Receptor activity Dendritic spines express
glutamate receptors (e.g.
AMPA receptor and
NMDA receptor) on their surface. The
TrkB receptor for
BDNF is also expressed on the spine surface, and is believed to play a role in spine survival. The tip of the spine contains an electron-dense region referred to as the "
postsynaptic density" (PSD). The PSD directly apposes the
active zone of its synapsing axon and comprises ~10% of the spine's membrane surface area; neurotransmitters released from the active zone bind receptors in the postsynaptic density of the spine. Half of the synapsing axons and dendritic spines are physically tethered by
calcium-dependent
cadherin, which forms cell-to-cell adherent junctions between two neurons. Glutamate receptors (GluRs) are localized to the postsynaptic density, and are anchored by cytoskeletal elements to the membrane. They are positioned directly above their signalling machinery, which is typically tethered to the underside of the plasma membrane, allowing signals transmitted by the GluRs into the
cytosol to be further propagated by their nearby signalling elements to activate
signal transduction cascades. The localization of signalling elements to their GluRs is particularly important in ensuring signal cascade activation, as GluRs would be unable to affect particular downstream effects without nearby signallers. Signalling from GluRs is mediated by the presence of an abundance of proteins, especially kinases, that are localized to the postsynaptic density. These include
calcium-dependent
calmodulin,
CaMKII (calmodulin-dependent protein kinase II),
PKC (Protein Kinase C),
PKA (Protein Kinase A),
Protein Phosphatase-1 (PP-1), and
Fyn tyrosine kinase. Certain signallers, such as CaMKII, are upregulated in response to activity. Spines are particularly advantageous to neurons by compartmentalizing biochemical signals. This can help to encode changes in the state of an individual synapse without necessarily affecting the state of other synapses of the same neuron. The length and width of the spine neck has a large effect on the degree of compartmentalization, with thin spines being the most biochemically isolated spines.
Plasticity Dendritic spines are very "plastic", that is, spines change significantly in shape, volume, and number in small time courses. Because spines have a primarily
actin cytoskeleton, they are dynamic, and the majority of spines change their shape within seconds to minutes because of the dynamicity of
actin remodeling. Furthermore, spine number is very variable and spines come and go; in a matter of hours, 10-20% of spines can spontaneously appear or disappear on the pyramidal cells of the cerebral cortex, although the larger "mushroom"-shaped spines are the most stable. Spine maintenance and plasticity is activity-dependent and activity-independent.
BDNF partially determines spine levels, and low levels of
AMPA receptor activity is necessary to maintain spine survival, and synaptic activity involving
NMDA receptors encourages spine growth. Furthermore,
two-photon laser scanning microscopy and confocal microscopy have shown that spine volume changes depending on the types of stimuli that are presented to a synapse.
Importance to learning and memory Evidence of importance Spine plasticity is implicated in
motivation,
learning, and
memory. In particular,
long-term memory is mediated in part by the growth of new dendritic spines (or the enlargement of pre-existing spines) to reinforce a particular neural pathway. Because dendritic spines are plastic structures whose lifespan is influenced by input activity, spine dynamics may play an important role in the maintenance of memory over a lifetime. Age-dependent changes in the rate of spine turnover suggest that spine stability impacts developmental learning. In youth, dendritic spine turnover is relatively high and produces a net loss of spines. This high rate of spine turnover may characterize critical periods of development and reflect learning capacity in adolescence—different cortical areas exhibit differing levels of synaptic turnover during development, possibly reflecting varying
critical periods for specific brain regions. suggesting that the learning of a new skill involves a rewiring process of neural circuits. Since the extent of spine remodeling correlates with success of learning, this suggests a crucial role of synaptic structural plasticity in memory formation. Research in neurological diseases and injuries shed further light on the nature and importance of spine turnover. After
stroke, a marked increase in structural plasticity occurs near the trauma site, and a five- to eightfold increase from control rates in spine turnover has been observed. Dendrites disintegrate and reassemble rapidly during
ischemia—as with stroke, survivors showed an increase in dendritic spine turnover. While a net loss of spines is observed in
Alzheimer's disease and cases of
intellectual disability, cocaine and amphetamine use have been linked to increases in dendritic branching and spine density in the
prefrontal cortex and the
nucleus accumbens. Because significant changes in spine density occur in various brain and spinal cord diseases, this suggests a balanced state of spine dynamics in normal circumstances, which may be susceptible to disequilibrium under varying pathological conditions. There is also some evidence for loss of dendritic spines as a consequence of aging. One study using mice has noted a correlation between age-related reductions in spine densities in the hippocampus and age-dependent declines in hippocampal learning and memory. Emerging evidence has also shown dendritic spine abnormalities in the pain processing regions of the spinal cord nociceptive system, including superficial and intermediate zones of the dorsal horn. Overall, the evidence suggests that dendritic spines are crucial for normal brain and spinal cord function. Alterations in spine morphology may not only influence synaptic plasticity and information processing but also have a key role in many neurological diseases. Furthermore, even subtle changes in dendritic spine densities or sizes can affect neuronal network properties, which could lead to cognitive or mood alterations, impaired learning and memory, as well as pain hypersensitivity. ==Modeling==