Circum-hour cell rhythm: The biophysical mechanism and metabolic role

We consider the universal biophysical mechanism of circum-hour oscillations of the parameters and characteristics of different cells and their organelles resulting from nonspecific response of cells to various adverse factors. The mechanism of circum-hour oscillations is based on the inverse association between enzyme activities and the concentration of low-molecular-weight substances in the medium; this association had been found earlier. Automated scanning analyzers of microscopic objects have been used to demonstrate the universal nature of circum-hour oscillations. They are likely to be related an increase in metabolic rate in many objects, including cells and their organelles and compartments.     

Directed import of macromolecules into mitochondria

Mitochondria are multifunctional organelles of eukaryotic cells that provide the energy for the cells by oxidative phosphorylation, play an important role in the apoptosis and take part in Fe-S clusters formation, fatty acids oxidation and synthesis of some aminoacids. They contain their own genome and are able to transcribe and to translate it. However, the vast majority of the macromolecules which function inside the mitochondria are imported into these organelles from the cytoplasm. The imported macromolecules include proteins and several types of small RNAs. Protein import is a universal process and its mechanism is conserved among all species. This mechanism is now known in detail. RNA import was shown to occur in several groups of eukaryotes, while the pool of imported RNA molecules varies in different organisms. Although the knowledge about the mechanisms of RNA import is less extensive than for the proteins, it becomes clear that these mechanisms are not universal among all the species possessing this pathway. In this review, we summarize the data about the import of macromolecules mentioned above into mitochondria.     

Biophysical basis for principles of universality of speech perception

There is increasing evidence that the synergistic interaction of the objectively accepted low-frequency rhythm and the subjectively accepted high-frequency sound is a source of speech "sense". The lack of one of these components or of their synergistic interaction results in the loss of "sense" of the acoustic signal being perceived. As for the universality of perception of the sound component of speech, there is a model of sound perception, which ensures this universality. This model describes the dynamics of audition using the synchronization model of oscillations in the Ruell-Takens scenario of transition to chaos. The oscillations are described by Hopf bifurcations known to be structurally stable, which just provides the universality of sound perception. However, up till now, nothing was known about the mechanism of rhythm. It was shown in our study that the mechanism of rhythm is described by the Feigenbaum scenario of transition to chaos. Upon transition from oscillations to chaos, this scenario incorporates a critical point near which the dynamics of the system is described in an universal way.     

Characterization of the Drosophila lipid droplet subproteome

Lipid storage droplets are universal organelles essential for the cellular and organismal lipometabolism including energy homeostasis. Despite their apparently simple design they are proposed to participate in a growing number of cellular processes, raising the question to what extent the functional multifariousness is reflected by a complex organellar proteome composition. Here we present 248 proteins identified in a subproteome analysis using lipid storage droplets of Drosophila melanogaster fat body tissue. In addition to previously known lipid droplet-associated PAT (Perilipin, ADRP, and TIP47) domain proteins and homologues of several mammalian lipid droplet proteins, this study identified a number of proteins of diverse biological function, including intracellular trafficking supportive of the dynamic and multifaceted character of these organelles. We performed intracellular localization studies on selected newly identified subproteome members both in tissue culture cells and in fat body cells directly. The results suggest that the lipid droplets of fat body cells are of combinatorial protein composition. We propose that subsets of lipid droplets within single cells are characterized by a protein "zip code," which reflects functional differences or specific metabolic states.     

Sustained simultaneous glycolytic and insulin oscillations in beta-cells

Chemical oscillation in glycolysis induced by glucose is an universal feature in all living cells. In beta-cells this is accompanied by sustained oscillations of concentration of insulin, which helps to keep the blood glucose level within optimum limits. Experiments in this regard had shown that the glycolytic and insulin oscillations are almost consistently in phase and their time periods are very close to each other at both high and low initial concentration of glucose. Experiments have also demonstrated the dynamical transition between the states of glycolytic oscillations indicating a saturation behaviour of glucose transporters at a higher glucose flow rate. We propose a phenomenological model to understand these simultaneous oscillations and how glycolysis provides a mechanism for pulsatory insulin secretion in the light of these basic experimental issues.     

