A 1H NMR study of cobalt(II) arsanilazocarboxypeptidase A

Cobalt(II) arsanilazotyrosine-248 carboxypeptidase A has been characterized through 1H NMR spectroscopy. The ability of the azoenzyme to form binary and ternary complexes with L- and D-phenylalanine and azide has been investigated. Comparison with the 1H NMR results obtained on unmodified cobalt(II) carboxypeptidase provides direct information on the specific effect of the presence of the azo group on the reactivity of the system. Marked differences in the interaction with D-phenylalanine have been observed, and structural inferences are drawn.     

Copper trafficking: the solution structure of Bacillus subtilis CopZ.

A sequence with a high homology (39% residue identity) with that of the copper-transport CopZ protein from Enterococcus hirae and with the same MXCXXC metal-binding motif has been identified in the genome of Bacillus subtilis, and the corresponding protein has been expressed. The protein, constituted by 73 amino acids, does bind copper(I) under reducing conditions and fully folded in both copper-bound and copper-free forms under the present experimental conditions. The solution structure of the copper-bound form was determined through NMR spectroscopy on an 15N-labeled sample. A total of 1508 meaningful nuclear Overhauser effects, 38 dihedral phi angles, and 48 dihedral psi angles were used in the structural calculations, which lead to a family of 30 conformers with an average rmsd to the mean structure of 0.32 +/- 0.06 A for the backbone and of 0.85 +/- 0.07 A for the heavy atoms. NMR data on the apoprotein also show that, also in this form, the protein is in a folded state and essentially maintains the complete secondary structure. Some disorder is observed in the loop devoted to copper binding. These results are compared with those reported for CopZ from E. hirae whose structure is well-defined only in the apo form. The different behaviors of copper-loaded E. hirae and B. subtilis are tentatively accounted for on the basis of the presence of dithiothreitol used in the latter case, which would stabilize the monomeric form. The comparison is extended to other similar proteins, with particular attention to the copper-binding loop. The nature and the location of conserved residues around the metal-binding site are discussed with respect to their relevance for the metal-binding process. Proposals for the role of CopZ are also presented.     

In vivo interaction between mouse liver lysosomes and chloroquine

Particles sedimenting at 27,000 g X 10 min (MLCQ) were separated from liver homogenates of mice injected with chloroquine (CQ). The MLCQ contained most of the drug recovered in the organ as well as 50% of the liver aryl sulphatase activity. The release of CQ from MLCQ was studied in some physicochemical conditions, and in the presence of various agents known to modify membrane composition and stability. At pH 7.4, the equilibrium between free and bound CQ depended on the dilution of the MLCQ, and the time to reach equilibrium was strongly influenced by the temperature of incubation. Several agents causing membrane disruption and lysosomal enzyme leakage, such as osmotic shock, sonication and digitonin, had little effect on the CQ release. Acid and alkaline buffers, 0.55 M KCl and 0.1% Triton X-100 caused, instead, the immediate release of most of the bound CQ. Concentrations of digitonin causing the release of aryl sulphatase activity had little effect on bound CQ, suggesting that the drug is retained in lysosomes by forces and/or structures different in nature from those retaining most of the lysosomal enzyme activity. We think that the CQ trapped in lysosomes is bound to high affinity sites in membranous structures which are particularly altered by agents known to extract peripheral proteins from biological membranes or to change the conformation of molecular structures.     

Are unit charges always negligible?

 The electrostatic contribution to the reduction potentials due to the unit charges of ionizable residues largely explains the span in redox potentials in a series of high-potential Fe₄S₄ iron-sulfur proteins and mutants. This appears to be a lucky case in which other contributions (in general) larger than that due to unit charges cancel out. Received, accepted: 26 November 1996     

MaxOcc: a web portal for maximum occurrence analysis

The MaxOcc web portal is presented for the characterization of the conformational heterogeneity of two-domain proteins, through the calculation of the Maximum Occurrence that each protein conformation can have in agreement with experimental data. Whatever the real ensemble of conformations sampled by a protein, the weight of any conformation cannot exceed the calculated corresponding Maximum Occurrence value. The present portal allows users to compute these values using any combination of restraints like pseudocontact shifts, paramagnetism-based residual dipolar couplings, paramagnetic relaxation enhancements and small angle X-ray scattering profiles, given the 3D structure of the two domains as input. MaxOcc is embedded within the NMR grid services of the WeNMR project and is available via the WeNMR gateway at http://py-enmr.cerm.unifi.it/access/index/maxocc . It can be used freely upon registration to the grid with a digital certificate.     

