Domain protolife

We propose the Thermal Protein First Paradigm (protocell theory) that affirms that first life was cellular. The first cells emerged from molecular (chemical) evolution as protocells (heated amino acids self-order in copolymerization reactions to form thermal proteins which self-organize when in contact with water to form protocells). Metaprotocells are specialized protocells capable of synthesizing ATP (light energy conversion to chemical energy), polypeptides, and polynucleotides. Aggregations of protocells in thermal protein matrices form distinctive morphologies (protocellular networks). Prokaryotic cells emerged from metaprotocells. We classify protocells and metaprotocells as members of the Domain Protolife. We revised the cell theory to include protolife.     

Synthesis of life in the lab? Defining a protoliving system

The synthesis of a living system in the lab has been judged by a number of critics as partly attained by the proteinoid microsphere because of its primitive properties of metabolism, growth, and reproduction. These same critics, however, judge the organism as not alive, or as being 50 to 75 percent alive (Baltscheffsky and Jurka, 1984), owing to the absence of a nucleic acid genetic coding mechanism. The experiments in retracing evolution suggest, however, that the self-sequencing of amino acids was the evolutionary precursor of modern nucleic acid templating; the genetic memory is the molecule. The proteinoid microsphere is not a modern living system, but does represent at least a protoliving system (Fox and Dose, 1972). Berra (1990, p. 75) has commented on other difficulties in defining a protoliving system. In Berra's opinion, metabolism, reproduction, responsiveness to stimuli, and cellularity constitute or describe aliveness. These properties characterize proteinoid microspheres. A number of experiments demonstrate that amino acids in aminoacyl adenylates yield specific products, whereas nucleotides are without effect. For this and related reasons, especially the demonstrated self-sequencing of amino acids when they are warmed, resultant bio-functional properties of self-assembled microstructures, and demonstrated self-sequencing of amino acids in modern systems, the results appear to bridge from the chemical era to the biological period. All the above emerges from a departure in style of research (Young, 1984; Pauling and Zuckerkandl, 1972). The latter authors said, "It appears likely that biogenesis is the passage from a 'non-living system' existing in a large number of states to a 'living' system also existing in a large number of states."(ABSTRACT TRUNCATED AT 250 WORDS)     

Experimental retracement of the origins of a protocell

Although Oparin used coacervate droplets from two or more types of polymer to model the first cell, he hypothesized homacervation from protein, consistent with Pasteur and Darwin. Herrera made two amino acids and numerous cell-like structures (sulfobes) in the laboratory, which probably arose from intermediate polymers. Our experiments have conformed with a homoacervation of thermal proteinoid, in which amino acid sequences are determined by the reacting amino acids themselves. All proteinoids that have been tested assemble themselves alone in water to protocells. The protocells have characteristics of life defined by Webster's Dictionary: metabolism, growth, reproduction and response to stimuli in the environment. The protocells are able also to evolve to more modern cells including the initiation of a nucleic acid coding system.Principal spinoffs from the results are revised evolutionary theory, models for protoneurons and networks thereof, and numerous industrial applications of thermal polyamino acids. Life itself has thus been reaffirmed to be rooted in protein, not in DNA nor RNA, which are however crucial to inheritance in modern life as instruction manual (Kornberg).Recognition of the advances have been considerably delayed by the deeply held assumption that life began by chance from random polymerization of amino acids, in contrast to the experimental findings. The concepts of DNA/RNA-first and protein-first are reconciled by a rise-and-fall progression as often seen in biochemical and biological evolution.The fact that amino acids order themselves explains in turn that thermal copolyamino acids are finding numerous applications. The entire sequence of processes in the proteinoid origins theory is now seen to be highly deterministic, in close accord with Einstein.     

