A Computer-Glimpse of the Origin of Life

Evolution is assumed to begin in a very particular compartmentalized location with periodic conditions. A highly diversified world is the driving force for the continuous increase in complexity by colonizing increasingly less favourable regions. Modeling the “origin-of-life” a Darwinian cyclic process is simulated (multiplication with sporadic errors followed by a construction and selection). Starting from a RNA-world (R-strands of R₁ and R₂ monomers building Hairpin-Assembler devices) and introducing another kind of monomers (A₁ and A₂ which interlink to the Hairpin-Assembler devices such that they become bound and form an A-oligomer) it is shown that a simple translation apparatus evolves producing enzymes (specific sequences of A₁ and A₂ monomers given by the sequences of R₁ and R₂ monomers on the assembler-strands). Later on D-strands are introduced, which are not capable of participating in the synthesis of A-oligomers. These D-strands become carriers of the genetic information and induce the formation of increasingly complex entities of functionally interplaying components.     

RNA Folding Argues Against a Hot-Start Origin of Life

Opinion is strongly divided on whether life arose on earth under hot or cold conditions, the hot-start and cold-start scenarios, respectively. The origin of life close to deep thermal vents appears as the majority opinion among biologists, but there is considerable biochemical evidence that high temperatures are incompatible with an RNA world. To be functional, RNA has to fold into a three-dimensional structure. We report both theoretical and experimental results on RNA folding and show that (as expected) hot conditions strongly reduce RNA folding. The theoretical results come from energy-minimization calculations of the average extent of folding of RNA, mainly from 0–90°C, for both random sequences and tRNA sequences. The experimental results are from circular-dichroism measurements of tRNA over a similar range of temperatures. The quantitative agreement between calculations and experiment is remarkable, even to the shape of the curves indicating the cooperative nature of RNA folding and unfolding. These results provide additional evidence for a lower temperature stage being necessary in the origin of life. Received: 1 March 2000 / Accepted: 14 June 2000     

Montmorillonite,Oligonucleotides, RNA and Origin of Life

Na-montmorillonite prepared from Volclay by the titration method facilitates the self-condensation of ImpA, the 5'-phosphorimidazolide derivative of adenosine. As was shown by AE-HPLC analysis and selective enzymatic hydrolysis of products, oligo(A)s formed in this reaction are 10 monomer units long and contain 67% 3',5'-phosphodiester bonds (Ferris and Ertem, 1992a). Under the same reaction conditions, 5'-phosphorimidazolide derivatives of cytidine, uridine and guanosine also undergo self-condensation producing oligomers containing up to 12-14 monomer units for oligo(C)s to 6 monomer units for oligo(G)s. In oligo(C)s and oligo(U)s, 75-80% of the monomers are linked by 2',5'-phosphodiester bonds. Hexamer and higher oligomers isolated from synthetic oligo(C)s formed by montmorillonite catalysis, which contain both 3',5'- and 2',5'-linkages, serve as catalysts for the non-enzymatic template directed synthesis of oligo(G)s from activated monomer 2-MeImpG, guanosine 5'-phospho-2-methylimidazolide (Ertem and Ferris, 1996). Pentamer and higher oligomers containing exclusively 2',5'-linkages, which were isolated from the synthetic oligo(C)s, also serve as templates and produce oligo(G)s with both 2',5'- and 3',5'-phosphodiester bonds. Kinetic studies on montmorillonite catalyzed elongation rates of oligomers using the computer program SIMFIT demonstrated that the rate constants for the formation of oligo(A)s increased in the order of 2-mer < 3-mer < 4-mer ... < 7-mer (Kawamura and Ferris, 1994). A decameric primer, dA(pdA)8pA bound to montmorillonite was elongated to contain up to 50 monomer units by daily addition of activated monomer ImpA to the reaction mixture (Ferris, Hill and Orgel, 1996). Analysis of dimer fractions formed in the montmorillonite catalyzed reaction of binary and quaternary mixtures of ImpA, ImpC, 2-MeImpG and ImpU suggested that only a limited number of oligomers could have formed on the primitive Earth rather than equal amounts of all possible isomers (Ertem and Ferris, 2000). Formation of phosphodiester bonds between mononucleotides by montmorillonite catalysis is a fascinating discovery, and a significant step forward in efforts to find out how the first RNA-like oligomers might have formed in the course of chemical evolution. However, as has been pointed out in several publications, these systems should be regarded as models rather than a literal representation of prebiotic chemistry (Orgel, 1998; Joyce and Orgel, 1999; Schwartz, 1999).     

