Conformational studies on nucleotide-amino acid interactions leading to origin of life

Living processes may be defined as the self-sustained chemical reactions based on the special chemical machinery of nucleic acid-directed protein synthesis. Its genesis may be traced to the molecular interaction between nucleotides and amino acids leading to a primitive adaptor-mediated ordered synthesis of polypeptides. A primitive decoding system is described and its characteristics are shown to imitate, in a primitive manner, the present-day elaborate machinery of protein synthesis. This molecular interaction theory may be rightly considered as the missing link between the Protochemical and biological Evolution. The origin of chiral specificity observed in living organisms is also traced to this specific molecular interaction in the protobiological milieu.     

Racemization and the origin of optically active organic compounds in living organisms

The organic compounds synthesized in prebiotic experiments are racemic mixtures. A number of proposals have been offered to explain how asymmetric organic compounds formed on the Earth before life arose, with the influence of chiral weak nuclear interactions being the most frequent proposal. This and other proposed asymmetric syntheses give only slight enantiomeric excess and any slight excess will be degraded by racemization. This applies particularly to amino acids where half-lives of 10(5)-10(6) years are to be expected at temperatures characteristic of the Earth's surface. Since the generation of chiral molecules could not have been a significant process under geological conditions, the origins of this asymmetry must have occurred at the time of the origin of life or shortly thereafter. It is possible that the compounds in the first living organisms were prochiral rather than chiral; this is unlikely for amino acids, but it is possible for the monomers of RNA-like molecules.     

Photoinhibition of 2-amino-2-carboxybicyclo[2,2,1]heptane transport by O-diazoacetyl-L-serine. An initial step in identifying the L-system amino acid transporter

Neutral amino acid uptake into mammalian cells occurs predominantly through the L, A, and ASC carrier-mediated transport systems. The proteins responsible for transport by these systems have not been isolated, and the three pathways presently are defined by their amino acid specificity and physiologic parameters. We have found that the amino acid derivative, O-diazoacetyl-L-serine (azaserine), is a potentially useful probe for identification of the L-(leucine-favoring) system transporter in human T-lymphocytes. Uptake of azaserine competitively inhibits the uptake of the prototype L-system amino acid, 2-amino-2-carboxybicycloheptane (BCH). Azaserine undergoes photolytic cleavage with 365 nm incident light to yield a highly reactive carbene intermediate and free N2. Following photolysis of [14C]azaserine in a suspension of lymphocytes, the 14C label is detectable within a crude cytoplasmic membrane preparation, and this process is inhibited by a 50-fold excess of unlabeled azaserine or 2-amino-2-carboxybicycloheptane, suggesting that the 14C-product is associated with the membranes at or near the L-system transport site. Furthermore, photolysis of azaserine in the presence of lymphocytes results in specific irreversible inhibition of L-system transport. Thus, photolysis of azaserine provides an initial step toward the identification of the L-system transporter.     

Trans-stimulation of L-system amino acid transport in normal and chronic leukemic human lymphocytes: phorbol ester restores function in CLL

Chronic lymphocytic leukemia (CLL) B-lymphocytes have a unique and specific diminution of L-system (leucine favoring) amino acid uptake; the maximal velocity is approximately 10% of normal B-lymphocytes. Treatment of CLL B-cells with the maturational agent, tetradecanoyl phorbol acetate, results in restoration of L-system amino acid uptake to normal velocity. To further characterize the effect of phorbol ester on the L-system of CLL B-cells, we have examined the ability of normal and CLL lymphocytes to exchange intracellular for extracellular amino acids by the L-system (trans-stimulation). A 60% increase in L-system uptake was noted in normal B- and T-lymphocytes in the presence of a high intracellular concentration of 2-amino-2-carboxy-bicycloheptane (BCH), a largely L-system-specific substrate. L-system transport was not trans-stimulated in CLL B-lymphocytes. Phorbol ester treatment restored L-system uptake in CLL to a normal Vmax of 900 mumol/liter cell water per minute in the absence of BCH loading. The Vmax could be increased further to 2,400 if phorbol ester-treated CLL cells were loaded with BCH. Hence, phorbol esters result not only in a normalization of L-system uptake in CLL B-cells but the transport system demonstrates exchange rates comparable to normal lymphocytes.     

