GlnK, a PII-homologue: structure reveals ATP binding site and indicates how the T-loops may be involved in molecular recognition.

GlnK is a recently discovered homologue of the PII signal protein, an indicator of the nitrogen status of bacteria. PII occupies a central position in the dual cascade that regulates the activity of glutamine synthetase and the transcription of its gene. The complete role of Escherichia coli GlnK is yet to be determined, but already it is known that GlnK behaves like PII and can substitute for PII under some circumstances thereby adding to the subtleties of nitrogen regulation. There are also indications that the roles of the two proteins differ; the expression of PII is constitutive while that of GlnK is linked to the level of nitrogen in the cell. The discovery of GlnK begs the question of why E. coli has both GlnK and PII. Clearly, the structural similarities and differences of GlnK and PII will lead to a better understanding of how PII-like proteins function in E. coli and other organisms. We have crystallised and solved the X-ray structure of GlnK at 2.0 A resolution. The asymmetric unit has two independent copies of the GlnK subunit and both pack around 3-fold axes to form trimers. The trimers have a barrel-like core with recognition loops (the T-loops) that protrude from the top of the molecule. The two GlnK molecules have similar core structures to PII but differ significantly at the C terminus and the loops. The T-loops of the two GlnK molecules also differ from each other; one is disordered while the conformation of the other is stabilised by lattice contacts. The conformation of the ordered T-loop of GlnK differs from that observed in the PII structure despite the fact that their sequences are very similar. The structures suggest that the T-loops do not have a rigid structure and that they may be flexible in solution. The presence of a turn of 310 helix in the middle of the T-loop suggests that secondary structure could form when it interacts with soluble receptor enzymes.Co-crystals of GlnK and ATP were used to determine the structure of the complex. In these crystals, GlnK occupies a position of 3-fold symmetry. ATP binds in a cleft on the side of the molecule. The cleft is suitably positioned for ATP to influence the flexible T-loops. It is found at the junction of two beta sheets and is formed by two peptides one of which contains a variant of the "Gly-loop" found in other mononucleotide binding proteins. This sequence, Thr-Gly-X-X-Gly-Asp-Gly-Lys-Ile-Phe, forms part of the B-loop and is conserved in a wide variety of organisms that include bacteria, algae and archeabacteria. This sequence is more highly conserved than the functional T-loop, suggesting that ATP has an important role in PII-like proteins.

[1]  D. Ollis,et al.  Structure of the Escherichia coli signal transducing protein PII. , 1994, Structure.

[2]  A. Ninfa,et al.  Structure/function analysis of the PII signal transduction protein of Escherichia coli: genetic separation of interactions with protein receptors , 1997, Journal of bacteriology.

[3]  M. Tsai,et al.  Mechanism of adenylate kinase: site-directed mutagenesis versus X-ray and NMR. , 1991, Biochemistry.

[4]  J. Walker,et al.  Distantly related sequences in the alpha‐ and beta‐subunits of ATP synthase, myosin, kinases and other ATP‐requiring enzymes and a common nucleotide binding fold. , 1982, The EMBO journal.

[5]  Collaborative Computational,et al.  The CCP4 suite: programs for protein crystallography. , 1994, Acta crystallographica. Section D, Biological crystallography.

[6]  J. Thornton,et al.  PROCHECK: a program to check the stereochemical quality of protein structures , 1993 .

[7]  Mike Carson,et al.  RIBBONS 2.0 , 1991 .

[8]  H V Westerhoff,et al.  The two opposing activities of adenylyl transferase reside in distinct homologous domains, with intramolecular signal transduction , 1997, The EMBO journal.

[9]  K. Forchhammer,et al.  Coexistence of two structurally similar but functionally different PII proteins in Azospirillum brasilense , 1996, Journal of bacteriology.

[10]  J. Navaza,et al.  AMoRe: an automated package for molecular replacement , 1994 .