Formation of Peptide Bonds from Metastable versus Crystalline Phase: Implications for the Origin of Life

Formation of peptide bonds was attempted bythermal activation of dry amino acids from aqueous solutionthat simulated prebiotic evaporative environments. Theevaporation trend of amino acids solutions shows abifurcation and can lead to either a crystalline phase(near equilibrium) or a metastable non-crystalline phase(far from equilibrium). Only amino acids in this metastablephase are able to form peptide bonds by thermal activationat temperatures that are generated by solar radiationtoday. We suggest that this metastable phase is the idealinitial material to trigger amino acid assemblage withprotein-like structure because provide the driving force(supersaturation) for an intense interaction betweenmonomers of different amino acids and allows activation ofthese monomers in plausible prebiotic conditions.     

Ice And The Origin Of Life

Sea ice occurs abundantly at the polar caps of the Earth and, probably, of many other planets. Its static and dynamic properties that may be important for prebiotic and early biotic reactions are described. It concentrates substrates and has many features that are important for catalytical actions. We propose that it provided optimal conditions for the early replication of nucleic acids and the RNA world. We repeated a famous prebiotic experiment, the poly-uridylic acid-instructed synthesis of polyadenylic acid from adenylic acid imidazolides in artificial sea ice, simulating the dynamic variability of real sea ice by cyclic temperature variation. Poly(A) was obtained in high yield and reached nucleotide chain lengths up to 400 containing predominantly 3′→ 5′ linkages.     

A Research Proposal on the Origin Of Life. Closing Lecture given at the ISSOL Congress in Oaxaca,Mexico, on July 4, 2002

This paper describes some experiments the author would haveliked to carry out if he had started earlier in the origin-of-life field.The proposal is preceded by a hypothetical outline of the mainevents in the origin of life. According to this outline, the emergence oflife amounts to the transition between two kinds of chemistry: 1) cosmic chemistry, which is beginning to be understood and mostlikely provided the building blocks with which life was first constructed; and 2)biochemistry, the well-known set of enzyme-catalyzedmetabolic reactions that support all living organisms today and must havesupported the universal common ancestor, or LUCA, from which all known formsof life are derived. The pathway leading from one to the other of thosetwo chemistries may be divided into three stages, defined as the pre-RNA, RNA, and protein-DNA stages. A briefsummary of the events that may have occurred in these three stages and ofthe possible underlying mechanisms is given. It is emphasized that theseevents were chemical in nature and, especially, that theymust have prefigured present-day biochemical processes. Protometabolismand metabolism, it is argued, must have been congruent. With congruence as the underlying working hypothesis, threeproblems open to experimental investigation are considered: 1) the involvementof peptides and other multimers as catalysts of early biogenic chemistry;2) the participation of thioesters in primitive energy transactions;and 3) the influence of amino acids on the molecular selection of RNAmolecules.     

Thermal Energy and the Origin of Life

Life has evolved on Earth with electromagnetic radiation (light), fermentable organic molecules, and oxidizable chemicals as sources of energy. Biological use of thermal energy has not been observed although heat, and the thermal gradients required to convert it into free energy, are ubiquitous and were even more abundant at the time of the origin of life on Earth. Nevertheless, Earth-organisms sense thermal energy, and in suitable environments may have gained the capability to use it as energy source. It has been proposed that the first organisms obtained their energy by a first protein named pF₁ that worked on a thermal variation of the binding change mechanism of today's ATP sythase enzyme. Organisms using thermosynthesis may still live where light or chemical energy sources are not available. Possible suitable examples are subsurface environments on Earth and in the outer Solar System, in particular the subsurface oceans of the icy satellites of Jupiter and Saturn.     

