Neurons and Glia, Synaptic Transmission, and CNS Pathways Flashcards
How many neuronal cells are in the brain? which has more cells, Gray or white matter? Which makes up the bulk (volume) of brain?
There are over 80 billion neuronal cells in the brain
GRAY matter has more neuronal cells in brain
Gray matter- 86 billion cells
White matter: 84 billion
white matter has Greater volume and makes up bulk, LARGER portion of brain
which kind of glial cells take up almost half of our brain’s total volume?
ASTROCYTES (bigger than neurons)
what are the types of Glial cells in the central nervous system?
Types of Glial cells in the CNS:
1. Astroglia
2. Oligodendroglia
3. Microglia
4. Ependymal cells
Which of the glial cells are the most numerous?
ASTROCYTES
Describe the characteristics for astrocytes, Oligodendocytes, Ependymal cells and Microglia
-Astrocytes: (projections to neurons/vasculature of brain)
1. Most NUMEROUS
2. regulate chemical environment of extracellular space (space between glial cells and neuron )
-a. potassium and other ions
b. neurotransmitter uptake and metabolism
3. have neurotransmitter receptors (react to release of neurotransmitters)
4. Part of Blood/brain barrier (allows for some things to get out of blood vessel and into nervous system; vice versa)
-Oligodendrocytes-
1. create Layers of membrane (myelin) that insulate axons
a. Node of Ranvier- (break in myelin sheath; uninsulated portion)
insulation of axon facilitates electrical Impulse along axon. (myelin sheath facilitates speed of transmission of axon and signal jump from node to ranvier)
-Ependymal Cells:
1. Line fluid cavities of the brain- Ciliated
-(help move fluid along space)
-Microglia
1. Phagocytic cells to gobble up debris-dying neurons, etc
(keep brain free of debris)
How much of brain do glial cells make up?
glial Cells make up 1/2 of brain (glial largest portion of brain; volume)
What does a typical neuron consist of?
Typical neuron consist of Cell body, dendrites, Axon and Terminal Bulb,
What are the roles of cell body, axon, dendrites and terminal bulb?
Cell body- central part of neuron that contains nucleus and process information from dendrites
Axons- long nerve fiber that transmits electrical impulses away from cell body (neuron) and towards another neuron
Dendrites- branches on neuron that accepts information from other neurons and transfers it along axon (bring info to the cell body)
terminal bulb- endpoints or knobs at end oi neuron that release neurotransmitters
What is a synapse?
Synapse- gap between 2 neurons
What are the basic types of Neurons?
Basic Neuron Types
1. Bipolar (interneuron)- one dendrite and one axon (at opposite poles)
2. Unipolar (sensory Neuron)-ONE axon that extends into its dendrites (seen in sensory neuron, spinal cord)
3. Multipolar (Motor Neuron)- one axon, multiple dendrites (collect info from different dendritic inputs)
4. Pyramidal cell- pyramid shape that have two distinct trees and apical dendrites and basilar dendrites (a form of multipolar neurons)
Describe the main components of a cell and their roles. Which parts of the cell or neuron needs a lot of energy?
Main components of a cell:
-Nucleus- transcription (DNA)
-Rough ER (endoplasmic reticulum) - Abundant; site of protein synthesis - outer membranes
-Free ribosomes- (polyribosomes)
-site of protein synthesis- cytosol
-Smooth Endoplasmic reticulum
-protein folding
-calcium balance, storage and release
Golgi apparatus-
-posttranslational processing of proteins
-sorting and distributing of proteins to different locations- soma, axon, synapse
Mitochondria- (energy supply)
-Large number in soma
-large number in synapse
neurons need a lot of energy in nucleus for protein production
need a lot of energy at synaptic end of neuron for release and reuptake of neurotransmitters
Describe the unique structures in a neuron and their roles
Unique structures of a neuron:
1.Soma- centralized portion (gives rise to dendrites)
2. Cytoskeleton- gives shape to neuron (maintain structure of axons and dendrites)
3. Axon- unique to neurons (mm to one meter long
-transmit electrical signals from soma to synapse over short or long distances
-protein composition of axons is different than Soma membrane
4. Dendrites- have polyribosomes- local protein synthesis occurs
-dendritic spines- (protrusions, )serve as site of information transfer (from one neuron to another)
Synapse- Site of electrical or chemical transmission
what are the specialized design features for neurons?
