Native aggregation as a cause of origin of temporary cellular structures needed for all forms of cellular activity, signaling and transformations
TL;DR: According to the hypothesis explored in this paper, native aggregation is genetically controlled (programmed) reversible aggregation that occurs when interacting proteins form new temporary structures through highly specific interactions.
Abstract: According to the hypothesis explored in this paper, native aggregation is genetically controlled (programmed) reversible aggregation that occurs when interacting proteins form new temporary structures through highly specific interactions. It is assumed that Anfinsen's dogma may be extended to protein aggregation: composition and amino acid sequence determine not only the secondary and tertiary structure of single protein, but also the structure of protein aggregates (associates). Cell function is considered as a transition between two states (two states model), the resting state and state of activity (this applies to the cell as a whole and to its individual structures). In the resting state, the key proteins are found in the following inactive forms: natively unfolded and globular. When the cell is activated, secondary structures appear in natively unfolded proteins (including unfolded regions in other proteins), and globular proteins begin to melt and their secondary structures become available for interaction with the secondary structures of other proteins. These temporary secondary structures provide a means for highly specific interactions between proteins. As a result, native aggregation creates temporary structures necessary for cell activity. "One of the principal objects of theoretical research in any department of knowledge is to find the point of view from which the subject appears in its greatest simplicity." Josiah Willard Gibbs (1839-1903)
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TL;DR: Low molecular-weight metabolites (LMWMs) as discussed by the authors comprise primary or central and a plethora of intermediary or secondary metabolites, all of which are characterized by a molecular weight below 900 Dalton.
Abstract: Low-molecular-weight metabolites (LMWMs) comprise primary or central and a plethora of intermediary or secondary metabolites, all of which are characterized by a molecular weight below 900 Dalton. The latter are especially prominent in sessile higher organisms, such as plants, corals, sponges and fungi, but are produced by all types of microbial organisms too. Common to all of these carbon molecules are oxygen, nitrogen and, to a lesser extent, sulfur, as heteroatoms. The latter can contribute as electron donators or acceptors to cellular redox chemistry and define the potential of the molecule to enter charge-transfer complexes. Furthermore, they allow LMWMs to serve as organic ligands in coordination complexes of various inorganic metals as central atoms. Especially the transition metals Fe, Cu and Mn can catalyze one electron reduction of molecular oxygen, which results in formation of free radical species and reactive follow-up reaction products. As antioxidants LMWMs can scavenge free radicals. Depending on the chemical environment, the same LMWMs can act as pro-oxidants by reducing molecular oxygen. The cellular regulation of redox homeostasis, a balance between oxidation and reduction, is still far from being understood. Charge-transfer and coordination complex formation with metals shapes LMWMs into gel-like matrices in the cytosol. The quasi-polymer structure is lost usually during the isolation procedure. In the gel state, LMWMs possess semiconductor properties. Also proteins and membranes are semiconductors. Together they can represent biotransistor components that can be part of a chemoelectrical signaling system that coordinates systems chemistry by initiating cell differentiation or tissue homeostasis, the activated and the resting cell state, when it is required. This concept is not new and dates back to Albert Szent-Gyorgyi.
30 citations
TL;DR: The evidence is given that the first protocells may have been formed on the basis of intrinsically disordered peptides, and available data on the similarity of the physical properties of cell models and living cells allow the Virchow's postulate to be rephrase as follows.
Abstract: Cell theory, as formulated by Theodor Schwann in 1839, introduced the idea that the cell is the main structural unit of living nature. Later, in solving the problem of cell multiplication, Rudolf Virchow expanded the cell theory with a postulate: all cells only arise from pre-existing cells. But what did the very first cell arise from? This paper proposes extending the Virchow's law by the assumption that between the nonliving protocell and the first living cell the continuity of fundamental physical properties (the principle of invariance of physical properties) is preserved. The protocell is understood here as a cell-shaped physical system on the basis of the self-organized biologically significant prebiotic macromolecules, primarily peptides, having a potential to transform into the living cell. Biophase is considered as the physical basis of the membraneless protocell, the internal environment of which is separated from the external environment due to the phase of adsorbed water. The evidence is given that the first protocells may have been formed on the basis of intrinsically disordered peptides. Data on the similarity of the physical properties of living cells and the following model systems are given: protein and artificial polymer solutions, coacervate droplets, and ion-exchange resin granules. Available data on the similarity of the physical properties of cell models and living cells allow us to rephrase the Virchow's postulate as follows: the physical properties of a living cell could only arise from pre-existing physical properties of the protocell.
25 citations
TL;DR: The ATP effect on protein aggregation was ambiguous: ATP alone had no effect on the protein’s thermal stability but it facilitated protein‘s destabilization in the presence of nitric oxide.
Abstract: Background and objective
Regulating protein function in the cell by small molecules, provide a rapid, reversible and tunable tool of metabolic control. However, due to its complexity the issue is poorly studied so far. The effects of small solutes on protein behavior can be studied by examining changes of protein secondary structure, in its hydrodynamic radius as well as its thermal aggregation. The study aim was to investigate effects of adenosine-5’-triphosphate (ATP), spermine NONOate (NO donor) as well as sodium/potassium ions on thermal aggregation of albumin and hemoglobin. To follow aggregation of the proteins, their diffusion coefficients were measured by quasi-elastic light scattering (QELS) at constant pH (7.4) in the presence of solutes over a temperature range from 25°C to 80°C.