Mapping protein–protein interaction by 13C′-detected heteronuclear NMR spectroscopy

The copper-mediated protein–protein interaction between yeast Atx1 and Ccc2 has been examined by protonless heteronuclear NMR and compared with the already available ¹H–¹⁵N HSQC information. The observed chemical shift variations are analyzed with respect to the actual solution structure, available through intermolecular NOEs. The advantage of using the CON-IPAP spectrum with respect to the ¹H–¹⁵N HSQC resides in the increased number of signals observed, including those of prolines. CBCACO-IPAP experiments allow us to focus on the interaction region and on side-chain carbonyls, while a newly designed CEN-IPAP experiment on side-chains of lysines. An attempt is made to rationalize the chemical shift variations on the basis of the structural data involving the interface between the proteins and the nearby regions. It is here proposed that protonless ¹³C direct-detection NMR is a useful complement to ¹H based NMR spectroscopy for monitoring protein–protein and protein–ligand interactions. Electronic Supplementary Material Supplementary material is available to authorised users in the online version of this article at     

The Binding Mode of ATP Revealed by the Solution Structure of the N-domain of Human ATP7A

We report the solution NMR structures of the N-domain of the Menkes protein (ATP7A) in the ATP-free and ATP-bound forms. The structures consist of a twisted antiparallel six-stranded β-sheet flanked by two pairs of α-helices. A protein loop of 50 amino acids located between β3 and β4 is disordered and mobile on the subnanosecond time scale. ATP binds with an affinity constant of (1.2 ± 0.1) × 10⁴ m⁻¹ and exchanges with a rate of the order of 1 × 10³ s⁻¹. The ATP-binding cavity is considerably affected by the presence of the ligand, resulting in a more compact conformation in the ATP-bound than in the ATP-free form. This structural variation is due to the movement of the α1-α2 and β2-β3 loops, both of which are highly conserved in copper(I)-transporting P_IB-type ATPases. The present structure reveals a characteristic binding mode of ATP within the protein scaffold of the copper(I)-transporting P_IB-type ATPases with respect to the other P-type ATPases. In particular, the binding cavity contains mainly hydrophobic aliphatic residues, which are involved in van der Waal''s interactions with the adenine ring of ATP, and a Glu side chain, which forms a crucial hydrogen bond to the amino group of ATP.     

Counting the zinc-proteins encoded in the human genome

Metalloproteins are proteins capable of binding one or more metal ions, which may be required for their biological function, or for regulation of their activities or for structural purposes. Genome sequencing projects have provided a huge number of protein primary sequences, but, even though several different elaborate analyses and annotations have been enabled by a rich and ever-increasing portfolio of bioinformatic tools, metal-binding properties remain difficult to predict as well as to investigate experimentally. Consequently, the present knowledge about metalloproteins is only partial. The present bioinformatic research proposes a strategy to answer the question of how many and which proteins encoded in the human genome may require zinc for their physiological function. This is achieved by a combination of approaches, which include: (i) searching in the proteome for the zinc-binding patterns that, on their turn, are obtained from all available X-ray data; (ii) using libraries of metal-binding protein domains based on multiple sequence alignments of known metalloproteins obtained from the Pfam database; and (iii) mining the annotations of human gene sequences, which are based on any type of information available. It is found that 1684 proteins in the human proteome are independently identified by all three approaches as zinc-proteins, 746 are identified by two, and 777 are identified by only one method. By assuming that all proteins identified by at least two approaches are truly zinc-binding and inspecting the proteins identified by a single method, it can be proposed that ca. 2800 human proteins are potentially zinc-binding in vivo, corresponding to 10% of the human proteome, with an uncertainty of 400 sequences. Available functional information suggests that the large majority of human zinc-binding proteins are involved in the regulation of gene expression. The most abundant class of zinc-binding proteins in humans is that of zinc-fingers, with Cys4 and Cys2His2 being the most common types of coordination environment.