Proline autocatalysis in the origin of biological enantioenriched chirality

Biological enantioenriched chirality is a phenomenon that in living organisms, amino acids and carbohydrates typically have the same absolute configuration. Perhaps one of the earliest attempts to delineate the origins of this phenomenon was a theory known as asymmetric autocatalysis, a reaction in which the structures of the chiral catalyst and the product are the same, and in which the chiral product acts as a chiral catalyst for its own production. In theory, this would mean that small asymmetries in the product will propagate rapidly. However, autocatalysis also relies on the cross‐inhibition of chiral states, something that would not likely be possible on primordial Earth. But recently, theories on asymmetric autocatalysis have begun to resurface as more recent findings indicate that other mechanisms exist to stabilize the homochiral states. In this study, I propose an autocatalytic cycle, and using density functional theory, prove that (1) it is plausible on primordial Earth, and (2) it propagates arbitrary asymmetries in proline. Thus, facilitating asymmetry in proline and allowing access to a wide variety of asymmetric proline‐catalyzed reactions, including those involved in the synthesis of amino acids and carbohydrates from achiral precursors.     

Informational parameters and randomness of mitochondrial DNA

Summary The informational content of genomes of nuclear and mitochondrial origin is examined. By using the parameters of Shannon's information theory the language of mitochondrial DNA is shown to be more similar to the language of bacterial DNA than to that of nuclear DNA in more evolutionarily advanced animals. Moreover, using the parameters of Kolmogorov's theory on randomness, genes of different organisms (Neurospora crassa andSaccharomyces cerevisiae) coding for the same protein (subunit 9 of ATPase) are shown to have, if both of mitochondrial origin, a similar degree of randomness, whereas genes coding for the same protein, both belonging to the same organisms, exhibit a quite different degree of randomness when one is of mitochondrial origin and the other of nuclear origin. These results are in favor of the symbiotic origin of mitochondria.     

Stereochemical aspects of the antigenic determinants of bacterial polysaccharides: the Rhodococcus equi capsular polysaccharides

The antigenic specificity of bacterial capsular polysaccharides has been extensively investigated. The origin of this specificity arises from the diversity of the oligosaccharide epitopes of the polysaccharide. Nuclear magnetic resonance spectroscopy provides a very powerful tool for probing the structure of the oligosaccharide epitopes. Using this technique in conjunction with chemical methods, the structures of the serotype-specific capsular polysaccharide antigens of Rhodococcus equi have been investigated. These studies have led to the identification of several structural features which can be related to serologic type specificity. This review will focus on some stereochemical aspects of the antigen determinants. Nuclear magnetic resonance based methods for determination of bacterial polysaccharide primary structure and for stereochemical analysis of chiral acidic substituents are presented.     

Expansion of genome coding regions by acquisition of new genes

As it is the case for non-coding regions, the coding regions of organisms can be expanded or shrunk during evolutionary processes. However, the dynamics of coding regions are expected to be more correlated with functional complexity and diversity than are the dynamics of non-coding regions. Hence, it is interesting to investigate the increase of diversity in coding regions – the origin and evolution of new genes – because this provides a new component to the genetic variation underlying the diversity of living organisms. Here, we examine what is known about the mechanisms responsible for the increase in gene number. Every mechanism affects genomes in a distinct way and to a different extent and it appears that certain organisms favor particular mechanisms. The detail of some interesting gene acquisitions reveals the extreme dynamism of genomes. Finally, we discuss what is known about the fate of new genes and conclude that many of the acquisitions are likely to have been driven by natural selection; they increase functional complexity, diversity, and/or adaptation of species. Despite this, the correlation between complexity of life and gene number is low and closely related species (with very similar life histories) can have very different number of genes. We call this phenomenon the G-value paradox.     

Nucleotide correlation based measure for identifying origin of replication in genomic sequences

Computational prediction of the origin of replication is a challenging problem and of immense interest to biologists. Several methods have been proposed for identifying the replicon site for various classes of organisms. However, these methods have limited applicability since the replication mechanism is different in different organisms. We propose a correlation measure and show that it is correctly able to predict the origin of replication in most of the bacterial genomes. When applied to Methanocaldococcus jannaschii, Plasmodium falciparum apicoplast and Nicotiana tabacum plastid, this correlation based method is able to correctly predict the origin of replication whereas the generally used GC skew measure fails. Thus, this correlation based measure is a novel and promising tool for predicting the origin of replication in a wide class of organisms. This could have important implications in not only gaining a deeper understanding of the replication machinery in higher organisms, but also for drug discovery.     

Gulliver's further travels: the necessity and difficulty of a hierarchical theory of selection.

