Formation of the Native Topology of a Protein is due to the "Conserved but Non-Functional" Residues: A Case of Apomyoglobin Folding.

This paper is dedicated to the memory of Oleg B. Ptitsyn (1929-1999) and presents an answer to his question: "What is the role of conserved non-functional residues in protein folding?". This answer follows from the experimental works of three labs.

Function of the Conserved Non-Functional Residues in Apomyoglobin - to Determine and to Preserve Correct Topology of the Protein.

In this paper the answer to O. B. Ptitsyn's question "What is the role of conserved non-functional residues in apomyoglobin" is presented, which is based on the research results of three laboratories.

The Molten Globule State of a Globular Protein in a Cell Is More or Less Frequent Case Rather than an Exception.

Quite a long time ago, Oleg B. Ptitsyn put forward a hypothesis about the possible functional significance of the molten globule (MG) state for the functioning of proteins. MG is an intermediate between the unfolded and the native state of a protein.

Complex Folding Landscape of Apomyoglobin at Acidic pH Revealed by Ultrafast Kinetic Analysis of Core Mutants.

Under mildly acidic conditions (pH 4-4.5) apomyoglobin (apoMb) adopts a partially structured equilibrium state ( M-state) that structurally resembles a kinetic intermediate encountered at a late stage of folding to the native structure at neutral pH. We have previously reported that the M-state is formed rapidly (<1 ms) via a multistate process and thus offers a unique opportunity for exploring early stages of folding by both experimental and computational techniques.

sw ApoMb Amyloid Aggregation under Nondenaturing Conditions: The Role of Native Structure Stability.

Investigation of the molecular mechanisms underlying amyloid-related human diseases attracts close attention. These diseases, the number of which currently is above 40, are characterized by formation of peptide or protein aggregates containing a cross-β structure. Most of the amyloidogenesis mechanisms described so far are based on experimental studies of aggregation of short peptides, intrinsically disordered proteins, or proteins under denaturing conditions, and studies of amyloid aggregate formations by structured globular proteins under conditions close to physiological ones are still in the initial stage.

Membrane-induced changes in the holomyoglobin tertiary structure: interplay with function.

The effect of anionic phospholipid membranes on holomyoglobin (holoMb) conformation and deoxygenation was studied. HoloMb structural changes and behavior in the presence of membranes were monitored by a variety of techniques including far UV and near UV circular dichroism, tryptophan (Trp) fluorescence, absorbance in the Soret region, differential scanning calorimetry, (1)H-NMR spectroscopy, size exclusion chromatography, and macroscopic diffusion. Kinetics of deoxygenation was monitored by absorption at 581 nm.

Folding intermediate and folding nucleus for I-->N and U-->I-->N transitions in apomyoglobin: contributions by conserved and nonconserved residues.

Kinetic investigation on the wild-type apomyoglobin and its 12 mutants with substitutions of hydrophobic residues by Ala was performed using stopped-flow fluorescence. Characteristics of the kinetic intermediate I and the folding nucleus were derived solely from kinetic data, namely, the slow-phase folding rate constants and the burst-phase amplitudes of Trp fluorescence intensity. This allowed us to pioneer the phi-analysis for apomyoglobin.

How strong are side chain interactions in the folding intermediate?

Influence of 12 nonpolar amino acids residues from the hydrophobic core of apomyoglobin on stability of its native state and folding intermediate was studied. Six of the selected residues are from the A, G and H helices; these are conserved in structure of the globin family, although nonfunctional, that is, not involved in heme binding. The rest are nonconserved hydrophobic residues that belong to the B, C, D, and E helices.

Phospholipid membranes affect tertiary structure of the soluble cytochrome b5 heme-binding domain.

The influence of charged phospholipid membranes on the conformational state of the water-soluble fragment of cytochrome b5 has been investigated by a variety of techniques at neutral pH. The results of this work provide the first evidence that aqueous solutions with high phospholipid/protein molar ratios (pH 7.2) induce the cytochrome to undergo a structural transition from the native conformation to an intermediate state with molten-globule like properties that occur in the presence of an artificial membrane surface and that leads to binding of the protein to the membrane.

Time-resolved CIDNP study of non-native states of bovine and human alpha-lactalbumins.

The reaction mechanism and details of the formation of CIDNP (chemically induced dynamic nuclear polarization) in the photoreactions of the aromatic dye 2,2'-dipyridyl with non-native states of bovine and human alpha-lactalbumins (BLA and HLA) in aqueous solution have been studied using the time-resolved CIDNP technique. Non-native states have been obtained at pH 2 in the presence of 0, 8, and 10 M urea-d(4) and at pH 6.7 in the presence of 10 M urea-d(4).

Three-state protein folding: experimental determination of free-energy profile.

When considering protein folding with a transient intermediate, a difficulty arises as to determination of the rates of separate transitions. Here we overcome this problem, using the kinetic studies of the unfolding/refolding reactions of the three-state protein apomyoglobin as a model. Amplitudes of the protein refolding kinetic burst phase corresponding to the transition from the unfolded (U) to intermediate (I) state, that occurs prior to the native state (N) formation, allow us to estimate relative populations of the rapidly converting states at various final urea concentrations.

Solvent-induced ligand dissociation and conformational states of Cellular Retinol-Binding Protein type I.

Cellular Retinol-Binding Protein type I (CRBP) exhibits very high affinity for its ligand, bound within a buried cavity completely shielded from the outside medium. Three-dimensional structure and backbone dynamics in aqueous solution at neutral pH, either in the absence or in the presence of retinol, fail to represent the protein in a state capable of ligand uptake and release. The question was asked whether changes in the composition of the outside medium might facilitate ligand dissociation.