Liposomes for microcompartmentation of enzymes and their influence on catalytic activity.

Modular systems for protein coupling have been applied for anchoring enzyme molecules on liposome surfaces. Two cytoplasmic model enzymes, alpha-amylase from Escherichia coli (EC. 3.2.1.1) and guanylate kinase from Saccharomyces cerevisiae (EC. 2.7.4.8), were directly coupled by a histidine-tag or indirectly via strep-tag and streptavidin or streptactin linker to a liposome membrane. Though the catalytic properties of the enzymes are generally maintained, stability and specific activity of the enzymes are modified after coupling and are especially influenced by the lipid used for the liposome assembly.

Cloning of the guanylate kinase homologues AGK-1 and AGK-2 from Arabidopsis thaliana and characterization of AGK-1.

Guanylate kinase is an essential enzyme for nucleotide metabolism, phosphorylating GMP to GDP or dGMP to dGDP. The low molecular mass cytosolic forms of guanylate kinase are implicated primarily in the regulation of the supply of guanine nucleotides to cell signalling pathways. The high molecular mass and membrane-associated forms of guanylate kinase homologues, notably found in neuronal tissues, are assigned roles in cell junction organization and transmembrane regulation. Here, we describe the first plant guanylate kinase-encoding genes, AGK1 and AGK2, from Arabidopsis thaliana. The nucleotide sequences of their genomic and cDNA clones predict proteins that carry N-terminal and C-terminal extensions of the guanylate kinase-like domain. The amino acid sequences of this domain share 46-52% identity with guanylate kinases from yeast, Escherichia coli, human, mouse and Caenorhabditis elegans. Arabidopsis guanylate kinases (AGKs) exhibit a high degree of conservation of active site residues and sequence motifs in common with other nucleoside monophosphate kinases, which suggests overall structural similarity of the plant proteins. Although bacterially expressed AGK-1 is enzymatically much less active than yeast guanylate kinase, its kinase domain is shown to complement yeast GUK1 recessive lethal mutations. AGKs are expressed ubiquitously in plant tissues with highest transcriptional activity detected in roots. The identification of AGKs provides new perspectives for understanding the role of guanylate kinases in plant cell signalling pathways.

Binding of nucleotides to guanylate kinase, p21(ras), and nucleoside-diphosphate kinase studied by nano-electrospray mass spectrometry.

The binding of nucleotides to three different nucleotide-binding proteins and to a control protein was studied by means of nano-electrospray mass spectrometry applied to aqueous nondenaturing solutions. The method leads to unambiguous identification of enzyme complexes with substrates and products but does not allow the determination of dissociation constants or even stoichiometries relevant to the binding in solution. For guanylate kinase (EC 2.7.4. 8), the transfer of HPO(3) between nucleotides was observed whenever a ternary complex with adenylate or guanylate nucleotides was formed. Guanosine 5'-tetraphosphate was generated after prolonged incubation with GDP or GTP. Mg(2+) binding was considerably enhanced in functional high affinity complexes, such as observed between guanylate kinase and its bisubstrate inhibitor P(1)-(5'-guanosyl)-P(5)-(5'-adenosyl) pentaphosphate or with the tight nucleotide-binding protein p21(ras) and GDP. Nucleoside-diphosphate kinase (EC 2.7.4.6) itself was phosphorylated in accordance to its known ping-pong mechanism. All nucleotide-binding proteins were shown to bind sulfate (SO(4)(2-)) with presumably high affinity and slow exchange rate. The binding of phosphate (PO(4)(3-)) could be inferred indirectly from competition with SO(4)(2-).

Functional analysis of the guanylate kinase-like domain in the synapse-associated protein SAP97.

SAP97 is a membrane cytoskeletal protein localized at the presynaptic nerve terminals of type 1 asymmetric synapses. It has been implicated in the assembly of synapses and in particular in the localization and clustering of ion channels. The C-terminal GK domain of SAP97 shares a high degree of sequence similarity with low-molecular-mass guanylate kinases. These enzymes are involved in the guanine nucleotide metabolic cycle and in the maintenance of GTP/GDP pools required for example in Ras-mediated cell signaling. It has therefore been hypothesized that SAP97 plays an essential role in cellular signaling by regulating the guanine nucleotide pools at synaptic junctions. Here, we test this hypothesis by assessing whether the GK domain in SAP97 encodes an authentic guanylate kinase. We show that the GK domain in and of itself does not encode an active guanylate kinase, that it cannot be activated by its binding partner GKAP and that flanking regions are not acting as inhibitory regulators for enzymatic activity. Thus, it would appear that the GK domain of SAP97 is not involved in the metabolism of guanine nucleotides required for signaling events.