Organellar peptide deformylases: universality of the N-terminal methionine cleavage mechanism

Most mature proteins do not retain their initial N-terminal amino acid (methionine in the cytosol and N-formyl methionine in the organelles). Recent studies have shown that dedicated machinery is involved in this process in plants. In addition to cytosolic and organelle-targeted methionine aminopeptidases, organellar peptide deformylases have been identified. Here, we attempt to answer questions about the mechanism, specificity and significance of N-terminal methionine cleavage in plant organelles. It seems to be universal because orthologues of plant deformylases are found in most living organisms.     

Identification and characterization of coiled body-like structures in pea (Pisum sativum L.)

Coiled bodies (CBs) are nuclear organelles which were considered as "universal" nuclear structures in eukaryotic cells, but the formation and function of CBs, especially in plant cells, remained unclear. In this article we reported that CBs in meristematic cells of pea are oval to round obstacles in nucleus and in adjacent to nucleolus, often have the same electron density with nucleolus. We found that CBs could be stained by the rRNP preference staining method, but no rDNA was detected in the structure. Furthermore, our results of immunoelectron microscopy showed that several processing factors, include fibrillarin, U3 snoRNA and ITS1, were present in CB. It seems probable that CBs is derived structurally from nucleolus and act as transport, storage and processing subnucleolar organelles.     

Melanosome biogenesis: shedding light on the origin of an obscure organelle

Melanosomes are specialized intracellular organelles in which melanin pigments are synthesized and stored. The ontogenesis of these morphologically unique organelles, as well as their relationship to "conventional" organelles of the secretory and endocytic pathways, has for decades been a matter of study - and controversy. Recent work by the groups of Michael Marks and Gra?a Raposo has uncovered the molecular mechanism that results in the formation of the lumenal striations characteristic of melanosome precursor organelles.     

Regulation of pigment organelle translocation. I. Phosphorylation of the organelle-associated protein p57

Treatment of goldfish xanthophores with adrenocorticotropin (ACTH) or cyclic AMP (cAMP) induces the centrifugal movement of their pigment organelles from the center of the cells. Using purified xanthophores pulse labeled with 32Pi, we have shown that the dispersion of the organelles is accompanied by the phosphorylation of a pair of polypeptides, termed p57. After fractionation on sucrose gradients, nearly all of the p57 is found associated with the pigment organelles. The phosphorylation induced by ACTH or cAMP apparently occurs at multiple sites on p57. The minimal effective doses of ACTH or cAMP required to induce full pigment dispersion also fully stimulate the phosphorylation of p57. Increased phosphorylation of p57 is detectable within a minute after stimulating the cells and appears to be near completion during the early phases of pigment dispersion. Upon withdrawal of ACTH, these events are reversed; the pigment organelles reaggregate toward the center of the cells and p57 is dephosphorylated. Again, dephosphorylation commences soon after ACTH is withdrawn and is complete before the organelles have completely reaggregated. These results suggest a novel mechanism for governing the movement of these organelles which acts on the organelles themselves through the phosphorylation and dephosphorylation of p57.     

进化细胞生物学的提出及其任务

作者提出应创建一门源于进化生物学与细胞生物学两者的交叉学科一进化细胞生物学(细胞的进化生物学)。其根本任务在于用进化的观点考察真核细胞的一切方面,从它们的起源和演化来认识它们的现在。文中列举了其具体的研究内容,并分析了其研究方法上的特点,指出在这里需要把进化生物学的综合性分析与细胞生物学的实验研究最紧密地结合起来。文中还论述了真核细胞的细胞器的“不进化”现象,指出其根本原因在于进化焦点的转移。     

Direct Targeting of Proteins from the Cytosol to Organelles: The ER versus Endosymbiotic Organelles

