Knowt
NBL Module 13
Video Lecture 1
LTP expression requires calmodulin and CaM Kinase II
LTP early phase requires activation of specific kinases downstream of the calcium that is entering into the postsynaptic region via the NMDA receptors
Kinases- include several directly activated by Calcium or indirectly activated by Calcium
One of the kinases activated by Calcium is CaM K2- calmodulin dependent Kinase II
Binds to Calmodulin
Calmodulin- type of adaptor protein
Has 4 calcium binding domains
Interacts with specific targets and leads to their regulation
One of the targets is Cam Kinase II
Fairly small protein, binds 4 atoms of calcium
When calcium level rises postsynaptically, it undergoes a conformational change.
Allows it to interact with targets like CaM KII
Cam KII has a regulatory domain and a catalytic domain
This is where the kinase domain is present
In the absence of activated calmodulin, CaM KII is autoinhibited
Cannot interact with and phosphorylate its substrate
When Calcium levels rise and bind to Calmodulin, Calcium calmodulin and interact with and activate CaM K2
Binds to regulatory domain and releases catalytic domain
Now it’s able to phosphorylate its specific targets
These targets include proteins like AMPA receptors and proteins involved in the trafficking and tethering of AMPA receptors in the postsynaptic region
Protein Kinase C, Protein Kinase A and ERK kinase
Have several complicated levels of regulation
Protein Kinase C binds Calcium and other cofactors
PKA is regulated indirectly through activation of cAMP levels downstream of Calcium and Calmodulin
ERK proteins- have very complicated mechanism of activation
These 3 protein kinases are also activated in the postsynaptic region downstream of Calcium entry into the postsynaptic neuron
These protein kinases all lead to the regulation of AMPA receptors
Protein kinases regulate AMPA receptors directly or indirectly
Directly- kinases lead to direct phosphoryulation of AMPA receptor alpha subunits
This modulates signal channel conductance- increases Calcium and Sodium ions that can flow through these channels in response to glutamate binding
Can also increase the density of AMPA receptors in postsynaptic region
Increase level of AMPA receptors through trafficking of receptors into plasma membrane and can also lead to tethering of receptors present in membrane and prevent their removal into endosomal pool
These functions lead to increased AMPA receptor numbers and AMPA receptor activity
In response to glutamate, it’s the AMPA receptors that mediate the majority of the postsynaptic response
By increasing AMPA receptors→ leads to direct increase in postsynaptic EPSP produced in postsynaptic neuron
Kinases can directly phosphorylate AMPA receptors and this leads to a change in the AMPA receptor conductance
In addition, CaM KII can also phosphorylate a set of proteins called TARPs
Transmembrane AMPA receptor regulatory proteins
One of the TARPS well characterized is a protein called stargazin- identified originally in mutant strain of mice
TARPs bind to AMPA receptors as they are trafficking
Following AMPA receptor biosynthesis and trafficking to and from the plasma membrane, what happens is by the phosphorylation of these TARP proteins, this leads to a tethering of the AMPA receptors that are localized at the postsynaptic region
Prevents endocytosis- there’s going to be a greater steady state level of AMPA receptors in the membrane
Protein kinase ERK leads to an increase in the exocytosis or insertion of AMPA receptors through trafficking mechanism
Enhances the number of receptors that are going to be inserted into postsynaptic plasma membrane
Both increase AMPA receptor activity and can lead to increase in steady state levels of these receptors at postsynaptic plasma membrane
Regulation of PKC and ERK kinases is very complicated
What is depicted is a very immediate effect of the activation of these kinases by the calcium-dependant mechanism
There are longer term effects in late phase of LTP
Primarily involve downstream targets of ERK kinase
Initial activation of protein kinases that leads to initial increase in postsynaptic response via increased AMPA receptors
ERK kinase can set in motion specific cascades involved in maintenance of specific increase of AMPA receptors
E-LTP: activity of presynaptic axons
Transmit APs- arrive at presynaptic terminus
Leads to release of glutamate from presynaptic glutamatergic neuron
Short term plasticity and longer-term effects- there can be an increase in the amount of glutamate release following the type of stimulation that induces LTP
Once the glutamate is released into synaptic cleft, it can bind to both AMPA and NMDA receptor
Initially the AMPA receptors that mediate the response, EPSPs allowing Sodium to flow into postsynaptic membrane and depolarizing it
At RMP, NMDA receptors have the Magnesium block
