A Model for the Origin of Life through Rearrangements among Prebiotic Phosphodiester Polymers

This model proposes that the origin of life on Earth occurred as a result of a process of alteration of the chemical composition of prebiotic macromolecules. The stability of organic compounds assembled into polymers generally exceeded the stability of the same compounds as free monomers. This difference in stability stimulated accumulation of prebiotic macromolecules. The prebiotic circulation of matter included constant formation and decomposition of polymers. Spontaneous chemical reactions between macromolecules with phosphodiester backbones resulted in a non-Darwinian selection for chemical stability, while formation of strong structures provided an advantage in the struggle for stability. Intermolecular structures between nucleotide-containing polymers were further stabilized by occasional acquisition of complementary nucleotides. Less stable macromolecules provided the source of nucleotides. This process resulted first in the enrichment of nucleotide content in prebiotic polymers, and subsequently in the accumulation of complementary oligonucleotides. Finally, the role of complementary copy molecules changed from the stabilization of the original templates to the de novo production of template-like molecules. I associate this stage with the origin of life in the form of cell-free molecular colonies. Original life acquired ready-to-use substrates from constantly forming prebiotic polymers. Metabolism started to develop when life began to consume more substrates than the prebiotic cycling produced. The developing utilization of non-polymeric compounds stimulated the formation of the first membrane-enveloped cells that held small soluble molecules. Cells “digested” the nucleotide-containing prebiotic macromolecules to nucleotide monomers and switched the mode of replication to the polymerization of nucleotide triphosphates.     

Reexamination of the role of nonhydrolyzable guanosine 5'-triphosphate analogues in tubulin polymerization: reaction conditions are a critical factor for effective interactions at the exchangeable nucleotide site

Recently it was proposed [O'Brien, E. T., & Erickson, H. P. (1989) Biochemistry 28, 1413-1422] that tubulin polymerization supported by guanosine 5'-(beta,gamma-imidotriphosphate) [p(NH)ppG], guanosine 5'-(beta,gamma-methylenetriphosphate) [p(CH2)ppG], and ATP might be due to residual GTP in reaction mixtures and that these nucleotides would probably support only one cycle of assembly. Since we had observed polymerization with these three compounds, we decided to study these reactions in greater detail in two systems. The first contained purified tubulin and a high concentration of glycerol, the second tubulin and microtubule-associated proteins (MAPs). In both systems, reactions supported by nucleotides other than GTP were most vigorous at lower pH values. In the glycerol system, repeated cycles of polymerization were observed with ATP and p(CH2)ppG, but not with p(NH)ppG. With p(NH)ppG, a single cycle of polymerization was observed, and this was caused by contaminating GTP. In the MAPs system, repeated cycles of polymerization were observed with both nonhydrolyzable GTP analogues, even without contaminating GTP, but ATP was not active at all in this system. Binding to tubulin of p(NH)ppG, p(CH2)ppG, and, to a lesser extent, ATP was demonstrated indirectly, since high concentrations of the three nucleotides displaced radiolabeled GDP originally bound in the exchangeable site, with p(NH)ppG the most active of the three compounds in this displacement assay. The failure of GTP-free p(NH)ppG to support tubulin polymerization in our glycerol system even though it displaced GDP from the exchangeable site was further investigated by examining the effects of p(NH)ppG on polymerization and polymer-bound nucleotide with low concentrations of GTP. The two nucleotides appeared to act synergistically in supporting polymerization, so that a reaction occurred with a subthreshold GTP concentration if p(NH)ppG was also in the reaction mixture. Analysis of radiolabeled exchangeable-site nucleotide in polymers formed in reaction mixtures containing both GTP and p(NH)ppG demonstrated that p(NH)ppG which entered polymer did so primarily at the expense of GDP originally bound in the exchangeable site rather than at the expense of GTP. It appears that in the glycerol reaction condition, tubulin-p(NH)ppG cannot initiate tubulin polymerization but that it can participate in polymer elongation. ATP and p(CH2)ppG also entered the exchangeable site during polymerization without GTP in glycerol, as demonstrated by displacement of radiolabeled GDP from polymer when these alternate nucleotides were used.(ABSTRACT TRUNCATED AT 400 WORDS)     