18 citations
Cites background from "Native aggregation as a cause of or..."
...Discussion Protein aggregation plays an important role in the cellular biology and in many applications of protein science and medical engineering [28]....
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Journal Article•
17 citations
TL;DR: Ling's theory is a complete quantitative theory with corroborated equations for solute distribution, transport, cell potentials and osmotic behaviour and describing the cell's energy cycle and IDP's are involved in all this.
Abstract: The example of gelatine shows that extended proteins behave quite differently than globular ones: with water they form a gel. Historically the colloid view of protoplasm was discredited in favour of membrane-(pump)-theory (MPT), but unjustified. In his association-induction hypothesis Ling demonstrates that MPT is full of contradictions and that the colloid view has to be re-considered. In that case IDP's play a crucial role in this. What Ling calls the ‘living state’ consists of the unitary protoplasmic structure from which it was experimentally demonstrated that it can survive and keep Na+ and K+ concentrations without a delineating membrane. It consists of unfolded polypeptide chains whereby the repetitive backbone peptide groups orient and polarise many layers of water, in which Na+ and other solutes have reduced solubility and whereby the polypeptide β- and ϒ-carboxyl-groups adsorb K+. This ‘associated’ state is the resting state: a coherent high-energy low-entropy meta-stable state. It can be kept by adsorbed ATP (NTP) eventually for years without consumption of ATP as demonstrated by Clegg on Artemia embryo's. Stimuli can transform this state into a lower-energy higher-entropy action state with dissociation of ADP and Pi and newly synthesised ATP can reinstall it. Rest-to-action and action-to-rest were shown to be real phase-shifts. Ling's theory is a complete quantitative theory with corroborated equations for solute distribution, transport, cell potentials and osmotic behaviour and describing the cell's energy cycle. IDP's are involved in all this. The new view on IDP's leads to new insights on the origin of life.
17 citations
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246 citations
TL;DR: Evidence is presented that this finding is not an artifact, and that solute-repulsion forces exist at distances far greater than conventional theory predicts, which implies that solutes may interact over an unexpectedly long range.
Abstract: Aqueous suspensions of microspheres were infused around gels of varying composition. The solutes were excluded from zones on the order of 100 \ensuremath{\mu}m from the gel surface. We present evidence that this finding is not an artifact, and that solute-repulsion forces exist at distances far greater than conventional theory predicts. The observations imply that solutes may interact over an unexpectedly long range.
204 citations
"Native aggregation as a cause of or..." refers background in this paper
...There is convincing experimental evidence to substantiate this point of view about the interaction of polypeptides and other hydrophilic polymers with water [28,29]....
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TL;DR: Two emerging areas are the application of microwave heating for the synthesis of peptides, peptoids, oligopeptides and carbohydrates and in the field of proteomics.
Abstract: As the range of techniques for microwave heating has expanded, so have the areas in which it can have a profound impact. Two emerging areas are the application of microwave heating for the synthesis of peptides, peptoids, oligopeptides and carbohydrates and in the field of proteomics.
181 citations
Book•
01 Jan 1984TL;DR: It is vital to know “What are the fundamental distinctions between a living cell and a dead one?”
Abstract: The living cell is the basic unit of life. Toward understanding of the living phenomenon in general and toward the erection of a solid foundation for future biomedical research it is vital to know “What are the fundamental distinctions between a living cell and a dead one?”
161 citations
TL;DR: In this article, a molecular modeling of an intact bacterial chemotaxis receptor based on the crystal structures of a cytoplasmic domain and a periplasmic domains suggests an interesting clustering of three dimeric receptors and a two-dimensional, close-packed lattice formation of the clusters, where each receptor dimer contacts two other receptor dimers at the cytoplasic domain, and two yet different receptor dimmers at the periplasic domain.
Abstract: Bacterial chemotaxis receptors can detect a small concentration gradient of attractants and repellents in the environment over a wide range of background concentration. The clustering of these receptors to form patches observed in vivo and in vitro has been suspected as a reason for the high sensitivity, and such wide dynamic range is thought to be due to the resetting of the receptor sensitivity threshold by methylation/demethylation of the receptors. However, the mechanisms by which such high sensitivity is achieved and how the methylation/demethylation resets the sensitivity are not well understood. A molecular modeling of an intact bacterial chemotaxis receptor based on the crystal structures of a cytoplasmic domain and a periplasmic domain suggests an interesting clustering of three dimeric receptors and a two-dimensional, close-packed lattice formation of the clusters, where each receptor dimer contacts two other receptor dimers at the cytoplasmic domain and two yet different receptor dimers at the periplasmic domain. This interconnection of the receptors to form a patch of receptor clusters suggests a structural basis for the high sensitivity of the bacterial chemotaxis receptors. Furthermore, we present crystallographic data suggesting that, in contrast to most molecular signaling by conformational changes and/or oligomerization of the signaling molecules, the changes in dynamic property of the receptors on ligand binding or methylation may be the language of the signaling by the chemotaxis receptors. Taken together, the changes of the dynamic property of one receptor propagating mechanically to many others in the receptor patch provides a plausible, simple mechanism for the high sensitivity and the dynamic range of the receptors.
161 citations
"Native aggregation as a cause of or..." refers background in this paper
...[41] studied the dynamics of the cytoplasmic domains of the E....
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