Specialized design features: Neurons
Unique gene products ; they produce proteins for neurotransmitter synthesis and packaging of neurotransmitter and receptor sub-units: give rise to cytoskeleton (maintains shape and structure of neuron)
-location of mitochondria (energy for soma, synapse) (distribution of mitochondria according to location)
-microtubules for structural support and axonal transport
-protein composition of membrane varies according to cell location:
free ribosomes- cytosolic proteins
Rough ER- membrane proteins
-cells have Heterogenous shapes and sizes
-Neurons are defined by their transmitters: acetylcholine- motor neurons
How are neurons defined?
Neurons are defined by their TRANSMITTERS
Describe the different features and components of an axon. What makes an Axon unique?
Axon contains:
1.Axon Hillock- where action potential is generated along axon to synaptic terminal
2. Nodes of Ranvier- sites of discontinuous myelin sheath from Oligodendrocytes
(sites where electrical signal jump from one end to another)
3. Axon terminal (bouton)- one of synaptic end that allows reuptake of neurotransmitter
4. Axon varicosities- enlargements along axon where neurotransmitters are synthesized, released and packaged
5. Axon collaterals and recurrent collaterals-
axon collaterals- branch of axon
recurrent collaterals- where axon branches and reinervates same cell or adjacent cell (modulate cell firing pattern)
Unique features for Axon - NO protein synthesis
-NO rough ER
NO free ribosomes
What are the components of cytoskeleton? what is the axon skeleton composed of ? What is Axon railway system ?
Cytoskeleton (elements that keep the shape of axons and dendrites ) composed of :
-Microtubules, neurofilaments and microfilaments
-Axon skeleton (structure) - microtubules (24 nm, tubule), neurofilaments (10 nm), and MICROFILAMENTS - that give neuron its SHAPE (5-7 nm; actin)
-Axon railway system- (Microtubules) transport materials along axon between soma and synapse
What are the two main types of axonal transport ?
Types of Axonal Transport:
- Fast axonal transport- occurs at a rate of 20-40 mm/day (RAPID, ACTIVE process)
-Fast Anterograde transport- (up top 400 mm/day; from soma to synapse)
- carries organelles, enzymes, synaptic vesicles and small molecules
-fast Retrograde transport (from synapse back to soma)
-for recycled materials and pathogens; rabies, herpes simplex, tetanus, polio viruses (from synapse back to soma)
-delay between infection and symptoms is time needed for transport up the axon
Slow axonal transport or AXOPLASMIC FLOW- 0.5 to 10 mm/day
-always ANTEROGRADE (soma to synapse)
-slower process
-moves enzymes, cytoskeletal components, and new axoplasm down the axon during Repair and Regeneration of damaged axons
-Damaged nerve fiber regenerate at a speed governed by slow axonal transport
what are the two types of proteins seen during axonal transport? are they part of retrograde or anterograde transport?
proteins: Kinesin and dynen
1. Kinesin- has synaptic components, cytoskeletal structures and ion channels
-have carrier system that uses ATP to walk cargo from soma to synapse
-ANTEROGRADE Transport
2. Dynein- has cargo for degradation, and neurotrophic signals
-moves from synapse back to soma
-RETROGRADE Transport
these transport proteins need ATP to carry cargo.
Describe the process of synaptic transmission
synaptic transmission process:
-store neurotransmitter in neuron
-release it from the nucleus
-this impulse will travel down the axon
-this prompts synaptic vesicles (contain transmitters) to migrate to pre-synaptic membrane
-fusion with membrane and dumping of transmitters located vesicles into synaptic cleft
transmitter migrate across synaptic cleft and activates dendrites of post-synaptic membrane.
describe the cell morphology seen with purkinje cell, pyramidal cell, and motor neuron of spinal cord
Purkinje cell- (seen in cerebellum); dendritic tree where cell can integrate information from many different channels
Pyramidal cell- apical dendritic tree, basilar set of dendrites, single axon
motor neuron of spinal cord- cell body, dendrites, single axon that travel Long distances to muscles (to activate muscles to carry out motor functions
How can information be processed when viewing cross-section of spinal cord? What is important for processing information in spinal cord ?
information enters to dorsal portion of spinal cord and ascends to higher level;
info travels down Spinal cord to ventral portion that innervates motor neuron (sends axon to muscle)
-*even at level of spinal cord there is CIRCUITRY involved in processing information in ascending and descending portions of spinal cord (using inhibitory (interneuron) and excitatory neurons activate circuit
Describe the different channels that are on Neuronal membranes
Neuronal membrane:
1. Na+ K+ ATPase (pump): maintains the balance between sodium and potassium outside and inside cell(has enzyme that maintains [ } gradient)
2. Receptors - are the target of different kinds of neurotransmitter molecules (like peptides, Amino acids, catecholamines.