Solid-phase methods for sequencing nucleic acids. VII. Chemical degradation of synthetic DNA-RNA hybrid fragments using CCS and DE 81 anion-exchange papers

Synthetic oligo(ribo-deoxyribo)nucleotides were analyzed and characterized by different solid-phase chemical degradation procedures, 5'- and 3'-end labelled mixed fragments were degraded by a slightly modified DNA cleavage procedure using 1 and 10% piperidine for the chain scission reaction and CCS anion-exchange paper. Besides the normal degradation products obtained by the usual modification and strand cleavage reactions of both deoxy- and ribonucleotide residues, additional bands were identified in the sequence patterns resulting from the hydrolysis of the RNA moiety induced by piperidine. Since both degradation reactions cleave the backbone of the mixed DNA-RNA fragments differently and produce nucleotide components with different charges, the degradation products do not interfere and can be resolved by gel electrophoresis on polyacrylamide. In addition, 3'-end labelled DNA-RNA oligomers were degraded by a RNA cleavage procedure using DE 81 anion-exchange paper as solid support. The combination of all three degradation methods allows to confirm the nucleotide sequence.     

Identification of acetaminophen polymerization products catalyzed by horseradish peroxidase

Horseradish peroxidase catalyzed the H2O2-dependent oxidation and polymerization of acetaminophen. Six acetaminophen polymers were isolated from horseradish peroxidase reaction mixtures by semipreparative high pressure liquid chromatography. Chemical structures were determined by a combination of electron impact and chemical ionization mass spectrometry and 500-MHz proton magnetic resonance spectroscopy. Two dimers, three trimers, and one tetramer were identified. The polymers formed primarily through a covalent bond between carbons ortho to the hydroxyl group, and to a lesser extent, between the carbon ortho to the hydroxyl group and the amino group of another acetaminophen molecule. Greater than 99% of the polymerization reaction products were quenched by the addition of 2.0 mM ascorbate. High acetaminophen concentration favored dimer formation, whereas low acetaminophen concentration favored formation of trimers and tetramers. Since approximately 1 mol of H2O2 was consumed per mol of covalent ligand formed between acetaminophen molecules, these products probably result from free radical termination reactions.     

15 Combinatorial chemistry in the prebiotic environment

The pathway leading to the origin of life presumably included a process by which polymers were synthesized abiotically from simpler compounds on the early Earth, then encapsulated to form protocells. Previous studies have reported that mineral surfaces can concentrate and organize activated mononucleotides, thereby promoting their polymerization into RNA-like molecules. However, a plausible prebiotic activation mechanism has not been established, and minerals cannot form cellular compartments. We are exploring ways in which nonactivated mononucleotides can undergo polymerization and encapsulation. We found that small yields of RNA-like molecules are synthesized by a condensation reaction when mixtures of amphiphilic lipids and mononucleotides are exposed to cycles of dehydration and rehydration. The lipids concentrate and organize the monomers within multilamellar liquid-crystalline matrices that self-assemble in the dry state. The chemical potential driving the polymerization reaction is supplied by the anhydrous conditions in which water becomes a leaving group, with heat providing activation energy. Significantly, the polymeric products are encapsulated in trillions of microscopic compartments upon rehydration. Each compartment is unique in its composition and contents, and can be considered to be an experiment in a natural version of combinatorial chemistry that would be ubiquitous in the prebiotic environment. A successful experiment would be a compartment that captured polymers capable of catalyzing their own replication. If this can be reproduced in the laboratory, it would represent a significant step toward understanding the origin of cellular life.     

Several regions of a tRNA precursor determine the Escherichia coli RNase P cleavage site.

