Retrograde signaling in biology is the process where a signal travels backwards from a target source to its original source. For example, thenucleus of a cell is the original source for creating signaling proteins. During retrograde signaling, instead of signals leaving the nucleus, they are sent to the nucleus.^[1] Incell biology, this type of signaling typically occurs between themitochondria orchloroplast and the nucleus. Signaling molecules from the mitochondria or chloroplast act on the nucleus to affectnuclear gene expression. In this regard, the chloroplast or mitochondria act as a sensor for internal external stimuli which activate a signaling pathway.^[2]

Inneuroscience, retrograde signaling (orretrograde neurotransmission) refers more specifically to the process by which a retrograde messenger, such asanandamide ornitric oxide, is released by a postsynapticdendrite orcell body, and travels "backwards" across achemical synapse to bind to theaxon terminal of a presynapticneuron.^[3]

Retrograde signals are transmitted fromplastids to the nucleus in plants andeukaryotic algae,^[4][2] and from mitochondria to the nucleus in most eukaryotes.^[5] Retrograde signals are generally considered to convey intracellular signals related to stress and environmental sensing.^[6] Many of the molecules associated with retrograde signaling act on modifying thetranscription or by directly binding and acting as atranscription factor. The outcomes of these signaling pathways vary byorganism and by stimuli or stress.^[4]

Retrograde signaling is believed to have arisen afterendocytosis of the mitochondria and chloroplast billions of years ago.^[7] Originally believed to be photosynthetic bacteria, the mitochondria and chloroplast transferred some of their DNA to the membrane protected nucleus.^[8] Thus, some of the proteins required for the mitochondria or chloroplast are within the nucleus. This transfer of DNA further required a network of communication to properly respond to external and internal signals and produce requisite proteins.^[9]

The first retrograde signaling pathways discovered inyeast is the RTG pathway.^[10][11] The RTG pathway plays an important role in maintaining the metabolichomeostasis of yeast.^[11] Under limited resources the mitochondria must maintain a balance ofglutamate for thecitric acid cycle.^[12] Retrograde signaling from the mitochondria initiates production precursor molecules of glutamate to properly balance supplies within the mitochondria.^[13] Retrograde signaling can also act to arrest growth if problems are encountered. InSaccharomyces cerevisiae, if the mitochondria fails to develop properly, they will stop growing until the issue is addressed orcell death is induced.^[13] This mechanism is vital to maintain homeostasis of the cell and ensure proper function of the mitochondria.^[13]

One of the most studied retrograde signaling molecules in plants arereactive oxygen species (ROS).^[14] These compounds, previously believed to be damaging to the cell, have since been discovered to act as a signaling molecule.^[15] Reactive oxygen species are created as a by-product of aerobic respiration and act on genes involved in the stress response.^[15] Depending on the stress, reactive oxygen species can act on neighboring cells to initiate a local signal.^[16] By doing this, surrounding cells are "primed" to react to the stress because genes involved in stress response are initiated prior to encountering the stress.^[16] The chloroplast can also act as a sensor for pathogen response and drought. Detection of these stresses in the cell will induce the formation of compounds that can then act on the nucleus to produce pathogen resistance genes or drought tolerance.^[17] 

The primary purpose of retrograde neurotransmission is regulation of chemicalneurotransmission.^[3] For this reason, retrograde neurotransmission allowsneural circuits to createfeedback loops. In the sense that retrograde neurotransmission mainly serves to regulate typical, anterograde neurotransmission, rather than to actually distribute any information, it is similar toelectrical neurotransmission.

In contrast to conventional (anterograde) neurotransmitters, retrograde neurotransmitters are synthesized in the postsynaptic neuron, and bind to receptors on theaxon terminal of the presynaptic neuron.^[18] Additionally, retrograde signaling initiates a signaling cascade that focuses on the presynaptic neuron. Once retrograde signaling is initiated, there is an increase in action potentials that begin in the presynaptic neuron, which directly impacts the postsynaptic neuron by increasing the number of its receptors.^[19]

Endocannabinoids likeanandamide are known to act as retrograde messengers,^[20][21][22] as is nitric oxide.^[23][24]

Retrograde signaling may also play a role inlong-term potentiation (LTP), a proposed mechanism of learning and memory, although this is controversial.^[25][26][27]

In 2009, Regehret al. proposed criteria for defining retrograde neurotransmitters. According to their work, a signaling molecule can be considered a retrograde neurotransmitter if it satisfies all of the following criteria:^[3]