Even though they bind glutamate, they can’t participate in synaptic transmission
Once AMPA receptors have depolarized the membrane potential, that depolarization removes Mg block and NMDA receptors are activated by glutamate that has been bound to them
NMDA receptors are permeable to both Sodium and Calcium but it’s the Calcium increase involved in idnuction of LTP
Calcium leads to activation of 4 different protein kinases in postsynaptic neuron
CaM KII, PKC, PKA, ERK
Lots of target for these protein kinases that are phosphorylated in response to activation downstream of calcium signal
Early phase of LTP- lasts about 30 minutes between first 30 to 60 minutes
Involves transient Calcium signal
CaMKII and PKC are transiently activated
Once they do their job in phosphorylating their substrates, leads to downstream effects
Targets of these protein kinases in the early phase of LTP is the increase in AMPA receptor number and activity at the plasma membrane
Indirectly occurs by phosphorylation of AMPA receptor- tethering proteins and indirectly by AMPA receptor trafficking proteins
Initially, we have a number of AMPA receptors that mediate synaptic transmission at spine synapse
After repeated stimulation which is going to lead to induction and early phase of LTP- there is an increase in the number of AMPA receptors
AMPA receptors there bind glutamate better and produce greater responses when glutamate is bound
This produces a larger response after particular stimulation
There is also more glutamate released presynaptically- contributes to increase in response as well
Early phase of LTPs- this is an increase in synaptic strength and when we refer to synaptic strength, we refer to postsynaptic response
Though this was originally characterized electrophysiologically, we now know that there are many biochemical and morphological changes that occur
In LTP- lasts less than an hour, depends on activation of protein kinase activity- leads to increase in AMPA receptors
Following initial 30 min- 60 min, we have late phase of LTP
Additional biochemical mechanisms come into play- lead to long term potentiation of the particular response
LTD- similar features of LTP
Reversible, saturative, associative
Difference is what the stimulation was that leads to the long-term response
LTP- high frequency stimulation
Depolarization of postsynaptic membrane at same time there is glutamate being released into synapse
LTD- low frequency stimulation
Much lower number of inputs and input activity into postsynaptic
Also involves Calcium and it also involves NMDA receptor
Requires for induction activation of NMAD receptors and influx of Calcium
Major difference- much lower and sustained level of Calcium flowing into postsynaptic neuron
During lTD, there is release of glutamate by low-frequency stimulation, enough depolarization too activate some of the NMDA receptors
During LTD- influx of Calcium is much lower
Low level of calcium influx activates calcium dependent protein phosphatases
Remove phosphate from substrates
Same type of substrates that were phosphorylated by Calcium dependant protein kinases and Calcium activated protein kinases are phosphorylated by Calcium dependant protein phosphatases
Once phosphate is removed from AMPA receptor, this leads to internalization of AMPA receptors via endocytosis of AMPA receptors into the pool
Leads to removal of AMPA receptors from postsynaptic plasma membrane
Fewer receptors = smaller response
Protein phosphatases are activated by lower calcium levels than protein kinase
Small amount of calcium is sufficient to activate protein phosphatases
Not enough Calcium to activate protein kinases
Phosphatase activity dominates over kinase
Even though it uses similar kind of mechanism downstream, it involves completely different proteins dephosphorylating- opposite effect that leads to decrease in AMPA receptors
Silent synapse is found between a presynaptic glutamatergic neuron and a postsynaptic neuron
CA3 and CA1 neurons in Schaffer collaterals
Only expresses NMDA receptors
Before LTP, these synapses have NMDA receptors but not AMPA receptors
Even though they receive presynaptic glutamate level at the synapse, they are unable to respond because NMDA receptors at RMP have the magnesium block
No postsynaptic response
Silent synapses were originally discovered by depolarizing postsynaptic cell artificially
After you depolarize the response, you can measure the NMDA response- influx of Sodium and calcium in response to the glutamate
Pairing paradigm- stimulate at low leve but depolarize membrane potential, you can measure postsynaptic response
If there is enough pressynaptic glutamate release and there is a pairing protocol to provide large depolarization of membrane potential and you provide a large presynaptic input of APs to release large amount of glutamate, after a few seconds to minutes, one can observe an AMPA receptor dependant current that is also present in the postsynaptic neurons
