Pain Recently Cdk5 has emerged as an essential kinase in sensory pathways. Recent reports by Pareek et al. suggest its necessity in pain signaling. CDK5 is required for proper development of the brain, and to be activated, it must associate with
CDK5R1 or
CDK5R2. Unlike other cyclin-dependent kinases, CDK5 does not also require
phosphorylation on the T loop. Therefore, binding with the activator is sufficient to activate the kinase.
Neurons Cdk5 is abundant and mainly expressed in neurons, where it phosphorylates protein polymers with a high molecular weight called neurofilaments, and microtubule-associated protein tau, which are abundant in the CNS (Central Nervous System). The enzyme is involved in many aspects of neuronal development and functions. The main role of Cdk5 when it comes to neurons is to assure proper neuronal migration. Neurons will send out both dendrites and axons to form connections with other neurons in order to transmit information, and Cdk5 regulates this process. In order to perform, Cdk5 needs to be activated by p35 (these 3 amino acids, Asp-259, Asn-266, and Ser-270, are involved in the formation of hydrogen bonds with Cdk5) or p39 (the isoform of p35), which are two of its neuron-specific regulatory subunits. This means that the level of expression of p35 and p39 is going to be related to the activity of the enzyme. If there is a high activity of Cdk5 during brain development, its activators will have a high expression. As a matter of fact, when studies were conducted on mice without p35 and p39, the results were the same as the ones observed on mice without Cdk5: there were clear disruptions of the laminar structures in the cerebral cortex, the olfactory bulb, the hippocampus, and the cerebellum. These areas' proper development and functionality depend on Cdk5, which relies on the correct expression of p35 and p39. Also, Cdk5 collaborates with
Reelin signaling in order to assure the proper neuronal migration in the developing brain. Cdk5 is not only implicated in neuronal migration. The enzyme will also help manage neurite extension, synapse formation, and synaptic transmission. It is also worth noting that Cdk5 also regulates the process of apoptosis, which is necessary in order to assure that the neural connections that are formed are correct. Moreover, because Cdk5 also intervenes in the regulation of synaptic plasticity, it is implicated in the processes of learning and memory formation, as well as the creation of drug addiction. On top of that, Cdk5 modulates actin-cytoskeleton dynamics by phosphorylating Pak1 and filamin 1 and regulates the microtubules by also phosphorylating tau, MAP1B, doublecortin, Nudel, and CRMPs, which are all microtubule-associated proteins. A non-proper expression of Cdk5 will generate defects in these substrates that can lead to multiple illnesses. For example, a defect on filamin 1 in humans provokes periventricular heterotopia; and a defect on Lis1 and doublecortin will cause lissencephaly type 1. As a matter of fact, four members of a consanguineous Israeli Muslim family that suffered from lissencephaly-7 with cerebellar hypoplasia had a
splice site mutation in the Cdk5 gene.
Drug abuse Cdk5 has been proven to be directly linked with drug abuse. It is established that drugs act on the reward system by disturbing intracellular signal transduction pathways, with Cdk5 being involved. Upon repetitive administration, several components of dopamine signalling are modified, including changes in gene expression and the circuitry of dopaminoceptive neurons. In the example of cocaine,
CREB (cAMP Response Element Binding) causes a transient burst in immediate-early gene expression in the striatum, as well as the expression of
ΔFosB isoforms, which accumulate and persist in striatal neurons with an extremely long half-life. Many studies have revealed that the overexpression of ΔFosB due to drug abuse is the cause of an upregulation of Cdk5, it being downstream of ΔFosB expression in the striatum, including the nucleus accumbens. It has been established that with repeated exposure to drugs such as cocaine and overexpression of ΔFosB isoforms, Cdk5 is upregulated, mediated by the upregulation of p35. It has also been demonstrated that this enzyme has an important place in dopamine neurotransmission regulation. Indeed, Cdk5 can act on the dopamine system by phosphorylating DARPP-32. As a consequence of tof Cdk5 upregulation, there is also a rise in the number of dendritic branch points and spines, both in medium spiny neurons in the
nucleus accumbens and
pyramidal neurons in the
medial prefrontal cortex. Hence, its involvement in the reward system, and by extension addiction. Further analysis of the relationship between Cdk5 proportion and drug effects has shown that there is a strong dependence on the dose and frequency of administration. For instance, if the frequency of the cocaine dose is low, or the dose is continuously administered over a period, the cocaine effects will be present even though the production of Cdk5 in the nucleus accumbens, in the
ventral tegmental area, and prefrontal cortex activity will not increase. However, when it comes to significantly frequent doses, the effects of cocaine are not displayed despite the enhanced proportion of Cdk5. Those differences can be explained by the fact that Cdk5 is a transitional state to overexposure to drugs like cocaine. Cdk5 has been suggested as a therapeutic target in addiction management. For example, it has been proved that sustained administration of Cdk5 antagonists inhibits the growth of spiny dendrites in the nucleus accumbens, which could be an avenue for addiction management. Further, Cdk5 could be used as a diagnostic marker for addiction.