The RNase P cleavage reaction was studied as a function of the number of base-pairs in the acceptor-stem and/or T-stem of a natural tRNA precursor, the tRNA(Tyr)Su3 precursor. Our data suggest that the location of the Escherichia coli RNase P cleavage site does not depend merely on the lengths of the acceptor-stem and T-stem as previously suggested. Surprisingly, we find that precursors with only four base-pairs in the acceptor-stem are cleaved by M1 RNA and by holoenzyme. Furthermore, we show that both disruption of base-pairing, and alteration of the nucleotide sequence (without disruption of base-pairing) proximal to the cleavage site result in aberrant cleavage. Thus, the identity of the nucleotides near the cleavage site is important for recognition of the cleavage site rather than base-pairing. The important nucleotides are those at positions -2, -1, +1, +72, +73 and +74. We propose that the nucleotide at position +1 functions as a guiding nucleotide. These results raise the possibility that Mg2+ binding near the cleavage site is dependent on the identity of the nucleotides at these positions. In addition, we show that disruption of base-pairing in the acceptor-stem affects both Michaelis-Menten constants, Km and kcat.     

Phosphohydrolases and the production of 5′-nucleotides by direct fermentation

A major problem involved in the direct fermentation of nucleotides is their breakdown by phosphohydrolases. Thus, adenine auxotrophs of most microorganisms produce hypoxanthine and/or inosine rather than inosine 5′-monophosphate (IMP) while guanine auxotrophs excrete xanthosine rather than xanthosine 5′-monophosphate (XMP). Examination of a Bacillus subtilis mutant producing hypoxanthine plus inosine revealed at least four phosphohydrolases, three of which could attack nucleotides. Even when the extracellular nucleotide phosphohydrolase was inhibited by Cu⁺² and its surface-bound alkaline phosphohydrolase was repressed and inhibited by inorganic phosphate, or removed by mutation, the breakdown products were still the only products of fermentation. Under these conditions, the third enzyme, a surface-bound non-repressible nucleotide phosphohydrolase was still active. It appears, at least in B. subtilis, that excretion is dependent upon breakdown by this enzyme and if hydrolysis does not occur, excretion of purine nucleotides is feedback inhibited by the resultant high intracellular IMP concentration. Corynebacterium glutamicum mutants, on the other hand, can excrete intact nucleotides, and direct fermentations for IMP, XMP, and GMP have been described. An examination of phosphohydrolases in a GMP-producing culture revealed no extracellular or surface enzymes. Disruption of the cells resulted in liberation of cellular phosphohydrolase activity with a substrate specificity remarkably similar to the flavorenhancing properties of the 5′-nucleotides. The order of decreasing susceptibility was GMP, IMP, XMP; AMP was not attacked.     

Purification of RNA using an anti-RNA monoclonal antibody.

Studies of the synthesis and modification of RNA employ many types of in vitro reactions. Often, the RNA product must be concentrated or purified away from other reaction components such as salts, unincorporated nucleotides, protein, or DNA. Here I describe an immunological approach suitable for the isolation of RNA from in vitro reactions. A variety of RNAs of differing size and nucleotide sequence were immunoprecipitated with a monoclonal antibody specific for RNA. RNA binding took place in seconds with nearly quantitative recoveries. Immunoprecipitation was more efficient than ethanol precipitation in removing unincorporated nucleotides. Proteins which do not bind to RNA remained soluble. The immunoprecipitated RNA sample was solubilized directly with a buffered solution suitable for gel electrophoresis under denaturing conditions. Thus, RNAs can be rapidly concentrated for electrophoresis in a single step. Antibody-RNA binding was reversible under nondenaturing conditions in the presence of excess rRNA. This procedure serves as a novel means of purifying RNA and RNA-binding proteins from in vitro reactions.     