Silent synapse has now become unsilenced- AMPA receptors now are going to participate in postsynaptic response
Reponse goes from 0 before LTP to a large increase in synaptic response
Mechanisms involved in unsilencing of silent synapses are the same as the mechanisms involved in synaptic strengthening
NMDA receptors are going to mediate Calcium increases, Calcium will phosphorylate AMPA receptors, and AMPA receptor tethering and trafficking proteins recruits AMPA receptors into the plasma membrane
Before there were no AMPA receptors and now there are AMPA receptors which are present
Contributes to increase in postsynaptic response
When measuring postsynaptic responses electrophysiologically using extracellular field potentials, we measure the response of thousands of synaptic spines
If we add more synaptic spines- synapses that are active- will lead to an increase in overall postsynaptic response
Synapse- contains both AMPA receptors and NMDA receptors
Nearby- silent synapse
For silent to become unsilenced- needs incoming release from the presynaptic neuron of glutamate but it also requires concomitant depolarization of postsynaptic membrane- can’t provide on its own
Can depend on depolarization produced by nearby synapses
When we have glutamate released by both axons at same time, glutamate will bind to AMPA receptors in mature synapse
Can passively spread to nearby synapses and depolarize that postsynaptic plasma membrane
Depolarization will remove the Magnesium block from NMDA receptors, then you have release of glutamate at the same time
Kicks off mechanism that lead to the increase in recruitment of AMPA receptors in postsynaptic plasma membrane
Silent synapse has been unsilenced and now there will be a response from both types of synapses
Hebbian mechanism- synapse specific
Have to have release of glutamate by presynaptic neuron
Once magnesium block has been removed, those receptors are going to allow for recruitment of AMPA receptors
Saturable- physiological
Input/synaptic specific- concomitant depolarization of postsynaptic membrane and release of glutamate at presynaptic terminus
LTP is both cooperative and associative- similar in terms of concepts
Much more similar to physiological situation within hippocampal neuron
Non Physiological tetanus type of stimulation- incoming activity is sufficient to depolarize membrane
Have glutamate- produce potentiated response
Artificial situation
Within hippocampus- cooperative and associative properties work towards LTP
Incoming presynaptic activity with postsynaptic response in normal synaptic transmission
Only one axon response
Cooperativity- even though on their own they might not be able to produce LTP, if they are firing at the same time, they can cooperate to depolarize membrane potential so all 3 synapses can now be strengthened
Associativity- incoming activity from synapse at same time associates responses
If there is a presynaptic input, 2 can associate to undergo LTP
Specificity- requires input of glutamate
Always has to have presynaptic glutamate release
Cooperativity- activation of multiple inputs which on their own are not sufficient to produce LTP
Can cooperate with each other to produce large enoug depolarization of membrane potential now that the NMDA receptors can become activated
Selectivity- only synapses that receive incoming activity will be strengthened
Associative- simultaneous pre and postsynaptic activity
Late- develops during early LTP but late LTP actually lasts for very long time in hippocampal neuron
Hours to days to week depending on type of incoming info
Requires new mRNA synthesis and transcription
Translation of newly transcribed mRNAs as well
Requires activation of transcription and translation
Activation depends on protein kinases stimulated early phase of LTP and stimulated by that influx in Calcium
Some of these kinases converge on Protein Kinase ERK
Phosphorylate and activate CREB and ERK
Leads to an increase of CREB and ERK dependent transcription
Signal of activated kinase is somehow able to be transmitted to the transcription factors CREB and ELK which increase transcription of many genes
Some transcription factors lead to decrease of other genes
Transcrpition occurs, mRNA is transported to cyotplasm for translation
Some can be transported to dendrite for local protein synthesis
Net effect- result in a persistent increase in AMPA receptor levels and AMPA receptor activity
Even though outcome in terms of synaptic response is similar to what occurs during early LTP, there are lots and lots of biochemical and structural changes that these dendritic spines undergo
Leads to an increase in dendritic spine volume
Can accommodate increase in AMPA receptors
Changes in the cytoskeleton, membrane excitability, continued activation of silent synapse