A System of Two Polymerases – A Model for the Origin of Life

What was the first living molecule – RNA or protein?This question embodies the major disagreement instudies on the origin of life. The fact that incontemporary cells RNA polymerase is a protein andpeptidyl transferase consists of RNA suggests theexistence of a mutual catalytic dependence betweenthese two kinds of biopolymers. I suggest that thisdependence is a `frozen accident', a remnant from thefirst living system. This system is proposed to be acombination of an RNA molecule capable of catalyzingamino acid polymerization and the resulting proteinfunctioning as an RNA-dependent RNA polymerase. Thespecificity of the protein synthesis is thought to beachieved by the composition of the surrounding mediumand the specificity of the RNA synthesis – by Watson– Crick base pairing. Despite its apparent simplicity,the system possesses a great potential to evolve intoa primitive ribosome and further to life, as it isseen today. This model provides a possible explanationfor the origin of the interaction between nucleicacids and protein. Based on the suggested system, Ipropose a new definition of life as a system ofnucleic acid and protein polymerases with a constantsupply of monomers, energy and protection.     

The origin of life: RNA and protein co-evolution on the ancient Earth

How life emerged from simple non-life chemicals on the ancient Earth is one of the greatest mysteries in biology. The gene expression system of extant life is based on the interdependence between multiple molecular species (DNA, RNA, and proteins). While DNA is mainly used as genetic material and proteins as functional molecules in modern biology, RNA serves as both genetic material and enzymes (ribozymes). Thus, the evolution of life may have begun with the birth of a ribozyme that replicated itself (the RNA world hypothesis), and proteins and DNA joined later. However, the complete self-replication of ribozymes from monomeric substrates has not yet been demonstrated experimentally, due to their limited activity and stability. In contrast, peptides are more chemically stable and are considered to have existed on the ancient Earth, leading to the hypothesis of RNA–peptide co-evolution from the very beginning. Our group and collaborators recently demonstrated that (1) peptides with both hydrophobic and cationic moieties (e.g., KKVVVVVV) form β-amyloid aggregates that adsorb RNA and enhance RNA synthesis by an artificial RNA polymerase ribozyme and (2) a simple peptide with only seven amino acid types (especially rich in valine and lysine) can fold into the ancient β-barrel conserved in various enzymes, including the core of cellular RNA polymerases. These findings, together with recent reports from other groups, suggest that simple prebiotic peptides could have supported the ancient RNA-based replication system, gradually folded into RNA-binding proteins, and eventually evolved into complex proteins like RNA polymerase.     

Error-reducing Structure of the Genetic Code Indicates Code Origin in Non-thermophile Organisms

During the RNA World, organisms experienced high rates of genetic errors, which implies that there was strong evolutionary pressure to reduce the errors’ phenotypical impact by suitably structuring the still-evolving genetic code. Therefore, the relative rates of the various types of genetic errors should have left characteristic imprints in the structure of the genetic code. Here, we show that, therefore, it is possible to some extent to reconstruct those error rates, as well as the nucleotide frequencies, for the time when the code was fixed. We find evidence indicating that the frequencies of G and C in the genome were not elevated. Since, for thermodynamic reasons, RNA in thermophiles tends to possess elevated G+C content, this result indicates that the fixation of the genetic code occurred in organisms which were either not thermophiles or that the code’s fixation occurred after the rise of DNA. Supplementary Materials Original data and programs are available at the author’s web site: .     

Serpentinite and the dawn of life

Submarine hydrothermal vents above serpentinite produce chemical potential gradients of aqueous and ionic hydrogen, thus providing a very attractive venue for the origin of life. This environment was most favourable before Earth's massive CO(2) atmosphere was subducted into the mantle, which occurred tens to approximately 100 Myr after the moon-forming impact; thermophile to clement conditions persisted for several million years while atmospheric pCO(2) dropped from approximately 25 bar to below 1 bar. The ocean was weakly acid (pH ～ 6), and a large pH gradient existed for nascent life with pH 9-11 fluids venting from serpentinite on the seafloor. Total CO(2) in water was significant so the vent environment was not carbon limited. Biologically important phosphate and Fe(II) were somewhat soluble during this period, which occurred well before the earliest record of preserved surface rocks approximately 3.8 billion years ago (Ga) when photosynthetic life teemed on the Earth and the oceanic pH was the modern value of approximately 8. Serpentinite existed by 3.9 Ga, but older rocks that might retain evidence of its presence have not been found. Earth's sequesters extensive evidence of Archaean and younger subducted biological material, but has yet to be exploited for the Hadean record.     

