On the origin of eukaryotic cells and their endomembranes.

A novel hypothesis for the origin of eukaryotic cells is presented. It is assumed that the universal ancestor was bounded by two membranes of heterochiral lipid composition. We propose that the prokaryotic cells (the hypothetical host entity for alpha proteic-bacteria), though sharing a common ancestor with Archaea, was bounded by two membranes. The hypothesis suggests that an alpha proteic-bacterial symbiont was enclosed in the prokaryotic cells intermembrane space. In this view, the eukaryotic nuclear membrane and endomembrane system arose from the prokaryotic cells inner membrane while the eukaryotic plasma membrane arose from the prokaryotic cells outer membrane. The outlined scenario agrees with the view that engulfment of an alpha-proteic-bacterial cell by a host entity and its transformation to a mitochondrion was the driving force leading to the appearance of the first eukaryotic cell. The hypothesis seems to be consistent with the pre-cell theory, theory of membrane heredity, and the phagocytosis-late scenario.     

A New Aspect to the Origin and Evolution of Eukaryotes

One of the most important omissions in recent evolutionary theory concerns how eukaryotes could emerge and evolve. According to the currently accepted views, the first eukaryotic cell possessed a nucleus, an endomembrane system, and a cytoskeleton but had an inefficient prokaryotic-like metabolism. In contrast, one of the most ancient eukaryotes, the metamonada Giardia lamblia, was found to have formerly possessed mitochondria. In sharp contrast with the traditional views, this paper suggests, based on the energetic aspect of genome organization, that the emergence of eukaryotes was promoted by the establishment of an efficient energy-converting organelle, such as the mitochondrion. Mitochondria were acquired by the endosymbiosis of ancient α-purple photosynthetic Gram-negative eubacteria that reorganized the prokaryotic metabolism of the archaebacterial-like ancestral host cells. The presence of an ATP pool in the cytoplasm provided by this cell organelle allowed a major increase in genome size. This evolutionary change, the remarkable increase both in genome size and complexity, explains the origin of the eukaryotic cell itself. The loss of cell wall and the appearance of multicellularity can also be explained by the acquisition of mitochondria. All bacteria use chemiosmotic mechanisms to harness energy; therefore the periplasm bounded by the cell wall is an essential part of prokaryotic cells. Following the establishment of mitochondria, the original plasma membrane-bound metabolism of prokaryotes, as well as the funcion of the periplasm providing a compartment for the formation of different ion gradients, has been transferred into the inner mitochondrial membrane and intermembrane space. After the loss of the essential function of periplasm, the bacterial cell wall could also be lost, which enabled the naked cells to establish direct connections among themselves. The relatively late emergence of mitochondria may be the reason why multicellularity evolved so slowly. Received: 29 May 1997 / Accepted: 9 October 1997     

Prenylation: From bacteria to eukaryotes

For their protection from host cell immune defense, intracellular pathogens of eukaryotic cells developed a variety of mechanisms, including secretion systems III and IV which can inject bacterial effectors directly into eukaryotic cells. These effectors may function inside the host cell and may be posttranslationally modified by host cell machinery. Recently, prenylation was added to the list of possible posttranslational modifications of bacterial proteins. In this work we describe the current state of the knowledge about the prenylation of eukaryotic and prokaryotic proteins and prenylation inhibitors. The bioinformatics analyses suggest the possibility of prenylation for a number of Francisella genus proteins.     

Host cell phospholipids are trafficked to and then modified by Chlamydia trachomatis.

There is little information on the trafficking of eukaryotic lipids from a host cell to either the cytoplasmic membrane of or the vacuolar membrane surrounding intracellular pathogens. Purified Chlamydia trachomatis, an obligate intracellular bacterial parasite, contains several eukaryotic glycerophospholipids, yet attempts to demonstrate transfer of these lipids to the chlamydial cell membrane have not been successful. In this report, we demonstrate that eukaryotic glycerophospholipids are trafficked from the host cell to C. trachomatis. Phospholipid trafficking was assessed by monitoring the incorporation of radiolabelled isoleucine, a precursor of C. trachomatis specific branched-chain fatty acids, into host-derived glycerophospholipids and by monitoring the transfer of host phosphatidylserine to chlamydiae and its subsequent decarboxylation to form phosphatidylethanolamine. Phospholipid trafficking to chlamydiae was unaffected by brefeldin A, an inhibitor of Golgi function. Furthermore, no changes in trafficking were observed when C. trachomatis was grown in a mutant cell line with a nonfunctional, nonspecific phospholipid transfer protein. Host glycerophospholipids are modified by C. trachomatis, such that a host-synthesized straight-chain fatty acid is replaced with a chlamydia-synthesized branched-chain fatty acid. We also demonstrate that despite the acquisition of host-derived phospholipids, C. trachomatis is capable of de novo synthesis of phospholipids typically synthesized by prokaryotic cells. Our results provide novel information on chlamydial phospholipid metabolism and eukaryotic cell lipid trafficking, and they increase our understanding of the evolutionary steps leading to the establishment of an intimate metabolic association between an obligate intracellular bacterial parasite and a eukaryotic host cell.     