Increase in spine numbers- can be an addition of new spines to the particular dendritic region
Video Lecture 2
Early LTP- occurs in first hour or so after LTP induction
There is an increase in postsytnaptic Calcium
Depends on NMDA receptors
Calcium goes on to activate specific protein kinases
These kinases phosphorylate AMPA receptors and AMPA receptor tethering and trafficking proteins that lead to increase in number of postsynaptic AMPA receptors that mediates early part of LTP
Doesn’t require production of new poritne or new mRNA
After an hour this is where the late phase of LTP comes into play
Late LTP develops during early LTP
Last for longer than an hour, can last up to weeks in hippocampus
Underlies storage of memories- involves systems that will be storing for a lifetime
Late LTP vs early LTP- mRNA and protein synthesis is required
Synapse and spine undergo changes in morphology and structure, as well as epigenetic changes to genome
Late LTP involves activation of protein kinases like CaMKII, PKC, and PKA
All of these converge on one downstream kinase called ERK
ERK- growth factor pathways
Extracellular regulated kinase
Originally identified in cells that undergo proliferation in cell culture in non-neuronal system
Critical for late LTP
Kinases that phosphorylate and activate the ERK protein are going to have a transient activation
Early phase of LTP- kinases will be activated and after 30-60 min, go back to baseline activity
ERK becomes activated
Once this is activated, it phosphorylates its downstream targets
2 targets: CREB and ELK
Both of these are transcription factors
Activation of ERK leads to direct stimulation of transcription in neurons that undergo LTP
During transcription- new mRNA synehsis
Get exported out of nucleus
Some will be translated directly in cytoplasm, some are transported to dendrite which are where the stnapses are that are undergoing increase in potentiation
Synapses that undergo plasticity
Result- increase in specific genes
Memory related genes or Immediate-early
These are going to have effects on dendritic spines or morphology on synapse
Will lead to persistent increases in AMPA receptor activity or AMPA receptor levels
Late phase of LTP- maintain increase in AMPA receptors that initially occurred during LTP
Also changes dendritic spine volume, changes in cytoskeleton, changes in membrane excitability through regulation of ion channels
Activation of silent synapses
CREB- cyclic AMP response element binding protein
Phosphorylated by protein kinases downstream of ERK
FUnction- bind to specific region in promoter
CRE- cyclic AMP response element
When CREB is phosphorylated- recruits protein called CREB binding protein- CBP
Leads to activation of complex
CREB has to be phosphorylated to activate transcription because it has to recruit CBP/P300
Histone acetyltransferase- HAT- CBP
Acetylation of histoen proteins
When this occurs- relaxes histones from binding to DNA, opens nucleosome to allow for recruitment of transcriptional activation machinery
CREB is not directly phosphorylated by ERK protein
Uses different kinases in order to activate the CREB
TGACGTCA- consensus sequence for CREB to bind to
Dna is double stranded- sense and antisense strain
DNA binds as a dimer- sequence is a palindrome
Requirement for the specific sequences- little bit of wiggle room
Interesting genes in neuron that contain CRE sequence like BDNF, chromogranins, enkephalins, and others
ERK is not a direct regulator for CREB
Uses RSK2 and MSK1
ERK is a MAP kinase- large gene family of kinase not only involved in LTP, but also cell growth and differentiation for cell survival
Phosphorylates downstream kinases- RSK and MSK
Once they become phosphorylated- enter into nucleus to phosphorylate CREB
Regujlation by ERK of CREB phosphorylation- requires intermediary kinases
CREB can also be phosphorylated by PKA- protein kinase activated by cAMP
Initially identified in responses downstream of siganling that leads to increase in secondary messenger AMP
CREB is also a substrate for CaM KII
CaM KII could phosphorylate CREB in LTP
CaM KII is activated by Calcium and calmodulin once calcium levels increase in postsynaptic neuron
Majority of CaM KII is localized in postsynaptic density- not a lot in the cytoplasm able to translocate into nucleus and cell body
Majority of phosphorylation occurs through RSK and MSK pathway
Could potentially lead to modulation
LTP could be modulated by signaling pathways that increase cAMP
This is one of the ways LTP can be modulated
Once CREB is phosphorylated, it recruits CBP
HAT activity
Histones become acetylated
DNA opens up- can recruit basal transcriptional machinery for production of mRNAs
Even though CREB binds to DNA- has to be phosphroyalted to recruit activity
Once DNA is relaxed, histones are not wrapped around- leads to increase in transcription of genes that bind CREB and have CRE in their promoters