Origin of symbol-using systems: speech,but not sign,without the semantic urge

Natural language—spoken and signed—is a multichannel phenomenon, involving facial and body expression, and voice and visual intonation that is often used in the service of a social urge to communicate meaning. Given that iconicity seems easier and less abstract than making arbitrary connections between sound and meaning, iconicity and gesture have often been invoked in the origin of language alongside the urge to convey meaning. To get a fresh perspective, we critically distinguish the origin of a system capable of evolution from the subsequent evolution that system becomes capable of. Human language arose on a substrate of a system already capable of Darwinian evolution; the genetically supported uniquely human ability to learn a language reflects a key contact point between Darwinian evolution and language. Though implemented in brains generated by DNA symbols coding for protein meaning, the second higher-level symbol-using system of language now operates in a world mostly decoupled from Darwinian evolutionary constraints. Examination of Darwinian evolution of vocal learning in other animals suggests that the initial fixation of a key prerequisite to language into the human genome may actually have required initially side-stepping not only iconicity, but the urge to mean itself. If sign languages came later, they would not have faced this constraint.     

Enantiomeric Crystallization from DL-Aspartic and DL-Glutamic Acids: Implications for Biomolecular Chirality in the Origin of Life

Amino acids in living systems consist almost exclusively of the L-enantiomer. How and when this homochiral characteristic of life came to be has been a matter of intense investigation for many years. Among the hypotheses proposed to explain theappearance of chiral homogeneity, the spontaneous resolution of conglomerates seems one of the most plausible. Racemic solids may crystallize from solution either as racemic compounds(both enantiomeric molecules in the same crystal), or lesscommonly as conglomerates (each enantiomer molecule separate indifferent enantiomeric crystals). Only conglomerates can developa spontaneous resolution (one of the enantiomeric molecule crystallizes preferentially, the other one remains in solution).Most of natural amino acids are racemic compounds at moderatetemperatures. How can we expect a hypothetical spontaneous resolution of these amino acids if they are not conglomerates?In this paper we show how DL-aspartic and DL-glutamic amino acids(racemic compounds), crystallize at ambient conditions as trueconglomerates. The experimental conditions here described,that allows this `anomalous' behaviour, could be also found innatural sedimentary environments. We suggest that these experimental procedures and its natural equivalents, have apotential interest for the investigation of the spontaneous resolution of racemic compounds comprising molecules associatedwith the origin of life.     

RNA Ligation and the Origin of tRNA

A straightforward origin of transfer RNA,(tRNA), is difficult to envision because of the apparentlycomplex idiosyncratic interaction between the D-loop and T-loop. Recently, multiple examples of the T-loop structuralmotif have been identified in ribosomal RNA. These examplesshow that the long-range interactions between the T-loop andD-loops seen in tRNA are not an essential part of the motifbut rather are facilitated by it. Thus, the core T-loopstructure could already have existed in a small RNA prior tothe emergence of the tRNA. The tRNA might then have arisenby expansion of an RNA that carried the motif. With thisidea in mind, Di Giulio's earlier hypothesis that tRNAevolved by a simple duplication or ligation of a minihelixRNA was re-examined. It is shown that an essentially moderntRNA structure can in fact be generated by the ligation oftwo 38-nucleotide RNA minihelices of appropriate sequence.Although rare, such sequences occur with sufficientfrequency, (1 in 3 × 10⁷), that they could be found in astandard in vitro RNA selection experiment. Theresults demonstrate that a series of RNA duplications, aspreviously proposed, can in principal account for the originof tRNA. More generally, the results point out that RNAligation can be a powerful driving force for increasedcomplexity in the RNA World.     