In eukaryotic cells consisting of many different types of organelles, targeting of organellar proteins is one of the most fundamental cellular processes. Proteins belonging to the endoplasmic reticulum (ER), chloroplasts and mitochondria are targeted individually from the cytosol to their cognate organelles. As the targeting to these organelles occurs in the cytosol during or after translation, the most crucial aspect is how specific targeting to these three organelles can be achieved without interfering with other targeting pathways. For these organelles, multiple mechanisms are used for targeting proteins, but the exact mechanism used depends on the type of protein and organelle, the location of targeting signals in the protein and the location of the protein in the organelle. In this review, we discuss the various mechanisms involved in protein targeting to the ER, chloroplasts and mitochondria, and how the targeting specificity is determined for these organelles in plant cells .     

Directed import of macromolecules into mitochondria

Mitochondria are multifunctional eukaryotic organelles that provide cells with energy via oxidative phosphorylation. They participate in the formation of Fe-S clusters, oxidation of fatty acids, and synthesis of certain amino acids and play an important role in apoptosis. Mitochondria have their own genome and are able to transcribe and translate it. However, most macromolecules functioning in mitochondria, such as proteins and some small RNAs, are imported from the cytoplasm. Protein import into mitochondria is a universal process, and its mechanism is very similar in all eukaryotic cells. Today this mechanism is known in detail. At the same time, the RNA import was discovered only in several eukaryotic groups. Nevertheless, it is proposed that this process is typical for most species. A set of imported RNA molecules varies in different organisms. Although the knowledge about the mechanisms of RNA import is less extensive than that of protein import, it becomes clear that these mechanisms greatly differ between different species. The review summarizes information about the import of such macromolecules into mitochondria.     

Ribosomal RNA and the major lines of evolution: a perspective

Does the "universal tree" based on small-subunit ribosomal RNA sequences show the phylogenetic relationship of all modern organisms? The answer is "yes" only if all these rRNAs are orthologous. Herein I argue that the major rRNA lineages (e.g. eubacterial, one or more archaebacterial and eukaryotic nucleocytoplasmic) probably arose from a divergent population of rRNAs in the progenote, antedating the universal common ancestral organism. Thus the major lineages of rRNA are probably not orthologous, but paralogous. The extrapolated date for the origin of the common ancestral small-subunit rRNA (3.6-4.7 x 10(9) years ago) is consistent with major rRNA lineages being paralogous. This perspective on the early evolution of genes and organisms rationalizes the presence of unexpected ribosomal characters in microsporidia, and bears on xenogenous and endogenous theories of the origin of the organelles in eukaryotes.     

On the encoding and decoding of calcium signals in hepatocytes

Many different agonists use calcium as a second messenger. Despite intensive research in intracellular calcium signalling it is an unsolved riddle how the different types of information represented by the different agonists, is encoded using the universal carrier calcium. It is also still not clear how the information encoded is decoded again into the intracellular specific information at the site of enzymes and genes. After the discovery of calcium oscillations, one likely mechanism is that information is encoded in the frequency, amplitude and waveform of the oscillations. This hypothesis has received some experimental support. However, the mechanism of decoding of oscillatory signals is still not known. Here, we study a mechanistic model of calcium oscillations, which is able to reproduce both spiking and bursting calcium oscillations. We use the model to study the decoding of calcium signals on the basis of co-operativity of calcium binding to various proteins. We show that this co-operativity offers a simple way to decode different calcium dynamics into different enzyme activities.     

Enzyme-substrate mode of action for bacteria survival in water biotic community

The role of enzyme--substrate interactions for the survival of bacteria in natural biocenoses has been analyzed with the systems "lysozyme-antilysozyme", "histon-antihiston" used as models. The conception of a possible universal mechanism for supporting the circulation of pathogenic and opportunistic microorganisms among eukaryotes, irrespective of their evolutionary status and environment, has been formulated. This mechanism is ensured by the natural resistance of the eukaryotic cells and by persistence factors on the part of the pathogen; as a result, the dynamic system of interactions is formed which facilitates the survival of microorganisms due to their persistence potential. New knowledge thus obtained opens prospects in the study of sanitary and ecological aspects of water biocenoses.     