Evolution of Protein Targeting into “Complex” Plastids: The “Secretory Transport Hypothesis”

Abstract: In algae different types of plastids are known, which vary in pigment content and ultrastructure, providing an opportunity to study their evolutionary origin. One interesting feature is the number of envelope membranes surrounding the plastids. Red algae, green algae and glaucophytes have plastids with two membranes. They are thought to originate from a primary endocytobiosis event, a process in which a prokaryotic cyanobacterium was engulfed by a eukaryotic host cell and transformed into a plastid. Several other algal groups, like euglenophytes and heterokont algae (diatoms, brown algae, etc.), have plastids with three or four surrounding membranes, respectively, probably reflecting the evolution of these organisms by so‐called secondary endocytobiosis, which is the uptake of a eukaryotic alga by a eukaryotic host cell. A prerequisite for the successful establishment of primary or secondary endocytobiosis must be the development of suitable protein targeting machineries to allow the transport of nucleus‐encoded plastid proteins across the various plastid envelope membranes. Here, we discuss the possible evolution of such protein transport systems. We propose that the secretory system of the respective host cell might have been the essential tool to establish protein transport into primary as well as into secondary plastids.     

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。     

The "pro-apoptotic genies" get out of mitochondria: oxidative lipidomics and redox activity of cytochrome c/cardiolipin complexes

One of the prominent consequences of the symbiogenic origin of eukaryotic cells is the unique presence of one particular class of phospholipids, cardiolipin (CL), in mitochondria. As the product originated from the evolution of symbiotic bacteria, CL is predominantly confined to the inner mitochondrial membrane in normally functioning cells. Recent findings identified CL and its oxidation products as important participants and signaling molecules in the apoptotic cell death program. Early in apoptosis, massive membrane translocations of CL take place resulting in its appearance in the outer mitochondrial membrane. Consequently, significant amounts of CL become available for the interactions with cyt c, one of the major proteins of the intermembrane space. Binding of CL with cytochrome c (cyt c) yields the cyt c/CL complex that acts as a potent CL-specific peroxidase and generates CL hydroperoxides. In this review, we discuss the catalytic mechanisms of CL oxidation by the peroxidase activity of cyt c as well as the role of oxidized CL (CLox) in the release of pro-apoptotic factors from mitochondria into the cytosol. Potential implications of cyt c/CL peroxidase intracellular complexes in disease conditions (cancer, neurodegeneration) are also considered. The discovery of the new role of cyt c/CL complexes in early mitochondrial apoptosis offers interesting opportunities for new targets in drug discovery programs. Finally, exit of cyt c from damaged and/or dying (apoptotic) cells into extracellular compartments and its accumulation in biofluids is discussed in lieu of the formation of its peroxidase complexes with negatively charged lipids and their significance in the development of systemic oxidative stress in circulation.     

细胞核起源研究的意义和研究途径的探讨

细胞核的起源是真核细胞进化形成的关键。回顾了过去几十年国内外对细胞核起源问题的探索历程,通过多年的摸索找到了一个条切实可行的探索细胞核起源问题的途径。其要点：在一系列的进化环节中首先抓住原始性的细胞核这一重要环节,探明原始性细胞核的特性,解决了从原始核到典型细胞核的进化问题,原始性细胞核自身的起源问题也就有了基础,为探源始性细胞核的特性,需要在现存的原生生物中间寻找最原始的类群,然后对它们的细胞核进行尽可能深入地和多方面地研究,对所得结果作进化地分析,以期提出一个原始性细胞核的模型,依据这个模型也就可对典型的细胞核的进化形成和原始核自身的起源作出推论,而这个原始性细胞核的模型,依据这个模型也就可以对典型细胞核的进化形成和原始核自身的起源作出推论,这些推论是可以设法加以检验的,不仅可以检验这些推论的正确性,而且对原始核模型的建立是重要的,可以据之加以发展,修正,甚至否定,沿此途径已经否定了原始性细胞核的涡鞭毛虫核模型,进而提出了双滴虫核模型。     

