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 role of conserved non-functional apomyoglobin residues in formation of native topology in the molten globule state of this protein is revealed. This fact allows suggesting that the conserved non-functional residues in this protein are indispensable for fixation and maintaining main elements of the correct topology of its secondary structure in the intermediate state. The correct topology is a native element in the intermediate state of the protein.

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. Its experimental detection and investigation in a cell are extremely difficult. In the last decades, intensive studies have demonstrated that the MG-like state of some globular proteins arises from either their modifications or interactions with protein partners or other cell components. This review summarizes such reports. In many cases, MG was evidenced to be functionally important. Thus, the MG state is quite common for functional cellular proteins. This supports Ptitsyn's hypothesis that some globular proteins may switch between two active states, rigid (N) and soft (MG), to work in solution or interact with partners.

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-ß 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. We investigated the effect of amino acid substitutions on propensity of the completely helical protein sperm whale apomyoglobin (sw ApoMb) for amyloid formation from its structured state in the absence of denaturing agents. Stability and aggregation of mutated sw ApoMb were studied using circular dichroism, Fourier transform infrared spectroscopy, x-ray diffraction, native electrophoresis, and electron microscopy techniques. Here, we demonstrate that stability of the protein native state determines both protein aggregation propensity and structural peculiarities of formed aggregates. Specifically, structurally stable mutants show low aggregation propensity and moderately destabilized sw ApoMb variants form amyloids, whereas their strongly destabilized mutants form both amyloids and nonamyloid aggregates.

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. The results gave evidence that proximity to a negatively charged membrane surface can cause destabilization of the structure of holomyoglobin, which delivers oxygen (O2) to mitochondria. It was shown that holoMb undergoes the native-to-intermediate-state transition in the presence of anionic phospholipid membranes at neutral pH, and that in this state it is able to interact with the membranes. When in the intermediate state, holoMb loses its rigid tertiary structure but preserves a pronounced secondary one. The presence of anionic phospholipid membranes substantially accelerates the process of deoxygenation. A possible functional role of the more flexible protein structure acquired in immediate proximity to the membrane surface is discussed.