Hypoxanthine guanine phosphoribosyltransferase distorts the purine ring of nucleotide substrates and perturbs the pKa of bound xanthosine monophosphate

Enzymatic efficiency and structural discrimination of substrates from nonsubstrate analogues are attributed to the precise assembly of binding pockets. Many enzymes have the additional remarkable ability to recognize several substrates. These apparently paradoxical attributes are ascribed to the structural plasticity of proteins. A partially defined active site acquires complementarity upon encountering the substrate and completing the assembly. Human hypoxanthine guanine phosphoribosyltransferase (hHGPRT) catalyzes the phosphoribosylation of guanine and hypoxanthine, while the Plasmodium falciparum HGPRT (PfHGPRT) acts on xanthine as well. Reasons for the observed differences in substrate specificities of the two proteins are not clear. We used ultraviolet resonance Raman spectroscopy to study the complexes of HGPRT with products (IMP, GMP, and XMP), in both organisms, in resonance with the purine nucleobase electronic absorption. This led to selective enhancement of vibrations of the purine ring over those of the sugar-phosphate backbone and protein. Spectra of bound nucleotides show that HGPRT distorts the structure of the nucleotides. The distorted structure resembles that of the deprotonated nucleotide. We find that the two proteins assemble similar active sites for their common substrates. While hHGPRT does not bind XMP, PfHGPRT perturbs the pK(a) of bound XMP. The results were compared with the mutant form of hHGPRT that catalyzed xanthine but failed to perturb the pK(a) of XMP.     

Evidence for the involvement of cytosolic 5'-nucleotidase (cN-II) in the synthesis of guanine nucleotides from xanthosine

In this paper, we show that in vitro xanthosine does not enter any of the pathways known to salvage the other three main natural purine nucleosides: guanosine; inosine; and adenosine. In rat brain extracts and in intact LoVo cells, xanthosine is salvaged to XMP via the phosphotransferase activity of cytosolic 5'-nucleotidase. IMP is the preferred phosphate donor (IMP + xanthosine --> XMP + inosine). XMP is not further phosphorylated. However, in the presence of glutamine, it is readily converted to guanyl compounds. Thus, phosphorylation of xanthosine by cytosolic 5'-nucleotidase circumvents the activity of IMP dehydrogenase, a rate-limiting enzyme, catalyzing the NAD(+)-dependent conversion of IMP to XMP at the branch point of de novo nucleotide synthesis, thus leading to the generation of guanine nucleotides. Mycophenolic acid, an inhibitor of IMP dehydrogenase, inhibits the guanyl compound synthesis via the IMP dehydrogenase pathway but has no effect on the cytosolic 5'-nucleotidase pathway of guanine nucleotides synthesis. We propose that the latter pathway might contribute to the reversal of the in vitro antiproliferative effect exerted by IMP dehydrogenase inhibitors routinely seen with repletion of the guanine nucleotide pools.     

Prebiotically plausible mechanisms increase compositional diversity of nucleic acid sequences

During the origin of life, the biological information of nucleic acid polymers must have increased to encode functional molecules (the RNA world). Ribozymes tend to be compositionally unbiased, as is the vast majority of possible sequence space. However, ribonucleotides vary greatly in synthetic yield, reactivity and degradation rate, and their non-enzymatic polymerization results in compositionally biased sequences. While natural selection could lead to complex sequences, molecules with some activity are required to begin this process. Was the emergence of compositionally diverse sequences a matter of chance, or could prebiotically plausible reactions counter chemical biases to increase the probability of finding a ribozyme? Our in silico simulations using a two-letter alphabet show that template-directed ligation and high concatenation rates counter compositional bias and shift the pool toward longer sequences, permitting greater exploration of sequence space and stable folding. We verified experimentally that unbiased DNA sequences are more efficient templates for ligation, thus increasing the compositional diversity of the pool. Our work suggests that prebiotically plausible chemical mechanisms of nucleic acid polymerization and ligation could predispose toward a diverse pool of longer, potentially structured molecules. Such mechanisms could have set the stage for the appearance of functional activity very early in the emergence of life.     