Bacterial remodelling of the host epigenome: functional role and evolution of effectors methylating host histones

The modulation of the chromatin organization of eukaryotic cells plays an important role in regulating key cellular processes including host defence mechanisms against pathogens. Thus, to successfully survive in a host cell, a sophisticated bacterial strategy is the subversion of nuclear processes of the eukaryotic cell. Indeed, the number of bacterial proteins that target host chromatin to remodel the host epigenetic machinery is expanding. Some of the identified bacterial effectors that target the chromatin machinery are ‘eukaryotic‐like’ proteins as they mimic eukaryotic histone writers in carrying the same enzymatic activities. The best‐studied examples are the SET domain proteins that methylate histones to change the chromatin landscape. In this review, we will discuss SET domain proteins identified in the Legionella, Chlamydia and Bacillus genomes that encode enzymatic activities targeting host histones. Moreover, we discuss their possible origin as having evolved from prokaryotic ancestors or having been acquired from their eukaryotic hosts during their co‐evolution. The characterization of such bacterial effectors as modifiers of the host chromatin landscape is an exciting field of research as it elucidates new bacterial strategies to not only manipulate host functions through histone modifications but it may also identify new modifications of the mammalian host cells not known before.     

The origin of the eukaryotic cell. I. Historical sources and current state of the concept of symbiotic and autogenic origins of the cell

The exogenous (symbiotic) conception of the eukaryotic origin is now widely spread. It is based on the recognition of the principle of combination (addition or enclosing) of diverse prokaryotic organisms; so the complicated unicellular eukaryotic organism (eukaryotic cell) was resulted. the principle of combination takes its historical scientific sources from the ideas of Buffon. With reference to the cell this principle was claimed for the first time. In our time the exogenous conception is characterized as a "symbiotic boom", because it is widely used in attempts to explain the origin of all the main organelles of the cell (right up to the micro-bodies). The autogenetic (endogenous) conception is based on the principle of straight phyliation, on the recognition of a successive evolutionary transformation of prokaryotic forms into eukaryotic ones. In this way all the cell organelles may have an endogenous origin. This principle springing from Lamarck has got a contemporary meaning in the doctrine of Darwin. In the next papers the author will present his own analysis and generation of the present day relevant facts to find out which of these two conceptions based on quite different scientific methodological principles may be correct.     

Emerging facets of plastid division regulation

Plastids are complex organelles that are integrated into the plant host cell where they differentiate and divide in tune with plant differentiation and development. In line with their prokaryotic origin, plastid division involves both evolutionary conserved proteins and proteins of eukaryotic origin where the host has acquired control over the process. The plastid division apparatus is spatially separated between the stromal and the cytosolic space but where clear coordination mechanisms exist between the two machineries. Our knowledge of the plastid division process has increased dramatically during the past decade and recent findings have not only shed light on plastid division enzymology and the formation of plastid division complexes but also on the integration of the division process into a multicellular context. This review summarises our current knowledge of plastid division with an emphasis on biochemical features, the functional assembly of protein complexes and regulatory features of the overall process.     

Origin of phagotrophic eukaryotes as social cheaters in microbial biofilms

Background  

The origin of eukaryotic cells was one of the most dramatic evolutionary transitions in the history of life. It is generally assumed that eukaryotes evolved later then prokaryotes by the transformation or fusion of prokaryotic lineages. However, as yet there is no consensus regarding the nature of the prokaryotic group(s) ancestral to eukaryotes. Regardless of this, a hardly debatable fundamental novel characteristic of the last eukaryotic common ancestor was the ability to exploit prokaryotic biomass by the ingestion of entire cells, i.e. phagocytosis. The recent advances in our understanding of the social life of prokaryotes may help to explain the origin of this form of total exploitation.     

Symbionticism revisited: a discussion of the evolutionary impact of intracellular symbioses.