Increase in Calcium
Through many different mechanisms- leads to activation of ERK
Once ERK is activated by phosphorylating RSK and MSK- translocate into nucleus- CREB becomes phosphorylated, recruits CBP- increase in transcription
RSK- ribosomal S6 kinase
MSK- mitogen and stress activated kinase
Involved in protein synthesis regulation in cultured cells responding to activation of cell proliferation
Kinases phosphorylate CREB protein at Serine 133- phosphorylation required for activation of transcription
CaM KII and PKA can phosphorylate CREB on the same residue
Can lead to alternative mechanisms for CREB regulation
ERK can phosphorylate a different transcription factor called ELK1
Binds to a different element in DNA of specific genes in promoter- SRE
Serum response element- identifidd in culture cells that were stimulated to divide when serum was present
Has growth and trophic factors for cells- leads to activation of ELK
ERK and ELK- surprise- involved in LTP
ERK and ELK were initially identified in non neuronal cell in growth and trophic stimulation in cell proliferation and survival
Type of plasticity where neurons undergo biochemical and morphological changes- also occurs in cell growth and survival
CREB and ELK bind to specific DNA elements
Genes that contain either CRE or SRE are groups of genes upregulated in response to LTP
Set of genes activated during late phase of LTP were actually identified in several different systems to be stimulated as a set of genes
IEGs- immediate early genes- activity regulated genes- plasticity related genes within neuronal plasticity research literature
IEGs are a group of genes shown to be rapidly and transiently activated at transcriptional level following growth factor stimulation in cultured cells
Activity regulated genes- activated by seizure activity within rodent brain- very robust activity in specific regions of the brain
Plasticity related genes are upregulated during synaptic/neuronal plasticity
Common
Either gene itself has CRE in 5’ region of gene or have SRE within gene
Not all genes that contain these specific DNA elements are upregulated in response to LTP, but share
Most genes contain not only one specific response element in their promoter, but several
Can bind transcription factors like NF Kappa B or AP-1
Lots of different types of transcription factors
Can contain additional transcription factor binding sites- have other response elements
Regulation of these plasticity related genes involves additional combinations of other transcription factor binding as well
2 major groups- transcription factors or Effector IEGs
Transcription factors- activated by CREB
Go onto bind to response elements in other genes involved in plasticity- would have initial expression of transcription factors very rapidly during LTP
Would go on to regulate transcription of additional proteins like cFOS, cJUN, JUNB
Not initially identified in nervous systems- were identified in cell growth and survival pathways
Effector IEGs- include many different types of genes
AMPA receptors- expression/basis of LTP involves increase in AMPA receptor numbers- present in postsynaptic regions
To replenish AMPA receptors to those regions- needs to be an increase in transcription of mRNAs that encode AMPA receptors and increase in AMPA receptor translation as well
BDNF- trophic factor in survival of neurons
Can bind to receptors and is involved in synaptic plasticity as well
Downstream is a signaling cascade that can lead to morphological changes that occur in the synapse and spine
Homer- GPCR scaffolding protein
Target- metabotropic glutamate receptor
Metabotropic receptors are also involved in LTP
ATC- activity regulated cytoskeletal proteins
It has an important function in regulating postsynaptic and dendritic cytoskeleton- underlies morphological changes that occur in spines
All have CRE or SRE in specific promoter regions- respond to activation of CREB or ELK transcription factors
In addition to NMDA receptors, metabotropic glutamate receptors play an important role in modulation of LTP
Influx of Calcium- leads to stimulation of CaM Kinase
CaM Kinase leads to phosphorylation of AMPA receptors and AMPA receptor regulatory proteins
Also involved in pathways leading to regulation of CREB
In addition- ELK and AP1- other transcription factors involved in the pathway
Increase in transcription of plasticity related genes
mRNAs will be produced by transcription, will be transported out of nucleus to be transcribed into cognate proteins
fMRP- peptide
Proteins in cyotplasm of neuron- whose transcription is activated- biochemical and morphological changes that underlie late stages of LTP
Synapse strengthening is synapse specific
How signal knows to strengthen only those synapses that have received incoming presynaptic activity
How does the signal get from activated synapse to nucleus?