[11]  W. Stites,et al.  Protein−Protein Interactions: Interface Structure, Binding Thermodynamics, and Mutational Analysis , 1997 .

[12]  S. Rhee,et al.  Cascade control of Escherichia coli glutamine synthetase. Purification and properties of PII protein and nucleotide sequence of its structural gene. , 1987, The Journal of biological chemistry.

[13]  Jones Ta,et al.  Diffraction methods for biological macromolecules. Interactive computer graphics: FRODO. , 1985, Methods in enzymology.

[14]  S. Hoving,et al.  An additional PII in Escherichia coli: a new regulatory protein in the glutamine synthetase cascade. , 1995, FEMS microbiology letters.

[15]  H. Westerhoff,et al.  Crystallization and preliminary X-ray analysis of Escherichia coli GlnK. , 1998, Acta crystallographica. Section D, Biological crystallography.

[16]  P. Kraulis A program to produce both detailed and schematic plots of protein structures , 1991 .

[17]  D. Ollis,et al.  Escherichia coli PII protein: purification, crystallization and oligomeric structure , 1994, FEBS letters.

[18]  G. Schulz Binding of nucleotides by proteins , 1992, Current Biology.

[19]  W. Kabsch,et al.  Dictionary of protein secondary structure: Pattern recognition of hydrogen‐bonded and geometrical features , 1983, Biopolymers.

[20]  J M Thornton,et al.  LIGPLOT: a program to generate schematic diagrams of protein-ligand interactions. , 1995, Protein engineering.

[21]  W. Kabsch,et al.  Structure of the guanine-nucleotide-binding domain of the Ha-ras oncogene product p21 in the triphosphate conformation , 1989, Nature.

[22]  R. Edwards,et al.  Nitrogen control in bacteria. , 1995, Microbiological reviews.

[23]  B. Magasanik,et al.  The regulation of nitrogen utilization in enteric bacteria , 1993, Journal of cellular biochemistry.

[24]  A. Ninfa,et al.  The Escherichia coli PII Signal Transduction Protein Is Activated upon Binding 2-Ketoglutarate and ATP (*) , 1995, The Journal of Biological Chemistry.

[25]  W. Windsor,et al.  Crystal structure of a complex between interferon-γ and its soluble high-affinity receptor , 1995, Nature.

[26]  P D Carr,et al.  X-ray structure of the signal transduction protein from Escherichia coli at 1.9 A. , 1996, Acta crystallographica. Section D, Biological crystallography.

[27]  G. Schulz,et al.  The glycine‐rich loop of adenylate kinase forms a giant anion hole , 1986, FEBS letters.

[28]  D. Ollis,et al.  The role of the T‐loop of the signal transducing protein PII from Escherichia coli , 1996, FEBS letters.

[29]  W. Kabsch,et al.  Refined crystal structure of the triphosphate conformation of H‐ras p21 at 1.35 A resolution: implications for the mechanism of GTP hydrolysis. , 1990, The EMBO journal.

[30]  K. Sharp,et al.  Protein folding and association: Insights from the interfacial and thermodynamic properties of hydrocarbons , 1991, Proteins.

[31]  Daniel Kahn,et al.  An alternative PII protein in the regulation of glutamine synthetase in Escherichia coli , 1996, Molecular microbiology.

[32]  J. Richardson,et al.  The anatomy and taxonomy of protein structure. , 1981, Advances in protein chemistry.

[33]  D. F. Waugh,et al.  Protein-protein interactions. , 1954, Advances in protein chemistry.

[34]  K. Forchhammer,et al.  Phosphoprotein PII from Cyanobacteria , 1997 .

[35]  A. Brunger Free R value: a novel statistical quantity for assessing the accuracy of crystal structures. , 1992 .

[36]  B. Magasanik,et al.  Role of glnB and glnD gene products in regulation of the glnALG operon of Escherichia coli , 1985, Journal of bacteriology.