Pancreas Even though the main role of Cdk5 is related to neuronal migration, its impact on the human body is not limited to the nervous system. Indeed, Cdk5 plays an important part in the control of
insulin secretion in the pancreas. Actually, this enzyme has been found in pancreatic
β cells and has been proven to reduce insulin exocytosis by
phosphorylating L-VDCC (L-type voltage-dependent Ca2+ channel).
Immune system During
T-cell activation, Cdk5 phosphorylates coronin 1a, a protein that contributes to the process of
phagocytosis and regulates
actin polarization. Therefore, this kinase promotes T-cell survival and motility. Cdk5 also takes part in the production of
interleukin 2 (IL-2), a cytokine involved in
cell signaling, by T-cells. To do so, it disrupts the repression of interleukin 2 transcription by the
Histone deacetylase 1 (HDAC1) through mSin3a protein phosphorylation. This reduces the ability of the HDAC1/mSin3a complex to bind to the IL-2 promoter, which leads to an increased interleukin 2 production.
Regulation of exocytosis Synaptic vesicle exocytosis is also regulated by CdK5, with the phosphorylation of the munc-18-a protein, which is indispensable for secretion, as it has a great affinity with a derivative of SNAP receptor (SNARE protein). This phosphorylation was demonstrated with the simulation of secretion from neuroendocrine cells, since the Cdk5 activity increased. When Cdk5 was removed, the norepinephrine secretion decreased.
Memory Thanks to an experiment with mice, a relation between memory and Cdk5 was demonstrated. On one hand, mice did not show fear integrated by a previous activity when Cdk5 was inactivated. On the other hand, when the enzyme activity was increased in the hippocampus -where memories are stored- the fear reappeared.
Remodelling of the actin cytoskeleton in the brain During
embryogenesis, Cdk5 is essential for brain development as it is crucial for the regulation of the
cytoskeleton that in turn is important for remodelling in the brain.
Circadian clock regulation The mammalian
circadian clock is controlled by Cdk5 with the phosphorylation of PER2. In the laboratory, Cdk5 was blocked in the SCN (suprachiasmatic nuclei, a master oscillator of the circadian system), consequently the free-running period in mice was reduced. During the diurnal period, the PER2 (at serine residue 394) was phosphorylated by the Cdk5, thus, the Cryptochrome 1 (CRY1) could easily interact with it and the PER2-CRY1 complex went into the nucleus. The molecular circadian cycle and period are properly established thanks to the task of the Cdk5 as a nuclear driver of these proteins.
Regulator of cell apoptosis and cell survival In addition to all the roles previously mentioned, the Cdk5 is involved in numerous cellular functions such as cell mobility survival,
apoptosis, and gene regulation. The plasma membrane, cytosol and perinuclear region are the locations where Cdk5/p35 activators are found. Nevertheless, Cdk5 can also be activated by cyclin I, this regulator causes an increase in the expression of BCl-2 family proteins, which are associated with anti-apoptotic functions. == Role in disease ==