Mm away from nucleus
There could be diffusion or trafficking of kinases from postsynaptic region to nuclear region for activation
Motoring of specific kinases or complexes
ERK complex- could be specifically transported into neuronal cell body to phosphorylate MSK and RSK to be translocated into nucleus
Types of eresponses that lead to LTP lead to depolarization of postsynaptic membrane
If that depolarization is great enough- Sidium ions diffuse along emmbrane and passively diffuse cell bodies
Enough incoming depolarizations- neuron fires AP
Back propagating AP- travels in forward direction along axons
Due to voltage gated ion channels in cell body- AP can be propagated back into dendrites
Once this AP has been produced- could lead to opening of voltage gated channels found in the membrane within cell body
Candidate channels activated by back propagated by AP- VGCa2+Cs
Initial production of large response within neuron leads to AP
AP flows back, leads to activation of VGCa2+Cs, influx of Calcium near cell body and nucleus
This Calcium signal leads to activation of ERK and RSK and MSK found near cell body- downstream activation of kinases in region, that would be the signal leading to activation of transcription
BDNF- identified as a trophic factor, survival factor for neurons that express receptor for BDNF- TrkB
Also shown that BDNF is synthesized in response to LTP
Using exogenous system- addition of BDNF leads to synapse strengthening and contribute to activity
Knockout/reduction of BDNF levels or receptor- synapses do not undergo typical type of LTP
BDNF- Survival factor and plasticity in development of synapse
Binds to TrkB- receptor tyrosine kinase
BDNF can also activate some of the same types of activities and functions such as AMPA receptor trafficking- similar to CaM Kinase
Might be contributing later on to recruitment of AMPA receptors and tethering of AMPA receptors at postsynaptic plasma membrane
BDNF works presynaptically and postsynaptically
Presynaptic- regulators in increase of glutamate release that occurs during LTP
BDNF release location has not been clearly established
Could be either presynaptic or postsynaptic neuron or both
Group of genes whose expression decreases in LTP- have been named memory suppressor genes
2 have been well studied
Protein phosphatase 1- activity is decreased in LTP
Calcineuron- PP2B- dephosphorylate proteins
At the same time that kinase activities are activated during LTP, there is reduction in proteins that dephosphrylate same groups of substrate- lead to net increase in protein phosphorylation during LTP
CREB2- inhibitor of CRE protein and CREB activities
Decreasing inhibitor of CREB contributes to activation of CREB dependant RNA transcription
Video Lecture 3
Changes work together for expression of LTP
Increase in AMPA receptor (Density)
Long term biochemical and morphological changes
Newly transcribed mRNA can be transported from cell body to dendrites
Can be synthesized in both locations
If you block protein synthesis- leads to inhibition of LTP
Protein synthesis in cell body has been characterized well
In dendritic spines- local protein synthesis
Syntehssi of proteins within dendrite provides a pool of newly synthesized and critical proteins that can travel a short distance and be incorporated into the changes occurring in dendritic spines
ERK and other kinases activate translation by phosphorylating translating proteins
RSK- ribosomal S6 kinase- protein synthesis
Upregulation of protein synthesis in cell soma and dendritic spines
Translation of proteins involves not only soluble cytoplasmic proteins synthesized on free polyribosome
Like CaM KII
Translation of transmembrane proteins involves rough ER and golgi complex
There are rough ER and smooth ER
Small golgi like structures called dendritic golgi outputs are localized to golgi
Synthesis of transmembrane proteins like AMPA receptors and ion channels that regulate excitability of membrane within dendritic spine- can be translated close to site of where they will be inserted
Part of the secretory pathway- small secretory vesicles are present in dendritic spines
Deliver transmembrane proteins into dendritic spine membrane
Increase in number of proteins with mRNAs being shipped to dendirtes and newly translated proteins will be incorporated
Enlargement of spine volume
Increase is required to accommodate newly syntehsized transmembrane and cytoplasmic proteins present in dendritic spine
AMPA receptor increase that mediates increase in response of postsynaptic region within spine
Increase in AMPA receptors- delivered to postsynaptic region
AMPA receptors will be tethered so they won’t be endocytosed easily
EPSPs
If you block AMPA receptor synthesis- blocks late phase of LTP
Switch in AMPA receptor subunit
There are some changes to individual gene components- affects AMPA receptor specificity and activity
NMDA receptors- involved in induction of LTP, lead to increase in Calcium levels which kicks off LTP program
ARC- activity regulated cytoskeletal associated protein
Spines undergo changes in actin cytoskeleton
One of the changes thought to be regulating this is ARC- essential for LTP, if you inhibit arc activity, you will block LTP
Plays prominent role in transition phase from early to late LTP
ARC is not just dedicated to dendritic spine plasticity- neuron in general
Levels are affected in neuropsychiatric disorders like depression
Hebbian nature/synaptic specificity
Only synapses with incoming stimulation will be strengthened (nearby ones won’t)
Activation of kinases, increase in transcription, mRNA translation, some will be translated in cell body, some in dendrites
How does it know which specific synapse?
