Concepts to understand

The flow of matter & information into and out of the cell

Living cells sustain gradients of ___ molecules and ions.

Diffusion tends to ___ gradients.
(Equilibrium at ΔG = 0)

However, gradients are not ___ restored in cells.

Lipid bilayer is a ___ barrier.
->Large ___ molecules and ions are BLOCKED from passing through.

SIMPLE DIFFUSION

favors ___, ___ molecules

Simple diffusion is ___ (uses no energy, moves down the concentration gradient)

What molecules tend to undergo simple diffusion?

Passive/Facilitated diffusion

-Large molecules, including polar, and ions can pass through ____ proteins, such as pores (____) or channels (animals) and transporters (___ ____).

Transmembrane proteins that transport a SINGLE solute type is a ____

Passive Facilitated Diffusion

Carrier Proteins
-Solute binds on one side; ____ change occurs; then lets go on other side
-Often carry ONE type of molecule

EX: passive ___ transporter (__)

Channel Protein
-Solute moves due to ___
-When ions are transported, these channels are called ___ channels.
->They are specific to __ & __

Example of a voltage-gated channels = opening of ___ channels

Neural signal ____ due to the opening of sodium channels.

SUMMARY So far

___ ___: no use of energy & moves along the gradient

Simple diffusion: moves ___ through the cell membrane

____ diffusion: Transmembrane proteins

____ : Transmembrane protein that transports a single solute type

Next
Active transport: use of energy & moves ____ the gradient

Membrane Potential
(___ across the membrane)

Cell is like an electric battery.
Cell is __ inside & __ outside.

Δψ : from -40 to -70 mV

ΔG = zFΔψ
z = charge
F = Faraday's constant

Δψ < 0 and F > 0 and ΔG < 0 when z __ 0

Membrane Potential is sustained by ___ /__ pumps

_ N+ out & _ K+ in with a +1 charge transfer per pump cycle

Cell generates 3 ΔG sources:
1)
2)
3)

Sodium/Potassium Pump is the example of ___ Transport

It is active, because ions move ___ their gradient (ΔG initial __ 0)

However, A LOT of ATP energy is used (ΔG ATP __ 0) so total (ΔG total __0)

Class Clicker Question

How does membrane potential, V= -70 mV, change if a significant number of Na+ channels (transporting only sodium) synchronously open?

A. will decrease, more negative
B. will increase, more positive

PRIMARY Active transport = when a ___ emergy source is used (__ or __)

SECONDARY Active Transport =

when the energy of ion ___ is used

*Primary energy source (ATP) creates the secondary energy source (__ ___).
->This energy is used to move cargo across the membrane.

Symport = two molecules move in ___ direction (move __)

Antiport =
Sodium/Calcium transporter

Two molecules move in ____ directions

This is active transport because the energy of the Na+ ___ is used.

Endocytosis = ___ large molecules and particles

Exocytosis = ___

Transduction of extracellular signals

Transduction = ___ of signal or energy from one form to another

Lateral diffusion = __ (communication)

Transverse diffusion = ___

Signal Transduction

___ = primary messenger & binds to

a receptor on the outer membrane surface

____ = on outer membrane surface
->SPECIFIC to the ligand
->Undegoes a conformational change
->SIgnal transduction
->Second messenger
->Amplification

Pathways =
Often ___ cell response
Complex interactions

G protein-coupled receptors (GPCR)

-Large family of protein receptors

-Ligand binds to receptor -> conformational change -> signal passed

Structure of GPCR = transmembrane __-___ and are couple to __ - proteins

G proteins (different types) are GTPases that ___ GTP

GTP becomes ___

Another example of a GPCR is the:

Adenyl Cyclase signaling pathway

Primary messengers (hormones) bind to GPCR and then G-proteins become activated and can either activate or inhibit adenyl cyclase (AC)

Second messenger = cAMP (___ the signal)

The adenyl cyclase signaling pathway

Phosphodiesterase = ___ cAMP (becomes AMP)
*It is important to be capable of turning __ the signal.

Caffeine __ the inhibitor and this results in __ signal action.

cAMP

_ cAMP molecules must bind to the regulatory sites on the inactive complex to activate the ___ subunits

->This activates protein __ __

Tyrosine Kinase Pathway

-Ligand binding causes ___

-Each kinase ___ its partner (auto___)

-Phosphorylated dimer becomes ___

Insulin receptor is an example of a tyrosine kinase receptor

-Tyrosine kinase domains catalyze phosphorylation of proteins called insulin receptor substrate (IRS) to further produce secondary messengers (PIP3).