Wallin (1927) first published the notion that the fusion of bacteria with host cells was the principal source of genetic novelty for speciation. He suggested that mitochondria are transitional elements in this process. While the significance that he attributed to symbiosis now seem excessive, he was one of the first authors to be aware of the evolutionary potential of symbiotic events and his view of mitochondria may not seem strange to many cell biologist today. The most significant evolutionary development which has been attributed to intracellular symbiosis is the origin of eukaryotic cellular organization. The current status of the 'serial endosymbiosis hypothesis' is briefly review. The case for the symbiotic origin of the chloroplast, based principally on 16 S RNA oligonucleotide cataloguing, is very strong. Mitochondrial origins are more obscure but also appear to be symbiotic due to recent 18 S cataloguing from wheat embryos. The probablility of the multiple origin of some eukaryotic organelles is also examined, the processes in question being the acquisition of distinct stocks of chloroplasts from disparate photosynthetic prokaryotes and the secondary donation of organelles from degenerate eukaryotic endosymbionts to their hosts, with specific reference to the dinoflagellates Peridinium balticum, Kryptoperidinium foliaceum and the ciliate Mesodinium rubrum. It is concluded that the evolutionary potential of intracellular symbiosis ('cytobiosis': a term introduced in this paper) is great, with the best established influence being on the origin of eukaryotic chloroplasts. Together with the potential effects of viral vectors, symbiosis serves as a supplementary speciation mechanism capable of producing directed evolutionary changes. It is likely that these processes will explain some of the apparent anomalies in evolutionary rates and direction which are not readily explicable by the conventional synthetic theory of evolution.     

The origin of the eukaryotic cell. IV. The general hypothesis of the autogenous origin of eukaryotes

The general hypothesis of autogenous (non-symbiotic) origin of the eukaryotic cell summarises some hypotheses explaining possible ways of the origin of main components and organelles of such a cell (the primary unicellular protist). Six hypothesises are suggested. Arising of the eukaryotic surface membrane of protist (cell) as a result of modification of its lipidoacidic composition, when most of synblocks and ensembles of eukaryotic enzymes sink into the cytoplasm (due to membrane vesiculation). Establishment of eukaryotic cytoplasm on the basis of successive formation of two locomotory-supporting apparates: the primary one (microtrabecular system), and the second one (cytoskeleton). Arising of the nucleus from a polyheteronomous nucleoid of proeukaryotes. A combinatorical hypothesis of mitosis formation. Polyheteronucleoid hypothesis of the origin of the mitochondria and chloroplasts. Arising of the flagellum from the contractile tentacle-like organelle, whose axoneme is made of single microtubules. A close interrelation and interaction in the process of evolution is noted between surface membranes, the cytoplasm and the nucleus. In accord a principles of block-construction and heterochrony (see: Seravin, 1986r), the author explains the preservation of prokaryotic signs of organization in some components (and organelles) of eukaryotic cell (and protists).     

Phylogenetic affinities between eukaryotic cells and a thermophilic mycoplasma

Thermoplasma acidophilum, a thermophilic mycoplasma, has several unusual features suggesting a possible relationship to eukaryotic cells. One feature is a histone-like protein that is associated with the DNA, condensing it into subunits similar to those in eukaryotic chromatin. A second feature is an association of cytoplasmic proteins that resembles eukaryotic actin and myosin. These two components are widely distributed in different groups of eukaryotic cells, but are typically lacking in prokaryotic cells. Furthermore, T. acidophilum lacks cytochromes and respires by enzymes that apparently are not coupled to oxidative phosphorylation. This primitive type of respiration resembles that of microbodies, another feature which is represented in the cytoplasm of all groups of eukaryotic cells. Furthermore, since T. acidophilum lacks a cell wall and appears to have a primitive correlate of endocytosis, it would appear to be mechanically capable of acquiring a symbiotic mitochondrion. Thus, our observations are consistent with the symbiotic hypothesis for the origin of eukaryotic cells. We suggest that an organism similar to T. acidophilum was the host cell for the original symbiosis, becoming the nucleus and cytoplasm of modern eukaryotic cells.     

The hidden side of the prokaryotic cell: rediscovering the microbial world.