For principled and substantially philosophical reasons, based largely on his reform of natural history by inverting the Paleyan notion of overarching and purposeful beneficence in the construction of organisms, Darwin built his theory of selection at the single causal level of individual bodies engaged in unconscious (and metaphorical) struggle for their own reproductive success. But the central logic of the theory allows selection to work effectively on entities at several levels of a genealogical hierarchy, provided that they embody a set of requisite features for defining evolutionary individuality. Genes, cell lineages, demes, species, and clades-as well as Darwin''s favoured organisms-embody these requisite features in enough cases to form important levels of selection in the history of life. R. A. Fisher explicitly recognized the unassailable logic of species selection, but denied that thsi real process could be important in evolution because, compared with the production of new organisms within a species, the origin of new species is so rare, and the number of species within most clades so low. I review this and other classical arguments against higher-level selection, and conclude (in the first part of this paper) that they are invalid in practice for interdemic selection, and false in principle for species selection. Punctuated equilibrium defines the individuality of species and refutes Fisher''s classical argument based on cycle time. In the second part of the paper, I argue that we have failed to appreciate the range and power of selection at levels above and below the organismic because we falsely extrapolate the defining properties of organisms to these other levels (which are characterized by quite different distinctive features), and then regard the other levels as impotent because their effective individuals differ so much from organisms. We would better appreciate the power and generality of hierarchical models of selection if we grasped two key principles: first, that levels can interact in all modes (positively, negatively, and orthogonally), and not only in the negative style (with a higher level suppressing an opposing force of selection from the lower level) that, for heuristic and operational reasons, has received almost exclusive attention in the existing literature; and second, that each hierarchical level differs from all others in substantial and interesting ways, both in the style and frequency of patterns in change and causal modes.     

Diversity, endemism and evolution in the Coral Triangle

In a recent paper by D. R. Bellwood and C. P. Meyer ('Searching for heat in a marine biodiversity hotspot', Journal of Biogeography , 2009, 36 , 569–576), the authors had two evident objectives: (1) to disprove the theory that the geographical origins of reef organisms could be determined by locating concentrations of endemic species, and (2) to emphasize that the high diversity of the Coral Triangle was due to an accumulation of species from outside that area. With regard to the first point, no such theory had previously been proposed to my knowledge. Second, the accumulation theory was promoted without consideration of the facts supporting the centre of origin hypothesis, except to dismiss it by saying that it had its origin in pre-continental drift ideas. This short response outlines the properties and evidence for the operation of centres of origin in this region.     

The scenario on the origin of translation in the RNA world: in principle of replication parsimony

Background  

It is now believed that in the origin of life, proteins should have been "invented" in an RNA world. However, due to the complexity of a possible RNA-based proto-translation system, this evolving process seems quite complicated and the associated scenario remains very blurry. Considering that RNA can bind amino acids with specificity, it has been reasonably supposed that initial peptides might have been synthesized on "RNA templates" containing multiple amino acid binding sites. This "Direct RNA Template (DRT)" mechanism is attractive because it should be the simplest mechanism for RNA to synthesize peptides, thus very likely to have been adopted initially in the RNA world. Then, how this mechanism could develop into a proto-translation system mechanism is an interesting problem.     

Lethal mutants and truncated selection together solve a paradox of the origin of life

Background

Many attempts have been made to describe the origin of life, one of which is Eigen''s cycle of autocatalytic reactions [Eigen M (1971) Naturwissenschaften 58, 465–523], in which primordial life molecules are replicated with limited accuracy through autocatalytic reactions. For successful evolution, the information carrier (either RNA or DNA or their precursor) must be transmitted to the next generation with a minimal number of misprints. In Eigen''s theory, the maximum chain length that could be maintained is restricted to nucleotides, while for the most primitive genome the length is around . This is the famous error catastrophe paradox. How to solve this puzzle is an interesting and important problem in the theory of the origin of life.

Methodology/Principal Findings

We use methods of statistical physics to solve this paradox by carefully analyzing the implications of neutral and lethal mutants, and truncated selection (i.e., when fitness is zero after a certain Hamming distance from the master sequence) for the critical chain length. While neutral mutants play an important role in evolution, they do not provide a solution to the paradox. We have found that lethal mutants and truncated selection together can solve the error catastrophe paradox. There is a principal difference between prebiotic molecule self-replication and proto-cell self-replication stages in the origin of life.

Conclusions/Significance

We have applied methods of statistical physics to make an important breakthrough in the molecular theory of the origin of life. Our results will inspire further studies on the molecular theory of the origin of life and biological evolution.     

Terrestrial and extraterrestrial sources of molecular homochirality

The unique chirality of biomolecules is reviewed, and the prebiotic requirement for the absolute chiral homogeneity of such molecules prior to their capability of self-replication is emphasized. Biotic and abiotic theories embracing both chance and determinate mechanisms which have been proposed for the origin of terrestrial chiral molecules are briefly summarized and evaluated, as are abiotic mechanisms for the subsequent amplification of the small enantiomeric excesses (e.e.s) in the chiral molecules which might be formed by such processes. While amplification mechanisms are readily validated experimentally and are potentially viable on the primitive Earth, it is concluded that all terrestrial mechanisms proposed for the origin of chirality have one or more limitations which make them either intrinsically invalid or highly improbable in the chaotic and turbulent environment of the prebiotic Earth. To circumvent these difficulties we have proposed an extraterrestrial scenario for the production of terrestrial chirality in which circularly polarized synchrotron radiation from the neutron star remnant of a supernova interacts with the organic mantles on interstellar grains, producing chiral molecules by the partial asymmetric photolysis of racemic constituent in the mantles, after which the interstellar grains with their enantiomerically enriched mantles are transported to Earth either by direct accretion or through cometary impact. At this point one of the known terrestrial e.e. enrichment mechanisms could promote the small extraterrestrially produced e.e.s. into the state of chiral homogeneity required for self-replicating biomolecules.     

