Hexokinase III
Hexokinase III, also known as hexokinase C, is an enzyme which in humans is encoded by the Hk3 gene on chromosome 5. Hexokinases phosphorylate glucose to produce glucose-6-phosphate, the first step in most glucose metabolism pathways. Similar to hexokinases I and II, this allosteric enzyme is inhibited by its product glucose-6-phosphate.
Structure
Hexokinase III is one of four homologous hexokinase isoforms in mammalian cells. This protein has a molecular mass of 100 kDa and is composed of two highly similar 50-kDa domains at its N- and C-terminals. This high similarity, along with the and the existence of a 50-kDa hexokinase, suggests that the 100-kDa hexokinases originated from a 50-kDa precursor via gene duplication and tandem ligation. As with hexokinase I, only the C-terminal domain possesses catalytic ability, whereas the N-terminal domain is predicted to contain glucose and glucose 6-phosphate binding sites, as well as a 32-residue region essential for proper protein folding. Moreover, the catalytic activity depends on the interaction between the two terminal domains. Unlike hexokinase I and hexokinase II, hexokinase III lacks a mitochondrial binding sequence at its N-terminal.Function
As a cytoplasmic isoform of hexokinase and a member of the sugar kinase family, hexokinase III catalyzes the rate-limiting and first obligatory step of glucose metabolism, which is the ATP-dependent phosphorylation of glucose to glucose 6-phosphate. Physiological levels of glucose 6-phosphate can regulate this process by inhibiting hexokinase III as negative feedback, though inorganic phosphate can relieve glucose 6-phosphate inhibition. Inorganic phosphate can also directly regulate hexokinase III, and the double regulation may better suit its anabolic functions. By phosphorylating glucose, hexokinase III effectively prevents glucose from leaving the cell and, thus, commits glucose to energy metabolism. Compared to hexokinase I and hexokinase II, hexokinase III possesses a higher affinity for glucose and will bind the substrate even at physiological levels, though this binding may be attenuated by intracellular ATP. Uniquely, hexokinase III can be inhibited by glucose at high concentrations. hexokinase III is also less sensitive to glucose 6-phosphate inhibition.Despite its lack of mitochondrial association, hexokinase III also functions to protect the cell against apoptosis. Overexpression of hexokinase III has resulted in increased ATP levels, decreased reactive oxygen species production, attenuated reduction in the mitochondrial membrane potential, and enhanced mitochondrial biogenesis. Overall, hexokinase III may promote cell survival by controlling ROS levels and boosting energy production. Currently, only hypoxia is known to induce hexokinase III expression through a HIF-dependent pathway. The inducible expression of hexokinase III indicates its adaptive role in metabolic responses to changes in the cellular environment.
In particular, Hk3 is ubiquitously expressed in tissues, albeit at relatively low abundance. Higher abundance levels have been cited in lung, kidney, and liver tissue. Within cells, hexokinase III localizes to the cytoplasm and putatively binds the perinuclear envelope. hexokinase III is the predominant hexokinase in myeloid cells, particularly granulocytes.