Boguslaw Stec

Crystal structure of a nonsymbiotic plant hemoglobin.

BACKGROUNDnNonsymbiotic hemoglobins (nsHbs) form a new class of plant proteins that is distinct genetically and structurally from leghemoglobins. They are found ubiquitously in plants and are expressed in low concentrations in a variety of tissues including roots and leaves. Their function involves a biochemical response to growth under limited O(2) conditions.nnnRESULTSnThe first X-ray crystal structure of a member of this class of proteins, riceHb1, has been determined to 2.4 A resolution using a combination of phasing techniques. The active site of ferric riceHb1 differs significantly from those of traditional hemoglobins and myoglobins. The proximal and distal histidine sidechains coordinate directly to the heme iron, forming a hemichrome with spectral properties similar to those of cytochrome b(5). The crystal structure also shows that riceHb1 is a dimer with a novel interface formed by close contacts between the G helix and the region between the B and C helices of the partner subunit.nnnCONCLUSIONSnThe bis-histidyl heme coordination found in riceHb1 is unusual for a protein that binds O(2) reversibly. However, the distal His73 is rapidly displaced by ferrous ligands, and the overall O(2) affinity is ultra-high (K(D) approximately 1 nM). Our crystallographic model suggests that ligand binding occurs by an upward and outward movement of the E helix, concomitant dissociation of the distal histidine, possible repacking of the CD corner and folding of the D helix. Although the functional relevance of quaternary structure in nsHbs is unclear, the role of two conserved residues in stabilizing the dimer interface has been identified.

MJ0109 is an enzyme that is both an inositol monophosphatase and the 'missing' archaeal fructose-1,6-bisphosphatase.

In sequenced genomes, protein coding regions with unassigned function constitute between 10 and 50% of all open reading frames. Often key enzymes cannot be identified using sequence homology searches. For example, despite the fact that methanogens have an apparently functional gluconeogenesis pathway, standard tools have been unable to identify a fructose-1,6-bisphosphatase (FBPase) gene in the sequenced Methanoccocus jannaschii genome. Using a combination of functional and structural tools, we have shown that the protein product of the M. jannaschii gene MJ0109, which had been tentatively annotated as an inositol monophosphatase (IMPase), has both IMPase and FBPase activities. Moreover, several gene products annotated as IMPases from different thermophilic organisms also possess FBPase activity. Thus, we have found the FBPase that was missing in thermophiles and shown that it also functions as an IMPase.

Insights into the mechanisms of catalysis and heterotropic regulation of Escherichia coli aspartate transcarbamoylase based upon a structure of the enzyme complexed with the bisubstrate analogue N-phosphonacetyl-L-aspartate at 2.1 Å

A high‐resolution structure of Escherichia coli aspartate transcarbamoylase has been determined to 2.1 Å; resolution in the presence of the bisubstrate analog N‐phosphonacetyl‐L‐aspartate (PALA). The structure was refined to a free R‐factor of 23.4% and a working R‐factor of 20.3%. The PALA molecule is completely saturated with interactions to side chain and backbone groups in the active site, including two interactions that are contributed from the 80s loop of the adjacent catalytic chain. The charge neutralization of the bound PALA molecule (and presumably the substrates as well) induced by the electrostatic field of the highly positively charged active site is an important factor in the high binding affinity of PALA and must be important for catalysis. The higher‐resolution structure reported here departs in a number of ways from the previously determined structure at lower resolution. These modifications include alterations in the backbone conformation of the C‐terminal of the catalytic chains, the N‐ and C‐termini of the regulatory chains, and two loops of the regulatory chain. The high‐resolution of this structure has allowed a more detailed description of the binding of PALA to the active site of the enzyme and has allowed a detailed model of the tetrahedral intermediate to be constructed. This model becomes the basis of a description of the catalytic mechanism of the transcarbamoylase reaction. The R‐structural state of the enzyme‐PALA complex is an excellent representation of the form of the enzyme that occurs at the moment in the catalytic cycle when the tetrahedral intermediate is formed. Finally, improved electron density in the N‐terminal region of the regulatory chain (residues 1 to 7) has allowed tracing of the entire regulatory chain. The N‐terminal segments of the R1 and R6 chains are located in close proximity to each other and to the regulatory site. This portion of the molecule may be involved in the observed asymmetry between the regulatory binding sites as well as in the heterotropic response of the enzyme. Protein 1999;37:729–742. ©1999 Wiley‐Liss, Inc.