RoboOligo: software for mass spectrometry data to support manual and de novo sequencing of post-transcriptionally modified ribonucleic acids

Ribosomal ribonucleic acid (RNA), transfer RNA and other biological or synthetic RNA polymers can contain nucleotides that have been modified by the addition of chemical groups. Traditional Sanger sequencing methods cannot establish the chemical nature and sequence of these modified-nucleotide containing oligomers. Mass spectrometry (MS) has become the conventional approach for determining the nucleotide composition, modification status and sequence of modified RNAs. Modified RNAs are analyzed by MS using collision-induced dissociation tandem mass spectrometry (CID MS/MS), which produces a complex dataset of oligomeric fragments that must be interpreted to identify and place modified nucleosides within the RNA sequence. Here we report the development of RoboOligo, an interactive software program for the robust analysis of data generated by CID MS/MS of RNA oligomers. There are three main functions of RoboOligo: (i) automated de novo sequencing via the local search paradigm. (ii) Manual sequencing with real-time spectrum labeling and cumulative intensity scoring. (iii) A hybrid approach, coined ‘variable sequencing’, which combines the user intuition of manual sequencing with the high-throughput sampling of automated de novo sequencing.     

43 Why G? Aggregation and gelation of GMP with XMP: the plot thickens

GMP alone, among the individual ribonucleotides, exhibits a reversible self-aggregation through hydrogen bonding to form tetrads that are the building blocks of higher order structures. These “G-tetrads” can further associate through π–π stacking to form chiral, columnar aggregates and, at higher monomer concentrations, lyotropic liquid crystalline phases. This alternate pathway for GMP should compete with its incorporation into oligonucleotides, which is why it is difficult to synthesize or amplify highly G-rich RNA or DNA with good efficiency in the absence of natural proteins, such as helicases, that function to unwind the strands. Given this competing pathway for GMP, we can ask if it came to be one of the four ribonucleotides in modern RNA in spite of, or because of, its unique properties. Our hypothesis is that the competition between reversible aggregation and covalent polymerization directed RNA toward sequences that were best suited to life on early earth. We find support in the observation that the same interactions that promote self-assembly of monomeric GMP also promote folding of G-rich RNA and DNA sequences to form inter- and intramolecular G-quadruplex structures. Such sequences are prevalent throughout the biological world and are thought to serve important functions related to genomic stability and gene regulation. G-quadruplex structures are also common motifs in aptamers, which are combinatorially derived DNA or RNA sequences that exhibit highly selective, high-affinity binding to molecular and macromolecular targets. An important consideration for GMP aggregation in a prebiotic RNA World scenario is the effect of other XMP on GMP self-assembly. In this talk, we will focus on the properties of solutions containing mixtures of GMP with AMP, CMP, and UMP. The results show that each nucleotide exerts a different influence on the self-assembly of GMP, raising interesting questions about scenarios on prebiotic Earth that would be consistent with abiotic RNA polymerization.     

Laccase‐catalysed polymeric dye synthesis from plant‐derived phenols for potential application in hair dyeing: Enzymatic colourations driven by homo‐ or hetero‐polymer synthesis

Laccase efficiently catalyses polymerization of phenolic compounds. However, knowledge on applications of polymers synthesized in this manner remains scarce. Here, the potential of laccase-catalysed polymerization of natural phenols to form products useful in hair dyeing was investigated. All 15 tested phenols yielded coloured products after laccase treatment and colour diversity was attained by using mixtures of two phenolic monomers. After exploring colour differentiation pattern of 120 different reactions with statistical regression analysis, three monomer combinations, namely gallic acid and syringic acid, catechin and catechol, and ferulic acid and syringic acid, giving rise to brown, black, and red materials, respectively, were further characterized because such colours are commercially important for grey hair dyeing. Selected polymers could strongly absorb visible light and their hydrodynamic sizes ranged from 100 to 400 nm. Analyses of enzyme kinetic constants, liquid chromatography and electrospray ionization-mass spectrometry (ESI-MS) coupled with collision-induced dissociation MS/MS indicate that both monomers in reactions involving catechin and catechol, and ferulic acid and syringic acid, are coloured by heteropolymer synthesis, but the gallic acid/syringic acid combination is based on homopolymer mixture formation. Comparison of colour parameters from these three reactions with those of corresponding artificial homopolymer mixtures also supported the idea that laccase may catalyse either hetero- or homo-polymer synthesis. We finally used selected materials to dye grey hair. Each material coloured hair appropriately and the dyeing showed excellent resistance to conventional shampooing. Our study indicates that laccase-catalysed polymerization of natural phenols is applicable to the development of new cosmetic pigments.     

