Single amino acid variation in barley 14-3-3 proteins leads to functional isoform specificity in the regulation of nitrate reductase.

The highly conserved family of 14-3-3 proteins function in the regulation of a wide variety of cellular processes. The presence of multiple 14-3-3 isoforms and the diversity of cellular processes regulated by 14-3-3 suggest functional isoform specificity of 14-3-3 isoforms in the regulation of target proteins. Indeed, several studies observed differences in affinity and functionality of 14-3-3 isoforms. However, the structural variation by which isoform specificity is accomplished remains unclear. Because other reports suggest that specificity is found in differential expression and availability of 14-3-3 isoforms, we used the nitrate reductase (NR) model system to analyse the availability and functionality of the three barley 14-3-3 isoforms. We found that 14-3-3C is unavailable in dark harvested barley leaf extract and 14-3-3A is functionally not capable to efficiently inhibit NR activity, leaving 14-3-3B as the only characterized isoform able to regulate NR in barley. Further, using site directed mutagenesis, we identified a single amino acid variation (Gly versus Ser) in loop 8 of the 14-3-3 proteins that plays an important role in the observed isoform specificity. Mutating the Gly residue of 14-3-3A to the alternative residue, as found in 14-3-3B and 14-3-3C, turned it into a potent inhibitor of NR activity. Using surface plasmon resonance, we show that the ability of 14-3-3A and the mutated version to inhibit NR activity correlates well with their binding affinity for the 14-3-3 binding motif in the NR protein, indicating involvement of this residue in ligand discrimination. These results suggest that both the availability of 14-3-3 isoforms as well as binding affinity determine isoform-specific regulation of NR activity.

[1]  R. Ferl,et al.  Phosphorylation and calcium binding properties of an Arabidopsis GF14 brain protein homolog. , 1994, The Plant cell.

[2]  P. Liao,et al.  The inhibitor protein of phosphorylated nitrate reductase from spinach (Spinacia oleracea) leaves is a 14‐3‐3 protein , 1996, FEBS letters.

[3]  M. Roberts,et al.  Regulatory 14-3-3 protein-protein interactions in plant cells. , 2000, Current opinion in plant biology.

[4]  W. Kaiser,et al.  Partial Purification and Characterization of a Calcium-Dependent Protein Kinase and an Inhibitor Protein Required for Inactivation of Spinach Leaf Nitrate Reductase , 1995, Plant physiology.

[5]  Robert J Ferl,et al.  Isoform-specific subcellular localization among 14-3-3 proteins in Arabidopsis seems to be driven by client interactions. , 2005, Molecular biology of the cell.

[6]  S. Huber,et al.  Biological significance of divalent metal ion binding to 14-3-3 proteins in relationship to nitrate reductase inactivation. , 1998, Plant & cell physiology.

[7]  S. Masters,et al.  Role of the 14‐3‐3 C‐terminal loop in ligand interaction , 2002, Proteins.

[8]  R. Ferl,et al.  14‐3‐3 proteins associate with the regulatory phosphorylation site of spinach leaf nitrate reductase in an isoform‐specific manner and reduce dephosphorylation of Ser‐543 by endogenous protein phosphatases , 1996, FEBS letters.

[9]  Jan Szopa,et al.  14-3-3 protein down-regulates key enzyme activities of nitrate and carbohydrate metabolism in potato plants. , 2005, Journal of agricultural and food chemistry.

[10]  M. Yaffe,et al.  The Structural Basis for 14-3-3:Phosphopeptide Binding Specificity , 1997, Cell.

[11]  Yamamoto,et al.  Members of the Arabidopsis 14-3-3 gene family trans-complement two types of defects in fission yeast. , 2000, Plant science : an international journal of experimental plant biology.

[12]  P. Allen,et al.  Interaction of 14-3-3 with Signaling Proteins Is Mediated by the Recognition of Phosphoserine , 1996, Cell.

[13]  N. Eckardt Transcription Factors Dial 14-3-3 for Nuclear Shuttle , 2001, The Plant Cell Online.

[14]  H. Spaink,et al.  Tissue-specific expression of 14-3-3 isoforms during barley microspore and zygotic embryogenesis , 2003 .

[15]  R. Ferl,et al.  Four Arabidopsis thaliana 14‐3‐3 protein isoforms can complement the lethal yeast bmh1 bmh2 double disruption , 1996, FEBS letters.

[16]  E Amler,et al.  Protein modeling combined with spectroscopic techniques: an attractive quick alternative to obtain structural information. , 2004, Physiological research.

[17]  T. Kinoshita,et al.  Specific binding of vf14-3-3a isoform to the plasma membrane H+-ATPase in response to blue light and fusicoccin in guard cells of broad bean. , 2001, Plant physiology.

[18]  Robert J. Ferl,et al.  Evolution and isoform specificity of plant 14-3-3 proteins , 2002, Plant Molecular Biology.

[19]  S. Huber,et al.  Divalent cations and polyamines bind to loop 8 of 14-3-3 proteins, modulating their interaction with phosphorylated nitrate reductase. , 2002, The Plant journal : for cell and molecular biology.

