The family of the PII signal transduction proteins contains the most highly conserved signaling proteins in nature. The cyanobacterial PII-homologue transmits signals of the cellular nitrogen status and carbon status through phosphorylation of a seryl-residue. To identify the enzyme responsible for dephosphorylation of the phosphorylated PII protein in Synechocystis PCC 6803, prospective phosphatase encoding genes were inactivated by targeted insertion of kanamycin resistance cassettes. Disruption of ORF sll1771 generates a mutant unable to dephosphorylate PII under various experimental conditions. On the basis of conserved signature motifs, the sll1771 product (termed PphA) is a member of the protein phosphatase 2C (PP2C) superfamily, which is characterized by Mg 2؉ ͞Mn 2؉ -dependent catalytic activity. Biochemical analysis of overexpressed and purified PphA confirms its PP2C-type enzymatic properties and demonstrated its reactivity toward the phosphorylated PII protein. Thus, PphA is the first protein phosphatase in Synechocystis PCC 6803 for which the physiological substrate and function is known.
The phosphorylation state of the putative signal transduction protein P(II) from the cyanobacterium Synechococcus sp. strain PCC 7942 depends on the cellular state of nitrogen and carbon assimilation. In this study, dephosphorylation of phosphorylated P(II) protein (P[II]-P) was investigated both in vivo and in vitro. The in vivo studies implied that P(II)-P dephosphorylation is regulated by inhibitory metabolites involved in the glutamine synthetase-glutamate synthase pathway of ammonium assimilation. An in vitro assay for P(II)-P dephosphorylation was established that revealed a Mg2+-dependent P(II)-P phosphatase activity. P(II)-P phosphatase and P(II) kinase activities could be separated biochemically. A partially purified P(II)-P phosphatase preparation also catalysed the dephosphorylation of phosphoserine/phosphothreonine residues on other proteins in a Mg2+-dependent manner. However, only dephosphorylation of P(II)-P was regulated by synergistic inhibition by ATP and 2-oxoglutarate. As the same metabolites stimulate the P(II) kinase activity, it appears that the phosphorylation state of P(II) is determined by ATP and 2-oxoglutarate-dependent reciprocal reactivity of P(II) towards its phosphatase and kinase.
Thioredoxins (Trx) participate in essential antioxidant and redox-regulatory processes via a pair of conserved cysteine residues. In dipteran insects like Drosophila and Anopheles, which lack a genuine glutathione reductase (GR), thioredoxins fuel the glutathione system with reducing equivalents. Thus, characterizing Trxs from these organisms contributes to our understanding of redox control in GR-free systems and provides information on novel targets for insect control. Cytosolic Trx of Drosophila melanogaster (DmTrx) is the first thioredoxin that was crystallized for X-ray diffraction analysis in the reduced and in the oxidized form. Comparison of the resulting structures shows rearrangements in the active-site regions. Formation of the C32-C35 disulfide bridge leads to a rotation of the side-chain of C32 away from C35 in the reduced form. This is similar to the situation in human Trx and Trx m from spinach chloroplasts but differs from Escherichia coli Trx, where it is C35 that moves upon change of the redox state. In all four crystal forms that were analysed, DmTrx molecules are engaged in a non-covalent dimer interaction. However, as demonstrated by gel-filtration analyses, DmTrx does not dimerize under quasi in vivo conditions and there is no redox control of a putative monomer/dimer equilibrium. The dimer dissociation constants K(d) were found to be 2.2mM for reduced DmTrx and above 10mM for oxidized DmTrx as well as for the protein in the presence of reduced glutathione. In human Trx, oxidative dimerization has been demonstrated in vitro. Therefore, this finding may indicate a difference in redox control of GR-free and GR-containing organisms.
Summary
The family of PII signal transduction proteins consists of one of the
most highly conserved signalling proteins in nature. The cyanobacterial PII
homologue transmits signals on the nitrogen and carbon status of the cells through
phosphorylation of a seryl residue. Recently, we identified a protein phospha‐tase
2C (PP2C) homologue from the cyanobacterium Synechocystis PCC 6803, termed
PphA, to be the cellular phospho‐PII (PII‐P) phosphatase. In
this investigation, we characterized the enzymatic properties of PphA and investigated
the regulation of its catalytic activity towards PII‐P. PphA dephosphorylates
phosphocasein and PII‐P with similar efficiency in a strictly Mg2+‐
or Mn2+‐dependent reaction. Low‐molecular‐weight phosphorylated
molecules are poor substrates for PphA. Its reactivity towards PII‐P,
but not towards phosphocasein, is inhibited by various nucleotides, suggesting that
this effect is based on specific properties of the PII protein. The inhibitory
effect of ATP can be strongly enhanced by the addition of 2‐oxoglutarate or oxaloacetate.
At low concentrations of 2‐oxoglutarate, changes in the ATP levels within the physiological
range affect the degree of PII‐Pase inhibition, whereas at 2‐oxoglutarate
levels beyond 0.1 mM, inhibition is almost complete at very low ATP levels. This
suggests that PII dephosphorylation is not only sensitive to 2‐oxoglutarate and oxaloacetate levels, it also integrates signals from the energy charge of the cells under specific cellular conditions.
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