Synaptic tagging and capture
Early LTP- something happens in synapse- early info that leaves behind specific tag
Remains within activated synapse, captures newly synthesized protein or mRNAs
Strengthening only occurs in newly activated synapse
CaM KII- activated by Calcium flowing in through NMDA receptors
Calcium binds to calmodulin, activates CaM KII
CaM KII binds to and synthezed the protein
CaM KII serves as the tag- leads to changes in actin cytoskeleton
Indirectly leads to capture of specific plasticity molecules
CaM KII is soluble- how could it be involved in tagging?
Not soluble- becomes tethered at synapse when activated
NMDA receptor is a binding partner
Tag of the specific synapse which has undergone activation
Not the only mechanism- different manipulations of CaM KII
Certainly not the lone protein
PKM zeta is a member of the PKC family
PKC family is one of the proteins involved in early LTP
PKM zeta- following LTP, influx of Calcium
Rapidly synthesized in dendritic spine and PKM synthesized in response to LTP- newly synthesized PKM zeta- happens in early phase of LTP
Depends on translation, not transcription
PKM zeta- synthesis will be regulated
Could regulate types of trafficking proteins
Remains at synapse
Essential for LTP, synthesized early on
Identifies it as a candidate
Can capture newly synthesized proteins
Concomitant increase in spine volume
Both ERK and PKM zeta are involved in increase of spine volume
Synthesis of newly synthesized proteins could lead to enlargement of spine
Some proteins and mRNAs- captured by synapses to provide synapse specificity
NMDA receptor functions as ionotropic receptor- Calcium and Sodium into postsynaptic neuron
Structural and scaffolding role
Lots of other signaling and scaffolding proteins binds to complex
PSD-95- ampa receptor tethering at synapse
Kalirin- regulation of membrane trafficking
NMDA receptor and calcium influx- could lead to changes in dendritic cytoskeleton
Additional trafficking receptors and proteins involved in actin cytoskeleton
Large protein complex- NMDA receptor serves both signaling and scaffolding role
In addition to postsynaptic density proteins- have tethering of AMPA and NMDA receptors- synapse is a region where there are cell adhesion molecules expressed and bind to each other
Neurolignads, postsynaptic cell adhesion proteins- binding partners of nurexins and cadherins
Cadherins bind to each other
As spines get larger, presynaptic area increases
Expression of cell adhesion molecules is also upregulated
Synapse- ability of pre and post to bind to each other increases
Strengthening of synapses- potent strength of post synaptic response
Synapse can get stronger as well through cell adhesion molecules binding to each other as postsynaptic region enlarges, will have more proteins to keep it stably attached to presynaptic region
Silent synapses- become strengthening
As AMPA receptors are recruited to post synaptic region
During LTP- increase in total number of spines
Formation of new spines during LTP process
1 week after LTP- density of spines
Following LTP- increase in density
Statistically significant increase
How could this be Hebbian- how would neuron know which specific spine/area to produce?