Significance of chiral purity of biomolecules for self-reproduction of organisms]

Living systems mainly syntesise and utilise chiral pure polimers which have only one form of enantiomers (l, l,..., l-proteins, d, d, d,..., d-sugars). The biologycal meaning of chiral purity of molecules in organisms is discussed. It is shown that chiral purity of biomolecules is necessary to ensure ordering of organisms during selfreproduction. Even when formation of chiral pure form does not have any advantages over formation of a set of other stereoisomers, only chiral pure molecules may act as regulators of further syntheses. Molecules with distorded chiral purity are not able to maintain the initial order during selfreproduction.     

Stereoselective differentiation in the Salt-induced Peptide Formation reaction and its relevance for the origin of life

All living organisms on earth are almost totally made up of biomolecules of only one chiral form. For example, proteins are built almost exclusively of L-amino acids, and sugars are composed of D-saccharides, a fact that is usually referred to as biohomochirality. Its origin is the center of numerous investigations and theories but is not really elucidated yet. The results of experimental investigations of peptide formation in a prebiotically relevant scenario, as described in this paper, give indications on a possible pathway for the synthesis of homochiral L-peptides in the course of the Salt-induced Peptide Formation (SIPF) reaction.     

Bacterial symbioses. Predation and mutually beneficial associations.

The endosymbiotic theory, which has proved to explain the origin of mitochondria and chloroplasts, also posits the origin of nucleus and other cellular organelles that could have derived from ancient relationships among bacteria. It seems that predation might have been a prerequisite to the establishment of symbiosis as a source of evolutionary novelty. This review describes current different examples of bacteria able not only to attack and degrade other bacteria, but also to establish stable symbiotic relationships with different eukaryotic organisms.     

Creating a Novel Origin of Replication through Modulating DNA-Protein Interfaces

Background

While the molecular mechanisms of DNA-protein specificity at the origin of replication have been determined in many model organisms, these interactions remain unknown in the majority of higher eukaryotes and numerous vertebrate viruses. Similar to many viral origins of replication, adeno-associated virus (AAV) utilizes a cis-acting origin of replication and a virus specific Replication protein (Rep) to faithfully carry out self-priming replication. The mechanisms of AAV DNA replication are generally well understood. However, the molecular basis of specificity between the Rep protein and the viral origin of replication between different AAV serotypes remains uncharacterized.

Methodology/Principal Findings

By generating a panel of chimeric and mutant origins between two AAV serotypes, we have mapped two independent DNA-Protein interfaces involved in replicative specificity. In vivo replication assays and structural modeling demonstrated that three residues in the AAV2 Rep active site are necessary to cleave its cognate origin. An analogous origin (AAV5) possesses a unique interaction between an extended Rep binding element and a 49 aa region of Rep containing two DNA binding interfaces.

Conclusions/Significance

The elucidation of these structure-function relationships at the AAV origin led to the creation of a unique recombinant origin and compatible Rep protein with properties independent of either parent serotype. This novel origin may impact the safety and efficacy of AAV as a gene delivery tool. This work may also explain the unique ability of certain AAV serotypes to achieve site-directed integration into the human chromosome. Finally, this result impacts the study of conserved DNA viruses which employ rolling circle mechanisms of replication.     

On the Origin of Metabolic Pathways

The heterotrophic theory of the origin of life is the only proposal available with experimental support. This comes from the ease of prebiotic synthesis under strongly reducing conditions. The prebiotic synthesis of organic compounds by reduction of CO₂ to monomers used by the first organisms would also be considered an heterotrophic origin. Autotrophy means that the first organisms biosynthesized their cell constituents as well as assembling them. Prebiotic synthetic pathways are all different from the biosynthetic pathways of the last common ancestor (LCA). The steps leading to the origin of the metabolic pathways are closer to prebiotic chemistry than to those in the LCA. There may have been different biosynthetic routes between the prebiotic and the LCAs that played an early role in metabolism but have disappeared from extant organisms. The semienzymatic theory of the origin of metabolism proposed here is similar to the Horowitz hypothesis but includes the use of compounds leaking from preexisting pathways as well as prebiotic compounds from the environment.