-catecholamines- activate receptor and cause inhibition/activation of the cell.
3. Na+ channel: pore In the membrane: when channel is open, allows flux of Na+ ions to go from out of cell to inside cell, creating voltage change (basis for activating psot-synaptic neuron)
4. K+ Channel- which when open, allows for efflux of K+ ions( to go from inside to outside cell) leafing to voltage change
5. Cl- Channel- that changes voltage of membrane (with efflux of Cl- ions) and gives rise to activation of electrical synaptic cell
There are also Transmitter receptors, transmitter reuptake pumps, ligand gated or voltage gated ion channels.
Which two categories do transmitter receptors fall into? How do they work
what is role of transmitter reuptake pumps?
Transmitter receptors:
1. G protein Coupled receptor-
INDIRECT ACTION - to change excitability series of steps, use secondary messengers.
ligand binds to channel, which activates or inhibits adenylate cyclase (convert ATP to cyclic AMP) Cyclic AMP is used as a second messenger inside cytosol. cAMP can do different things
-ligand binds to receptor, which triggers sequence of events that shuts down or stimulates the production of Cyclic AMP, which then acts as second messenger, causing an action in cytosol and affects excitability of neuron
- Ligand gated Ion channels-
DIRECT ACTION- flux ions across membrane
Ligand bind to receptor on channel cause physical change in channel structure , allowing flux of ions across membrane
ex: GABA (gamma-amino butyric acid)- amino acid transmitter activating Cl- channel on post-synaptic membrane
-GABA is released and binds to Cl- gated channel (ligand-gated), causing conformational change in protein.
Transmitter reuptake pumps-, used to terminate neurotransmitter action and take neurotransmitter back into where it came from, after it was released; to be reused and restored in future
What is the role and function of GABA (gonna-amino-butryic acid)
GABA- Universal inhibitory transmitter in the brain
-Has INHIBITORY action on cells
-GABA is an example of ligand that binds to receptor (ligand-gated ion channels)
GABA (gamma-amino butyric acid)- amino acid transmitter activating Cl- channel on post-synaptic membrane
-GABA is released and binds to Cl- gated channel (ligand-gated), causing conformational change in protein. channel not activated pore is closed.
When channels are activated by GABA binding to channel, it opens pore and allows Cl- to go from outside of cell, into the cell. Cl- enters cell, creates high negative charge inside cells, causing Hyperpolarization which moves it further away from the ability to dishcharge action potentials
Describe the action of second messengers like cyclic AMP
Second messenger action
Cyclic AMP: has many functions; can change responsiveness of cell to second transmitter;
activation of Phospholipase c , which converts phospholipase to IP3 (another second messenger) , affecting the excitability of cell; whether stimulating or inhibiting.
glutamate -amino acid transmitter
bind to channel and allow for transmission of Na+ ions across membrane. Sodium ions would depolarize membrane and move it closer to excitability threshold
What is an example of another amino acid transmitter? How does it differ from GABA?
Glutamate - amino acid transmitter that
binds to channel and allows for transmission of Na+ ions across membrane.
Sodium ions will Depolarize membrane and move it closer to excitability threshold
(GABA does opposite, hyperpolarizing membrane (due to Cl-)
what are the cellular elements of the nervous system?
Neurons and Glial cells.
Neurons-> cells-> Circuits-> Networks
How can you characterize the properties of individual neurons?
What is one major characteristic about neurons?
How does this relate to a rat and its whisker system?
Anatomical , biochemistry (what transmitters are produced) , physiology (whether excitatory or inhibitory neurotransmitter will be released)
sensory neuron- what kinds of shapes or colors might it respond to
Molecular level- what drives protein synthesis of this cell from an other neuron
- individual neurons form circuits (they do not operate alone
-circuit in cerebral cortex of rat brain - portion of cortex that processes sensory info from periphery
-slab of sensory cortex that responds by moving whiskers to capture information about its environment (how big is space he’s in, if wall is present) whisker system for rodent is sensitive, and their primary mode of navigating the world.
these cells constitute circuit, code information from single whisker
circuit is part of larger network
-defined number of whiskers in rows and columns
info transferred from sensory array of whiskers to transgeminal complex, transfers it to thalamus, give rise to cells in cortex and Locus Coeruleus
-network of cells and connections that inform rat about position of whisker.
rat has info about periphery, which informs rat about its behavior (change its position )