Could be non-input specific
Within dendrite, spines are developing
Filopodia- mature and developing into mature spine
Small regions of contact between pre and post synaptic target- there could be activity like glutamate release
Filopodia- immature spine
Very early spine- can’t measure synaptic contacts between presynaptic and postsynaptic
Could be non-hebbian plasticity
If there is robust activity in areas close to spine, regions close to it- not specific, some of plasticity proteins- could spill out in regions close to activity dependent processes
Not 100% fidelity- secondary mechanism to increase spine density
Downstream of changes- increase of AMPA receptors, spine volume increases in morphological changes
Unsilencing of silent synapses- can increase spine volumes
Hippocampus is’t the place where long term memory is stored
Transmits info into other regions of cerebral cortex
Called systems consolidation
We don’t know the mechanisms, but involves similar synaptic and molecular changes that occur within hippocampus itself
Once hippocampus has transmitted info about which incoming info for declarative and spatial memory is important, the hippocampus goes back to prememory state
Once synapse has become strengthened, to go back to prememory activity- has to be reversed
Reverse is related to LTD
Hippocampus can now be used for encoding of future long-term memory
Video Lecture 4
Memories are present in cerebrocortical networks
Synaptic.cellular consolidation
2 places where it can occur- hippocampus during memory encoding process
Cerebrocortical circuits once memory has been transferred from memory
Late phase of LTP
Systems consolidation
Independent of hippocampus in a scale of a few weeks
Synaptic/cellular consolidation- consequence of biochemical and morpholiglcal changes initiated by original experience
In hippocampus- hours
Neocortical interaction between that and hippocampus
Days to years interaction
Can take many periods for memory to be consolidated
Consolidation takes place during LTP in hippocampus
Synaptic consolidation- produces changes in efficacy, whether in hippocampus or cortex
Synapses within neocrtical circuits will be modified
2 stage- hippocampus is involved in initial stage, transmits info into hippocampus
Once hippocampus has transmitted info and relative activity- undergoes synaptic renormalization (LTD)
Reorganized and renormalized back to prememory state
Declarative memories- stored in cortical networks
For recall- hippocampus is not involved
Episodic memory- hippocampus is involved
Systems consolidation- LTP and synaptic consolidation in process- we don’t know much about mechanisms involved
One activity- sleep
Info is going to be transmitted from cortical networks to hippocampus for encoding of relevant info that is stored in long term memory
Hippocampus transmits info back to cortical networks which eventually become independent
Role of hippocampus- connect pieces of info initially transmitted to hippocampus from sensory and association cortices
Binds info together, connects different cortical regions for storage
Sleep- defined as process in which body is paralyzed, brain different stages of activity
SWS- slow in frequency
Sleep is important for memory
One original hypothesis- Different phases of sleep are dedicated to different types of memory
Both stages are involved
Sequential hypothesis
Waking- acquisition of memory, info is transmitted from cerebral cortex to store in hippocampus
As transition between SWS to REM sleep- rapid eye movement- strengthening of neocortical memory representations- consolidation of synapses within neocortex
Several cycles of slow wave sleep and REM sleep in 8 hour cycle
Sleep spindle- hippocampal dependent LTM
Occurs before slow wave sleep
Info gets transmitted from cortical networks to hippocampus
Function- help transmit info, replay back from cerebral cortex to strengthen activity
Initial parts of transmission of strengthened circuit activity is transmitted back to neocortical circuits
SWS- systems consolidation, followed by rescaling activity
Hippocampal dependent activity would be rescaled
Wake state- memories stored and encoded to cerebral cortex can be retrieved back to short term memory, will be recalled to use
Cortical networks can do 2 things: encode new memories using hippocampus
Previously strengthened neocortical networks will be used for retrieval of newly encoded info
Synapses are modulated and strengthened- not much info about system consolidation and retrieval
During systems consolidation- initial activity can be recorded in cortex
Cortex contacts hippocampus to gauge info available to transfer
Theory one- Hippocampus is not required to encode memories after several weeks or months
HM- multiple trace model- declarative memories separated to semantic and episodic memory
Semantic memories- have standard theory, memories become independent of hippocampus as a function of tiem
Episodic memories- autobiographical, episodic rich memory require hippocampus for longer periods of time
Recall/retrieval of info depend on hippocampus
There may be different types of systems involved in ongoing encoding of memories and retrieval as well
After memories are stored- reactivation period
Become restored and unstable
Memory reconsolidation- restabilizes memory that was previously destabilized
If reconsolidation is modulated in this time by brain memory or drugs- can change negatively
Individuals who have had traumatic events- has been developed as a therapy to help them forget those
Once CaM Kinase becomes activated- autophosphorylation
Persistently activated, doesn’t need calmodulin for activation
Remains persistent even after original signals have diminished
Can phosphorylate other CaM Kinases
Prion proteins- has normal cell shape, interactions with mutated prion protein- can bind to normal protein and convert it into disease causing prion
Transforamtion of proteins between conformations
Converts protein to prion protein mutation
Creutzfeld-Jacob disease- mutation
Other proteins could also change conformation
Memory causing prion- would be stable, anytime newly synthesized prememory is produced- memory causing prion could convert a protein into a memory prion
Alzheimer’s and Parkinson’s- persistent changes downstream
