In enzymology, a ceramide kinase, also abbreviated as CERK, is an enzyme that catalyzes the chemical reaction: Thus, the two substrates of this enzyme are ATP and ceramide, whereas its two products are ADP and ceramide-1-phosphate. This enzyme belongs to the family of transferases, specifically those transferring phosphorus-containing groups with an alcohol group as acceptor. The systematic name of this enzyme class is ATP:ceramide 1-phosphotransferase. This enzyme is also called acylsphingosine kinase. This enzyme participates in sphingolipid metabolism.
CERK is a 537 amino acid enzyme in humans. CERK was first discovered in 1989 when it was co-purified with synaptic vesicles from brain cells. Upon discovery, CERK was proposed to be a ceramide kinase that functions in the presence of μM concentration of calcium anions. Since CERK lacks a calcium binding site, the regulatory mechanism of CERK was poorly understood. CERK was later confirmed to bind calmodulin in the presence of calcium, indicating the calmodulin first binds calcium and then CERK. Once bound, CERK becomes active and is capable of phosphorylating ceramides. Binding of calmodulin occurs between amino acids 420 and 437 in CERK at a putative 1-8-14B calmodulin binding motif. The binding motif in CERK contains leu-422, phe-429, and leu-435 which respectively correspond to the 1st, 8th, and 14th hydrophobic amino acids where calmodulin binds. Mutation of Phe-429 results in weak calmodulin binding, while mutations of Phe-331 or Phe-335 entirely preclude binding. CERK activity has primarily been observed within human neutrophils, cerebrumgranule cells, and epithelium-derived lung cells. When inactive, CERK is suspended within the cytosol of the cell. When CERK is activated by interleukin-1β, it is localized to the trans-golgi, and from there, possibly delivered to the plasma membrane. Activation may also to cause CERK to localize within endosomes. CERK’s PH domain plays an integral role in this localization. Once localized, to the trans-golgi CERK activates cytosolic phospholipase A2 that has localized to the trans-golgi. Activation of cPLA2 results in hydrolysis of membrane phospholipids to produce arachidonic acid. Ceramide kinase has also been demonstrated to regulate localization and level of phosphatidylinositol 4,5-bisphosphate produced from NORPA, a phospholipase C homolog in Drosophila melanogaster. In addition to endosomal and trans-golgi localization, CERK has been found to localize to outer mitochondrial membrane at the site of COX-2 localization in A549 cells.
Ceramide-1-phosphate
As a lipid kinase CERK is responsible for the phosphorylation of ceramides. CERK is capable of phosphorylating multiple ceramide species. Though CERK will phosphorylate C2, C20, C22, and C24 ceramides, substrate specificity is quite poor. By contrast, CERK has the greatest substrate specificity for C6, C8, and C16 ceramides, indicating that the location of the sphingosine group plays a role in specificity. Dihydroceramide can also be phosphorylated by CERK, but to a lesser extent. In contrast to C6 ceramide, CERK has low specificity for C6 dihydroceramide, but retains high specificity for C8 dihydroceramide- Ceramide transport proteins transport ceramides to CERK for phosphorylation. Phosphorylation of ceramides to produce ceramide-1-phosphate is believed to facilitate the localization of cPLA2 to the trans-golgi so that CERK can activate cPLA2.
Production of C-1-P bolsters cell survival and proliferation. It has been shown that C-1-P promotes DNA synthesis in fibroblasts. C-1-P also prevents apoptosis by inhibiting the caspase-9/caspase-3 pathway and preventing DNA fragmentation in macrophages. This is thought to occur via C-1-P interacting with and blocking functionality of acid sphingomyelinase. This results in diminished ceramide production, which precludes apoptosis. Recently, phosphorylation of ceramide via CERK has been shown to stimulate myoblast proliferation. It was demonstrated that C-1-P perpetuates the phosphorylation of glycogen synthase kinase-3 β and retinoblastoma protein, which contributes to transition from the G1 phase to M phase of the cell cycle. Additionally, production of C-1-P appears to result in increased expression of Cyclin D. CERK has demonstrated an ability to activate phosphatidylinositol 3-kinase/Akt, ERK1/2, and mTOR. CERKs ability to produce signaling molecules that facilitate the activation of cell proliferation as well as its interaction with PI3K/Akt, and mTOR indicate that disregulated CERK expression may lead to cancer.
Other roles
In addition to cell survival and proliferation, CERK has been implicated in many other processes. CERK is believed to participate in altering the lipid raft structure via C-1-P production, contributing to phagosome formation in polymorphonuclear leukocytes. CERK has also been found to participate in the calcium-dependent degranulation of mast cells.