Abstract
Crystal structures of the unique hexokinase KlHxk1 of the yeast Kluyveromyces lactis were determined using eight independent crystal forms. In five crystal forms, a symmetrical ring-shaped homodimer was observed, corresponding to the physiological dimer existing in solution as shown by small-angle x-ray scattering. The dimer has a head-to-tail arrangement such that the small domain of one subunit interacts with the large domain of the other subunit. Dimer formation requires favorable interactions of the 15 N-terminal amino acids that are part of the large domain with amino acids of the small domain of the opposite subunit, respectively. The head-to-tail arrangement involving both domains of the two KlHxk1 subunits is appropriate to explain the reduced activity of the homodimer as compared with the monomeric enzyme and the influence of substrates and products on dimer formation and dissociation. In particular, the structure of the symmetrical KlHxk1 dimer serves to explain why phosphorylation of conserved residue Ser-15 may cause electrostatic repulsions with nearby negatively charged residues of the adjacent subunit, thereby inducing a dissociation of the homologous dimeric hexokinases KlHxk1 and ScHxk2. Two complex structures of KlHxk1 with bound glucose provide a molecular model of substrate binding to the open conformation and the subsequent classical domain closure motion of yeast hexokinases. The entirety of the novel data extends the current concept of glucose signaling in yeast and complements the induced-fit model by integrating the events of N-terminal phosphorylation and dissociation of homodimeric yeast hexokinases.
Highlights
The enzymes of the hexokinase family catalyze the intracellular trapping and the initiation of metabolism of glucose, fructose, and mannose
The molecular basis underlying the involvement of hexokinases in the transcriptional control of glucose metabolism and in glucose homeostasis is their ability to interact with mitochondria and to reversibly translocate to nuclei (3, 6 –9)
Contrary to the situation in bakers’ yeast, glucose and fructose limitation causes the translocation of the mammalian hexokinase isoenzyme IV to the nucleus of the liver parenchymal cell where it binds to its regulatory protein, GKRP, and retranslocates when glucose is abundantly available again [16]
Summary
ScHxk, S. cerevisiae hexokinase isoenzyme 2 (B or PII); KlHxk, K. lactis hexokinase 1; ScHxk, S. cerevisiae hexokinase isoenzyme 1 (A or PI); SmHxk, S. mansoni hexokinase 1; KlMig, K. lactis Mig regulatory protein; ScMig, S. cerevisiae Mig regulatory protein; PDB, Protein Data Bank; SAXS, small-angle x-ray scattering; Bicine, N,Nbis(2-hydroxyethyl)glycine; CHES, 2-(cyclohexylamino)ethanesulfonic acid; AMP-PCP, adenosine 5Ј-(,␥-methylenetriphosphate); AMP-PNP, adenosine 5Ј-(,␥-imino)triphosphate. The radius of the latter crystal dimer is in agreement with the radius of gyration of 30 –31.3 Å determined from small-angle x-ray scattering of dimeric ScHxk in solution [34] It remains unclear whether the asymmetric dimer in crystal form BII corresponds to the dimer observed in solution, as oligomers usually exhibit a closed symmetry. Taking into consideration the high degree of sequence identity and the similar oligomerization behavior of KlHxk and ScHxk, as well as the detection of KlHxk phosphorylation at Ser-15 in preliminary studies, the novel structural model seems appropriate to explain the regulation of KlHxk and, by analogy, of ScHxk function(s) by covalent modification and modulation of the monomer-dimer equilibrium. The crystal structure analysis of open and closed forms of KlHxk including enzyme-glucose complexes as presented here allows for a re-evaluation of the induced-fit model of yeast hexokinase-glucose interaction using the same isoenzyme as the object of study
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