The rule of six, a basic feature for efficient replication of Sendai virus defective interfering RNA.

The addition of the hepatitis delta virus genomic ribozyme to the 3' end sequence of a Sendai virus defective interfering RNA (DI-H4) allowed the reproducible and efficient replication of this RNA by the viral functions expressed from cloned genes when the DI RNA was synthesized from plasmid. Limited nucleotide additions or deletions (+7 to -7 nucleotides) in the DI RNA sequence were then made at five different sites, and the different RNA derivatives were tested for their abilities to replicate. Efficient replication was observed only when the total nucleotide number was conserved, regardless of the modifications, or when the addition of a total of 6 nucleotides was made. The replicated RNAs were shown to be properly enveloped into virus particles. It is concluded that, to form a proper template for efficient replication, the Sendai virus RNA must contain a total number of nucleotides which is a multiple of 6. This was interpreted as the need for the nucleocapsid protein to contact exactly 6 nucleotides.     

Chemical alterations taken place during deep-fat frying based on certain reaction products: A review

Deep-fat frying at 180°C or above is one of the most common food processing methods used for preparing of human kind foods worldwide. However, a serial of complex reactions such as oxidation, hydrolysis, isomerization, and polymerization take place during the deep-fat frying course and influence quality attributes of the final product such as flavor, texture, shelf life and nutrient composition. The influence of these reactions results from a number of their products including volatile compounds, hydrolysis products, oxidized triacylglycerol monomers, cyclic compounds, trans configuration compounds, polymers, sterol derivatives, nitrogen- and sulphur-containing heterocyclic compounds, acrylamide, etc. which are present in both frying oil and the fried food. In addition, these reactions are interacted and influenced by various impact factors such as frying oil type, frying conditions (time, temperature, fryer, etc.) and fried material type. Based on the published literatures, three main organic chemical reaction mechanisms namely hemolytic, heterolytic and concerted reaction were identified and supposed to elucidate the complex chemical alterations during deep-fat frying. However, well understanding the mechanisms of these reactions and their products under different conditions helps to control the deep-fat frying processing; therefore, producing healthy fried foods. By means of comprehensively consulting the papers which previously studied on the chemical changes occurred during deep-fat frying process, the major reaction products and corresponding chemical alterations were reviewed in this work.     

Accumulation of 5′ guanine nucleotides by mutants of Brevibacterium ammoniagenes

5′Xanthylic acid was efficiently converted to 5′guanine nucleotides (5′GMP, 5′GDP, and 5′GTP) without being degraded to guanine via 5′GMP by decoyinine resistant mutants of strain KY 13315 which had been isolated from Brevibacterium ammoniagenes and was practically devoid of 5′nucleotide degrading activity. The concentration of phosphate in the medium showed a profound effect on the ratio of the accumulated 5′guanine nucleotides, making it possible to direct the fermentation towards 5′GMP or 5′GTP. A direct accumulation of 5′guanine nucleotides from carbohydrate was possible by mixed cultivation of a 5′XMP accumulating strain and a 5′XMP converting mutant. A maximum concentration of 9.67 mg of 5′guanine nucleotides per ml was obtained directly from glucose in such a mixed culture.