[20]  M. Palmgren,et al.  14‐3‐3 proteins activate a plant calcium‐dependent protein kinase (CDPK) , 1998, FEBS letters.

[21]  Robert J Ferl,et al.  Plasma membrane H(+)-ATPase and 14-3-3 isoforms of Arabidopsis leaves: evidence for isoform specificity in the 14-3-3/H(+)-ATPase interaction. , 2004, Plant & cell physiology.

[22]  Gavin Lingiah,et al.  Function and specificity of 14-3-3 proteins in the regulation of carbohydrate and nitrogen metabolism. , 2003, Journal of experimental botany.

[23]  J. Rostas,et al.  Subcellular Localisation of 14‐3‐3 Isoforms in Rat Brain Using Specific Antibodies , 1994, Journal of Neurochemistry.

[24]  M. Roberts,et al.  Plant 14-3-3 protein families: evidence for isoform-specific functions? , 2001, Biochemical Society transactions.

[25]  S. Huber,et al.  The C-terminal tail of Arabidopsis 14-3-3omega functions as an autoinhibitor and may contain a tenth alpha-helix. , 2003, The Plant journal : for cell and molecular biology.

[26]  M. Yaffe,et al.  A Structural Basis for 14-3-3σ Functional Specificity*♦ , 2005, Journal of Biological Chemistry.

[27]  H. Spaink,et al.  Isoform-specific differences in rapid nucleocytoplasmic shuttling cause distinct subcellular distributions of 14-3-3σ and 14-3-3ζ , 2004, Journal of Cell Science.

[28]  A. Karschin,et al.  Interaction with 14‐3‐3 proteins promotes functional expression of the potassium channels TASK‐1 and TASK‐3 , 2002, The Journal of physiology.

[29]  T. D. Bunney,et al.  14-3-3 protein regulation of proton pumps and ion channels , 2002, Plant Molecular Biology.

[30]  R. Liddington,et al.  Raf-1 Kinase and Exoenzyme S Interact with 14-3-3ζ through a Common Site Involving Lysine 49* , 1997, The Journal of Biological Chemistry.

[31]  A. D. Boer,et al.  Plant 14-3-3 proteins assist ion channels and pumps , 2001 .

[32]  J Pohl,et al.  14-3-3ζ Binds a Phosphorylated Raf Peptide and an Unphosphorylated Peptide via Its Conserved Amphipathic Groove* , 1998, The Journal of Biological Chemistry.

[33]  W. Kaiser,et al.  Post-translational regulation of nitrate reductase: mechanism, physiological relevance and environmental triggers. , 2001, Journal of experimental botany.

[34]  R. Ghirlando,et al.  Crystal Structure of the 14-3-3ζ:Serotonin N-Acetyltransferase Complex A Role for Scaffolding in Enzyme Regulation , 2001, Cell.

[35]  R. Liddington,et al.  Mutations in the Hydrophobic Surface of an Amphipathic Groove of 14-3-3ζ Disrupt Its Interaction with Raf-1 Kinase* , 1998, The Journal of Biological Chemistry.

[36]  C. Larsson,et al.  Data mining the Arabidopsis genome reveals fifteen 14-3-3 genes. Expression is demonstrated for two out of five novel genes. , 2001, Plant physiology.

[37]  Jesse D. Martinez,et al.  Isoform‐specific expression of 14‐3‐3 proteins in human lung cancer tissues , 2005, International journal of cancer.

[38]  Tom D. Bunney,et al.  14-3-3 protein is a regulator of the mitochondrial and chloroplast ATP synthase , 2001, Proceedings of the National Academy of Sciences of the United States of America.

[39]  M. V. van Hemert,et al.  14‐3‐3 proteins: key regulators of cell division, signalling and apoptosis , 2001, BioEssays : news and reviews in molecular, cellular and developmental biology.

[40]  Robert J. Ferl,et al.  Evolution of the 14-3-3 Protein Family: Does the Large Number of Isoforms in Multicellular Organisms Reflect Functional Specificity? , 2000, Journal of Molecular Evolution.

[41]  T. Obsil,et al.  14-3-3 Protein C-terminal Stretch Occupies Ligand Binding Groove and Is Displaced by Phosphopeptide Binding* , 2004, Journal of Biological Chemistry.

[42]  Petra ten Hoopen,et al.  The barley two-pore K+-channel HvKCO1 interacts with 14-3-3 proteins in an isoform specific manner , 2005 .

[43]  S. Huber,et al.  Post-translational regulation of nitrate reductase activity: a role for Ca2+ and 14-3-3 proteins , 1996 .

[44]  J. Kijne,et al.  Differences in spatial expression between 14-3-3 isoforms in germinating barley embryos. , 1999, Plant physiology.

[45]  Frederik Börnke,et al.  The variable C-terminus of 14-3-3 proteins mediates isoform-specific interaction with sucrose-phosphate synthase in the yeast two-hybrid system. , 2005, Journal of plant physiology.

[46]  C. MacKintosh,et al.  Metabolic enzymes as targets for 14-3-3 proteins , 2002, Plant Molecular Biology.