How many different forms of life exist and how they are evolutionarily related is one of the most challenging problems in biology. In 1962, Roger Y. Stanier and Cornelis B. van Niel proposed "the concept of a bacterium" and thus allowed (micro)biologists to divide living organisms into two primary groups: prokaryotes and eukaryotes. Initially, prokaryotes were believed to be devoid of any internal organization or other characteristics typical of eukaryotes, due to their minute size and deceptively simple appearance. However, the last few decades have demonstrated that the structure and function of the prokaryotic cell are much more intricate than initially thought. We will discuss here two characteristics of prokaryotic cells that were not known to Stanier and van Niel but which now allow us to understand the basis of many characteristics that are fully developed in eukaryotic cells: First, it has recently become clear that bacteria contain all of the cytoskeletal elements present in eukaryotic cells, demonstrating that the cytoskeleton was not a eukaryotic invention; on the contrary, it evolved early in evolution. Essential processes of the prokaryotic cell, such as the maintenance of cell shape, DNA segregation, and cell division, rely on the cytoskeleton. Second, the accumulation of intracellular storage polymers, such as polyhydroxyalkanoates (a property studied in detail by Stanier and colleagues), provides a clear evolutionary advantage to bacteria. These compounds act as a "time-binding" mechanism, one of several prokaryotic strategies to increases survival in the Earth's everchanging environments.     

An overview of endosymbiotic models for the origins of eukaryotes, their ATP-producing organelles (mitochondria and hydrogenosomes), and their heterotrophic lifestyle.

The evolutionary processes underlying the differentness of prokaryotic and eukaryotic cells and the origin of the latter's organelles are still poorly understood. For about 100 years, the principle of endosymbiosis has figured into thoughts as to how these processes might have occurred. A number of models that have been discussed in the literature and that are designed to explain this difference are summarized. The evolutionary histories of the enzymes of anaerobic energy metabolism (oxygen-independent ATP synthesis) in the three basic types of heterotrophic eukaryotes those that lack organelles of ATP synthesis, those that possess mitochondria and those that possess hydrogenosomes--play an important role in this issue. Traditional endosymbiotic models generally do not address the origin of the heterotrophic lifestyle and anaerobic energy metabolism in eukaryotes. Rather they take it as a given, a direct inheritance from the host that acquired mitochondria. Traditional models are contrasted to an alternative endosymbiotic model (the hydrogen hypothesis), which addresses the origin of heterotrophy and the origin of compartmentalized energy metabolism in eukaryotes.     

Protein export from Plasmodium parasites

Many prokaryotic and eukaryotic intracellular pathogens survive by altering the host cell through the export of proteins. In contrast to the well-studied prokaryotic export systems, knowledge of protein export in eukaryotic pathogens is scant. The recent discovery that a short protein sequence targets a protein for export from the malaria parasite Plasmodium falciparum has shed light on the possible mechanism of proteins export and has allowed the preliminary identification of several hundred exported proteins. Among the exported proteins are the members of the paralogous protein families, previously identified exported proteins and many uncharacterized proteins. The interaction of the parasite with the host cell is thus much more complex, and involves more parasite proteins, than previously thought.     

Symbiogenesis as Evolution of Open Genetic Systems

The evolution of intracellular symbioses formed by bacteria with plants and animals is addressed as a model for reconstructing the origin of eukaryotic cells as a symbiosis between different forms of prokaryotes (symbiogenesis). In microorganisms that are in facultative or conditionally obligatory (ecologically obligatory) dependence on symbiosis, their gene networks arise on the basis of host-activated intragenomic rearrangements and horizontal gene transfer. The latter factor determines the evolution of the genomes of symbiotic bacteria as open genetic systems (OGSs), in which the ratio of accessory genome regions to its core regions is increased compared to free-living relatives. Coevolution of bacteria and eukaryotic hosts results in the formation of higher rank OGSs, symbiogenomes, the integrity of which is mediated by signaling interactions that determine cross-regulation of partner genes. Increasing the effectiveness of their cooperation is achieved with the transition of bacteria to strictly obligatory (genetically obligatory) dependence on hosts, determined by (a) the loss of considerable regions of the microbial genome encoding the functions of autonomous development and (b) adaptation of bacteria to permanent intracellular existence, endocytobiosis. At this stage, symbiogenomes acquire the status of inheritance systems, determined by vertical (as a rule, transovarial) transfer of microsymbionts through host generations. The transformation of endocytobionts into cellular organelles is associated with the loss of their genetic autonomy, i.e., the ability to maintain and express their rudimentary genomes, until their complete loss. However, organelles partially retain phenotypic identity of ancestral bacteria, which is determined by the importation from the host cell of the gene products (proteins, RNA) obtained earlier from microsymbionts, which led to the formation of structurally integrated hologenomes. The gene loss and gain strategy realized in this way led to the formation of different patterns of eukaryotic cell organization in accordance with the mosaic scenario, which includes sequential introduction of several symbionts into the host cell, or with the matryoshka doll scenario, in which new symbionts are introduced into the cells of previously acquired symbionts.