The Origin of Life: A Problem of History,Chemistry, and Evolution

The origin of life is a field full of controversies, not only because of our vague understanding concerning the relevant issues, but also, perhaps more often, owing to our dim conceptual framework throughout the whole field. To improve this situation, an in‐depth conceptual dissection is presented here. It is elucidated that, at its core, the origin of life has three aspects. The facts involved in the process are taken as the historical aspect, which is destined to be uncertain and often irrelevant to debate regarding details. The rules involved include two distinct aspects: chemical mechanisms operated in the whole process, while evolutionary mechanisms joined in only after the emergence of the first Darwinian entities – and then accounted for the subsequent buildup of complexity (this cannot be explained solely by natural selection). Basically, we can ask about the possibility of any assumed event in the origin of life: ‘Is it evolutionarily plausible, chemically feasible, and historically likely?’ Clues from any of the three aspects may be quite valuable in directing our explorations on the other two. This conceptual dissection provides a clearer context for the field, which may even be more useful than any sort of specific research.     

Origin of amino acid homochirality: relationship with the RNA world and origin of tRNA aminoacylation

The origin of homochirality of l-amino acids has long been a mystery. Aminoacylation of tRNA might have provided chiral selectivity, since it is the first process encountered by amino acids and RNA. An RNA minihelix (progenitor of the modern tRNA) was aminoacylated by an aminoacyl phosphate oligonucleotide that exhibited a clear preference for l- as opposed to d-amino acids. A mirror-image RNA system with l-ribose exhibited the opposite selectivity, i.e., it exhibited an apparent preference for the d-amino acid. The selectivity for l-amino acids is based on the stereochemistry of RNA. The side chain of d-amino acids is located much closer to the terminal adenosine of the minihelix, causing them collide and interfere during the amino acid-transfer step. These results suggest that the putative RNA world that preceded the protein theatre determined the homochirality of l-amino acids through tRNA aminoacylation.     

An Open Question on the Origin of Life: The First Forms of Metabolism

The general framework of the origin of life on Earth is outlined, emphasizing that the so‐called prebiotic ‘RNA world’ is as yet on shaky scientific ground, and that one should any way ask the question of the structure of the first protocellular compartments capable of the initial forms of metabolism. This question is the basis of the research project on the minimal cells, containing the minimal and sufficient complexity capable of leading to life. Such research is briefly summarized, highlighting experiments with liposome‐based semisynthetic cells which are capable of ribosomal protein synthesis with a very minimal number of enzymes. The most recent finding in this area of research is the unexpected observation that the formation and closure of liposomes in situ acts as an attractor for the solute molecules in solution, bringing about a very high local concentration in some of the liposomes. It is argued that this spontaneous overcrowding, which permits reactions which are not possible in the original dilute solution, might be the origin of cellular metabolism for the origin of life on Earth.     

Peptide Amyloids in the Origin of Life

How life can emerge from non-living matter is one of the fundamental mysteries of the universe. A bottom-up approach to this problem focuses on the potential chemical precursors of life, in particular the nature of the first replicative molecules. Such thinking has led to the currently most popular idea: that an RNA-like molecule played a central role as the first replicative and catalytic molecule. Here, we review an alternative hypothesis that has recently gained experimental support, focusing on the role of amyloidogenic peptides rather than nucleic acids, in what has been by some termed “the amyloid-world” hypothesis. Amyloids are well-ordered peptide aggregates that have a fibrillar morphology due to their underlying structure of a one-dimensional crystal-like array of peptides in a β-strand conformation. While they are notorious for their implication in several neurodegenerative diseases including Alzheimer's disease, amyloids also have many biological functions. In this review, we will elaborate on the following properties of amyloids in relation to their fitness as a prebiotic entity: they can be formed by very short peptides with simple amino acids sequences; as aggregates they are more chemically stable than their isolated component peptides; they can possess diverse catalytic activities; they can form spontaneously during the prebiotic condensation of amino acids; they can act as templates in their own chemical replication; they have a structurally repetitive nature that enables them to interact with other structurally repetitive biopolymers like RNA/DNA and polysaccharides, as well as with structurally repetitive surfaces like amphiphilic membranes and minerals.