Structures of Thermophilic and Mesophilic Adenylate Kinases from the Genus Methanococcus

The crystal structures of adenylate kinases from the thermophile Methanococcus thermolithotrophicus and the mesophile Methanococcus voltae have been solved to resolutions of 2.8A and 2.5A, respectively. The structures of the enzymes are similar to that of the adenylate kinase from archaeal Sulfolobus acidocaldarius in many respects such as the extended central beta-sheets, the short LID domain, and the trimeric state. The analysis of unligated and AMP-bound subunits of M.voltae suggests that movements of two mobile domains are not independent of each other. The methanococcal structures are examined with respect to their lack of the invariant Lys residue within the phosphate-binding loop, and two Arg residues in the LID domain are proposed as substituting residues based on their conservation among archaeal adenylate kinases and mobility within the structures. Since S.acidocaldarius adenylate kinase has the invariant Lys residue as well as the two Arg residues, its phosphate-binding loop is examined and compared with those of other adenylate kinases. On the basis of the comparison and other available biochemical data, the unusual conformation of the Lys residue in S.acidocaldarius adenylate kinase is explained. Despite possessing 78% sequence identity, the methanococcal enzymes exhibit significantly different thermal stabilities. To study the determinants of thermostability, several structural features including salt-links, hydrogen bonds, packing density, surface to volume ratio and buried surface area are compared between the enzymes. From their difference in apolar buried surface area, hydrophobic interaction is proposed to be a basis for the disparate thermostabilities, and the corresponding free energy difference is also estimated. Results of previous mutational studies are interpreted in terms of the crystal structures, and support the importance of hydrophobic interactions in thermostability.

Direct structural evidence for a concerted allosteric transition in Escherichia coli aspartate transcarbamoylase

Regulation of protein function, often achieved by allosteric mechanisms, is central to normal physiology and cellular processes. Although numerous models have been proposed to account for the cooperative binding of ligands to allosteric proteins and enzymes, direct structural support has been lacking. Here, we used a combination of X-ray crystallography and small angle X-ray scattering in solution to provide direct structural evidence that the binding of ligand to just one of the six active sites of Escherichia coli aspartate transcarbamoylase induces a concerted structural transition from the T to the R state.

How the CO in myoglobin acquired its bend: lessons in interpretation of crystallographic data

Contrary to the expectation of chemists, the first X-ray structures of carbon monoxide bound to myoglobin (Mb) showed a highly distorted Fe-C-O bond system. These results appeared to support the idea of a largely steric mechanism for discrimination by the protein against CO binding, a lethal act for the protein in terms of its physiological function. The most recent independently determined high-resolution structures of Mb-CO have allowed the 25 year old controversy concerning the mode of CO binding to be resolved. The CO is now seen to bind in a roughly linear fashion without substantial bending, consistent with chemical expectations and spectroscopic measurements. Access to deposited diffraction data prompted a reevaluation of the sources of the original misinterpretation. A series of careful refinements of models against the data at high (1.1 A) and modest resolutions (1.5 A) have been performed in anisotropic versus isotropic modes. The results suggest that the original artifact was a result of lower quality crystals combined with anisotropic motion and limited resolution of the diffraction data sets. This retrospective analysis should serve as a caution for all researchers using structural tools to draw far-reaching biochemical conclusions.