin: Necessary for actin filament severing, activated by PIP2 and Ca2+.

Microtubule and Actin Behavior
Microtubules: Show dynamic instability (growth and shrinkage).

Actin Filaments: Exhibit treadmilling (disassembly at one end, assembly at the other).

Minus and Plus Ends
Minus Side: Directed toward the centrosome, delivering cargo to the center.

Plus Side: Directed toward the cell periphery, involved in growth.

Troponin (Muscle Contraction)
Troponin binds to calcium, facilitating muscle contraction.

Module 10: Kinesin, Dynein, and Muscle Contraction
Kinesin: Responsible for anterograde movement, ATP-dependent.

Dynein: Responsible for retrograde movement, the largest and fastest motor protein.

Troponin: Binds to Ca2+, allowing myosin to bind to actin by moving tropomyosin.

Power Stroke: Myosin releases ADP and phosphate, causing muscle contraction.

Myosin: Lacks processivity but has high speed. Kinesin and Dynein, on the other hand, are
processive.

Rigor State: Myosin binds firmly to actin in the absence of a nucleotide.

Opposing Head Movement: Sliding of myosin through muscle filaments.

Contraction of Skeletal Fibers: Large muscle fibers result from the fusion of multiple
precursor cells.
Sarcomere: Comprised of plus ends with Z-filaments.

ATP Hydrolysis: Causes the myosin head to enter a cocked conformation, essential for
movement.

Action Potential: Prompts the opening of T-tubules, necessary for nerve and muscle cell
function.

Module 9: Actin Dynamics and Microtubules
Profilin: Moves actin from the thymosin pool to the plus end, facilitating polymerization.

Cofilin: Dissolves old actin filaments to make new ones using ADP.

Stathmin: Reduces the rate of elongation by binding to tubulin dimers.

Gelsolin: Regulates actin dynamics, binding to the plus end to promote severing.

Capping Proteins
CAP2 (Tubulin): Stabilizes the plus end of microtubules.

MAP (Microtubule-Associated Proteins): Stabilize microtubules and prevent disassembly,
aiding in microtubule formation.

ARP Complex (Actin-Related Proteins)
Nucleates actin filament growth.

Intermediate Filaments
Vimentin-Like Proteins: Provide muscle cell support through intermediate filaments, which
lack polarity.

Microtubule-Severing Proteins
Sever microtubules to create new microtubules and facilitate turnover.

Tropomodulin
Caps the minus end of actin filaments, preventing disassembly and stabilizing the structure.

Module 8: Accessory Proteins and Microtubule Dynamics
Accessory Proteins: Link filaments to other cell components, providing structural support.

GTP (Tubulin): Tubulin α-subunits are never broken down, while β-subunits break down
via hydrolysis.

Actin Treadmilling: Actin grows at one end and disassembles at the other, maintaining a
steady size.
Dynamic Instability: Refers to microtubules’ ability to rapidly grow and shrink.

Steady State: Equilibrium where the loss and addition of subunits are balanced.

Catastrophe: Refers to the shrinkage of microtubules, while Rescue refers to their regrowth.

Nucleotide States of Actin and Tubulin
T-Form: Bound to ATP (actin) or GTP (tubulin).

D-Form: Bound to ADP (actin) or GDP (tubulin).

Microtubules
Involved in intracellular transport and segregating chromosomes during cell division.

Intermediate Filaments
Fibrous, provide structural support for cells.

Actin/Myosin
Globular proteins that work together in muscle contraction.

Microtubule Nucleation
Occurs at the γ-tubulin ring complex, which serves as a nucleation site for microtubules.

Branching Nucleation
Branching occurs from pre-existing cells to make new actin filaments.

Module 4: GLUT Transporters and SALT Inhibitors
SGLT Inhibitors: Used to treat type 2 diabetes by reducing glucose reabsorption.

GLUT2: Lower affinity glucose transporter that releases glucose into the blood.

GLUT2: Typically active when glucose is moved out of the cell.

Module 5: Resting Potential and Voltage Gated Channels
Resting Potential: Refers only to excitable cells where membrane potential remains stable.

Effectively Impermeable: Due to potassium leakage channels.

Saltatory Conduction: Depolarization travels along a myelinated axon by jumping between
nodes.

Voltage-Sensitive Channels
Ca2+ ATPase: Pumps calcium ions back into storage to restore resting potential.

Neurotransmitter-Gated Channels: Facilitate ion flow to alter membrane potential.
Module 7: Nuclear Lamin A and Laminopathies
A-type Lamin: Encoded by the LMNA gene and has three forms (A, B, C).

Associated Conditions: Skeletal and cardiac defects like bradycardia and heart failure.

Hutchinson-Gilford Progeria Syndrome (HGPS): A condition affecting pediatric patients,
characterized by accelerated aging.