Investigating the Roles of a Putative Transmembrane Domain of Mammalian Diacylglycerol Kinase Epsilon

Dicu, Armela Ovidia

06 1900

<p> An area of current research interest involves the diacylglycerol kinase (DGK) family. Diacylglycerol kinases (DGKs) are a group of enzymes that phosphorylate diacylglycerol (DAG), a second messenger involved in cell signaling. The product of this reaction, phosphatidic acid (PA), also has signaling roles. An interesting isoform is DGKε, that although it has no identifiable regulatory domains other than the C1 domains. In addition, the catalytic domain is homologous to that of other DGK isoforms; however, DGKε exhibits an unusual specificity toward acyl chains of DAG, selectively phosphorylating an arachidonoyl-DAG substituted at the sn-2 position. Recently, researchers have identified an N-terminal hydrophobic domain of about 19 amino-acids in human DGKε. The present study attempted to identify the function of the N-terminal putative transmembrane domain of human DGKε and its relationship to the activity and substrate specificity of this enzyme by designing a truncated form of DGKε lacking the putative transmembrane domain.</p> <p> We have shown that the putative transmembrane domain of DGKε is not required for enzyme activity or for substrate specificity. In a mixed micellar assay the enzyme-catalyzed reaction followed surface dilution kinetics with respect to diacylglycerol and followed Michaelis-Menten kinetics with respect to ATP. The results show that the truncated form of the enzyme maintains substrate specificity for lipids with an arachidonoyl moiety present at the sn-2 position. The truncation increased the catalytic rate constant for all three substrates used in this study. It appears unlikely that the putative transmembrane domain, a segment unique to DGKε, has no functional role. It is possible that the hydrophobic segment may have a role in enzyme regulation by associating the enzyme in oligomers that are inactive in quiescent cells and get activated upon dissociation into monomers by increased levels of DAG in the membrane. We have shown that the presence of higher molecular species in the gel is not dependent on the presence or absence of the putative transmembrane domain. The only difference between the full-length and truncated enzyme is the monomer to dimer ratio. It appears likely that another segment of DGKε besides the putative transmembrane domain may be involved in oligomerization and that oligomerization is either transient or very weak. The absence of the hydrophobic domain of DGKε seems to cause no drastic changes either in the activity, the substrate specificity, or the state of oligomerization of the enzyme.</p> <p> Therefore, the next question is whether the hydrophobic domain of DGKε inserts itself in the membrane as a transmembrane helix or it only helps associate the enzyme to the surface of the membrane. We studied the topology of theN-terminal domain of DGKε in intact and permeabilized cells by indirect immunofluorescent microscopy. The results show that the N-terminal domain of the protein is present in the cytosol. The data supports a model in which the hydrophobic domain of DGKε forms a hydrophobic loop that attaches to the inner layer of the plasma membrane or that the hydrophobic domain attaches to the inner leaflet through its nonpolar surface of a horizontal helix. The first hypothesis is supported by the presence of a Pro residue in the middle of the hydrophobic domain. This Pro would introduce a kink in the helix creating a loop, but the absence of one or more glycine residues proximal to proline may hinder the formation of the loop. The second hypothesis is sustained by the presence of a polar surface on one side of the helical wheel. This orientation indicates the presence of a slightly horizontal helix attached to the surface of the inner layer of the plasma membrane.</p> <p> Regardless of the orientation of the helix, the weak association of the enzyme with the membrane is supported by previous data on the ease of extractability of the enzyme with high salts and on the Triton X-114 phase partitioning.</p> / Thesis / Master of Science (MSc)

EXAMINATION OF ENZYMATIC ACTIVITY AND SUBSTRATE SPECIFICITY IN ENZYMES INVOLVED IN THE PHOSPHATIDYLINOSITOL CYCLE

D'Souza, Kenneth

31 March 2015

<p>Phosphatidylinositol (PI) is a phospholipid that constitutes only a minor component of eukaryotic membranes. However, they are critical in many fundamental cellular processes, such as signal transduction pathways, vesicular trafficking and actin cytoskeletal dynamics. PI is highly enriched in specific acyl chains at both the <em>sn-1</em> and <em>sn-2</em> positions, the major species being 1-stearoyl-2-arachidonoyl. Enzymes required for PI synthesis are believed to play a major role in this enrichment through the selective catalysis of specific substrates. We have studied several aspects of two enzymes involved in PI synthesis, Diacylglycerol kinase ε (DGKε) and CDP-Diacylglycerol synthases (CDS). We have studied the role of the ATP-binding motif of DGKε and showed that this enzyme is not only required for enzymatic activity, but substrate specificity and sub-cellular localization. We have also looked at the region adjacent to the catalytic site, containing a cholesterol recognition motif, and determined that this also affects the enzymes activity and substrate specificity. Finally, we have characterized the enzymatic properties of two CDS isoforms <em>in vitro</em> and demonstrated that these isoforms exhibit different substrate specificities. Taken together, our results serve to further our understanding of both DGKε and CDS1/2 and their roles in PI synthesis and enrichment with specific acyl chains.</p> / Master of Science (MSc)

Lipid metabolism

signal transduction pathways

acyl chain specificity

phosphatidylinositol cycle

diacylglycerol kinase epsilon

CDP-DAG synthase