• The appropriate machinery for synthesizing and releasing the retrograde messenger must be located in the postsynaptic neuron
• Disrupting the synthesis and/or release of the messenger from the postsynaptic neuron must prevent retrograde signaling
• The appropriate targets for the retrograde messenger must be located in the presynaptic bouton
• Disrupting the targets for the retrograde messenger in the presynaptic boutons must eliminate retrograde signaling
• Exposing the presynaptic bouton to the messenger should mimic retrograde signaling provided the presence of the retrograde messenger is sufficient for retrograde signaling to occur
• In cases where the retrograde messenger is not sufficient, pairing the other factors with the retrograde signal should mimic the phenomenon

The most prevalent endogenous retrograde neurotransmitters arenitric oxide^[23][24] and variousendocannabinoids, which are lipophilic ligands.^[19][28]

The retrograde neurotransmitter, nitric oxide (NO) is a soluble gas that can readily diffuse through various cell membranes.^[29]Nitric oxide synthase is the enzyme responsible for the synthesis of NO in various presynaptic cells.^[30] Specifically, NO is known to play a critical role in LTP, which plays an important role in memory storage within thehippocampus.^[31] Additionally, literature suggests that NO can act as intracellular messengers in the brain and can also have an effect on the presynaptic glutamatergic and GABAergic synapses.^[32]

Utilizing retrograde signaling, endocannabinoids, a type of retrograde neurotransmitter, are activated when they bind to G-protein coupled receptors on the presynaptic terminals of neurons.^[33] The activation of endocannabinoids results in the release of particular neurotransmitters at the excitatory and inhibitory synapses of a neuron, ultimately impacting various forms of plasticity.^[34][19][33]

As it pertains to LTP, retrograde signaling is a hypothesis describing how events underlying LTP may begin in thepostsynaptic neuron but be propagated to thepresynaptic neuron, even though normalcommunication across achemical synapse occurs in a presynaptic to postsynaptic direction. It is used most commonly by those who argue that presynaptic neurons contribute significantly to the expression of LTP.^[35]

Long-term potentiation is the persistent increase in the strength of achemical synapse that lasts from hours to days.^[36] It is thought to occur via two temporally separated events, withinduction occurring first, followed byexpression.^[36] Most LTP investigators agree that induction is entirely postsynaptic, whereas there is disagreement as to whether expression is principally a presynaptic or postsynaptic event.^[26] Some researchers believe that both presynaptic and postsynaptic mechanisms play a role in LTP expression.^[26]

Were LTP entirely induced and expressed postsynaptically, there would be no need for the postsynaptic cell to communicate with the presynaptic cell followingLTP induction. However, postsynaptic induction combined withpresynaptic expression requires that, following induction, the postsynaptic cell must communicate with the presynaptic cell. Because normalsynaptic transmission occurs in a presynaptic to postsynaptic direction, postsynaptic to presynaptic communication is considered a form ofretrograde transmission.^[25]

The retrograde signaling hypothesis proposes that during the early stages of LTP expression, the postsynaptic cell "sends a message" to the presynaptic cell to notify it that an LTP-inducing stimulus has been received postsynaptically. The general hypothesis of retrograde signaling does not propose a precise mechanism by which this message is sent and received. One mechanism may be that the postsynaptic cell synthesizes and releases a retrograde messenger upon receipt of LTP-inducing stimulation.^[37][38] Another is that it releases a preformed retrograde messenger upon such activation. Yet another mechanism is that synapse-spanning proteins may be altered by LTP-inducing stimuli in the postsynaptic cell, and that changes in conformation of these proteins propagates this information across the synapse and to the presynaptic cell.^[39]

Of these mechanisms, the retrograde messenger hypothesis has received the most attention. Among proponents of the model, there is disagreement over the identity of the retrograde messenger. A flurry of work in the early 1990s to demonstrate the existence of a retrograde messenger and to determine its identity generated a list of candidates includingcarbon monoxide,^[40]platelet-activating factor,^[41][42]arachidonic acid,^[43] and nitric oxide. Nitric oxide has received a great deal of attention in the past, but has recently been superseded byadhesion proteins that span the synaptic cleft to join the presynaptic and postsynaptic cells.^[39] Theendocannabinoidsanandamide and/or2-AG, acting throughG-protein coupledcannabinoid receptors, may play an important role in retrograde signaling in LTP.^[20][21]

• Cell signaling
• Neurophysiology

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