Biogenesis of the protein storage vacuole crystalloid

We identify new organelles associated with the vacuolar system in plant cells. These organelles are defined biochemically by their internal content of three integral membrane proteins: a chimeric reporter protein that moves there directly from the ER; a specific tonoplast intrinsic protein; and a novel receptor-like RING-H2 protein that traffics through the Golgi apparatus. Highly conserved homologues of the latter are expressed in animal cells. In a developmentally regulated manner, the organelles are taken up into vacuoles where, in seed protein storage vacuoles, they form a membrane-containing crystalloid. The uptake and preservation of the contents of these organelles in vacuoles represents a unique mechanism for compartmentalization of protein and lipid for storage.     

Development of crystalline peroxisomes in methanol-grown cells of the yeast Hansenula polymorpha and its relation to environmental conditions

The development of peroxisomes has been studied in cells of the yeast Hansenula polymorpha during growth on methanol in batch and chemostat cultures. During bud formation, new peroxisomes were generated by the separation of small peroxisomes from mature organelles in the mother cells. The number of peroxisomes migrating to the buds was dependent upon environmental conditions. Aging of cells was accompanied by an increase in size of the peroxisomes and a subsequent increase in their numbers per cell. Their ultimate shape and substructure as well as their number per cell was dependent upon the physiological state of the culture. The change in number and volume density of peroxisomes was related to the level of alcohol oxidase in the cells. Development of peroxisomes in cells of batch cultures was accompanied by an increase in size of the crystalline inclusions in the organelles; they had become completely crystalline when the cells were in the stationary phase. Peroxisomes in cells from methanol-limited chemostat cultures were completely crystalline, irrespective of growth rate. Results of biochemical and cytochemical experiments suggested that alcohol oxidase is a major component of the crystalline inclusions in the peroxisomes of methanol-grown Hansenula polymorpha. Possible mechanisms involved in the ultrastructural changes in peroxisomes during their development have been discussed.Abbreviations DAB 3,3-diaminobenzidine - OD optical density (663 nm)     

How yeast cells synchronize their glycolytic oscillations: a perturbation analytic treatment

Of all the lifeforms that obtain their energy from glycolysis, yeast cells are among the most basic. Under certain conditions the concentrations of the glycolytic intermediates in yeast cells can oscillate. Individual yeast cells in a suspension can synchronize their oscillations to get in phase with each other. Although the glycolytic oscillations originate in the upper part of the glycolytic chain, the signaling agent in this synchronization appears to be acetaldehyde, a membrane-permeating metabolite at the bottom of the anaerobic part of the glycolytic chain. Here we address the issue of how a metabolite remote from the pacemaking origin of the oscillation may nevertheless control the synchronization. We present a quantitative model for glycolytic oscillations and their synchronization in terms of chemical kinetics. We show that, in essence, the common acetaldehyde concentration can be modeled as a small perturbation on the "pacemaker" whose effect on the period of the oscillations of cells in the same suspension is indeed such that a synchronization develops.     

Origin of life: protoribosome forms peptide bonds and links RNA and protein dominated worlds

Although the mode of action of the ribosomes, the multi-component universal effective protein-synthesis organelles, has been thoroughly explored, their mere appearance remained elusive. Our earlier comparative structural studies suggested that a universal internal small RNA pocket-like segment called by us the protoribosome, which is still embedded in the contemporary ribosome, is a vestige of the primordial ribosome. Herein, after constructing such pockets, we show using the "fragment reaction" and its analyses by MALDI-TOF and LC–MS mass spectrometry techniques, that several protoribosome constructs are indeed capable of mediating peptide-bond formation. These findings present strong evidence supporting our hypothesis on origin of life and on ribosome''s construction, thus suggesting that the protoribosome may be the missing link between the RNA dominated world and the contemporary nucleic acids/proteins life.