Chemical and catalytical properties of thermal polymers of amino acids (proteinoids)

The significance of thermal polyamino acids (proteinoids) as abiotic predecessors of proteins is reviewed on the basis of new experimental results. Most proteinoids yield only 50% to 80% amino acid upon acid hydrolysis. They contain 40% to 60% less peptide links than typical proteins, whereas their average nitrogen content is like that of proteins. The arrangement of amino acid residues is nonrandom. The degree of nonrandomness is difficult to determine because unusual crosslinks disturb most of the sequencing methods typically applied, in protein chemistry. The products obtained in a polymerization experiment are heterogeneous. They can be separated into a limited number of related fractions by chromatography or electrophoresis and other separation methods applied in protein chemistry. Their molecular weights are typically between 400 and 10 000. The number of free NH₂-groups, is usually smaller than in comparable proteins A significant fraction of NH₂-groups yields imidazole-type bases during the thermal polymerization. Optically active amino acids racemize during the same process. So far no helicity could be detected. Proteinoids are thus clearly distinct from proteins However, many of them exhibit weak catalytic activities and tend to undergo self-assembly into microstructures. Their properties of which only a few have been mentioned still support their role as possible candidates for ancestors of first proteins.     

Amino Acid Metabolic Origin as an Evolutionary Influence on Protein Sequence in Yeast

The metabolic cycle of Saccharomyces cerevisiae consists of alternating oxidative (respiration) and reductive (glycolysis) energy-yielding reactions. The intracellular concentrations of amino acid precursors generated by these reactions oscillate accordingly, attaining maximal concentration during the middle of their respective yeast metabolic cycle phases. Typically, the amino acids themselves are most abundant at the end of their precursor’s phase. We show that this metabolic cycling has likely biased the amino acid composition of proteins across the S. cerevisiae genome. In particular, we observed that the metabolic source of amino acids is the single most important source of variation in the amino acid compositions of functionally related proteins and that this signal appears only in (facultative) organisms using both oxidative and reductive metabolism. Periodically expressed proteins are enriched for amino acids generated in the preceding phase of the metabolic cycle. Proteins expressed during the oxidative phase contain more glycolysis-derived amino acids, whereas proteins expressed during the reductive phase contain more respiration-derived amino acids. Rare amino acids (e.g., tryptophan) are greatly overrepresented or underrepresented, relative to the proteomic average, in periodically expressed proteins, whereas common amino acids vary by a few percent. Genome-wide, we infer that 20,000 to 60,000 residues have been modified by this previously unappreciated pressure. This trend is strongest in ancient proteins, suggesting that oscillating endogenous amino acid availability exerted genome-wide selective pressure on protein sequences across evolutionary time. Electronic supplementary material  The online version of this article (doi:) contains supplementary material, which is available to authorized users. Benjamin L. de Bivort and Ethan O. Perlstein have contributed equally to this work.     

Efforts towards the design of 'teflon' proteins: in vivo translation with trifluorinated leucine and methionine analogues

In vivo incorporation of monofluorinated noncanonical amino acids into recombinant proteins has been well-established for decades. Proteins fluorinated in this way proved to be useful tools for many practical applications. In contrast, trifluorinated amino acids have been incorporated in only a few peptides and relatively small proteins by using expression systems in living cells. A novel class of proteins with a fluorous core can be envisaged only if full replacement of the core-building hydrophobic and aliphatic amino acids such as leucine or methionine with the related analogues trifluoromethionine and trifluoroleucine would be feasible. However, our systematic efforts to introduce these amino acids in larger proteins (over 10 Da) that contain different structural motifs clearly show that only partial substitutions are possible. The reasons are high toxicity of these substances and difficulties to accommodate them into the compact cores of natural proteins without adverse effects on their structural integrity. Therefore, engineering of such three dimensional 'Teflon'-like structures would require, besides an expansion of the amino acid repertoire of the genetic code, a de novo protein design as well.     

Bioenergetics and Life's Origins

Bioenergetics is central to our understanding of living systems, yet has attracted relatively little attention in origins of life research. This article focuses on energy resources available to drive primitive metabolism and the synthesis of polymers that could be incorporated into molecular systems having properties associated with the living state. The compartmented systems are referred to as protocells, each different from all the rest and representing a kind of natural experiment. The origin of life was marked when a rare few protocells happened to have the ability to capture energy from the environment to initiate catalyzed heterotrophic growth directed by heritable genetic information in the polymers. This article examines potential sources of energy available to protocells, and mechanisms by which the energy could be used to drive polymer synthesis.Previous research on life''s origins has for the most part focused on the chemistry and energy sources required to produce the small molecules of life—amino acids, nucleobases, and amphiphiles—and to a lesser extent on condensation reactions by which the monomers can be linked into biologically relevant polymers. In modern living cells, polymers are synthesized from activated monomers such as the nucleoside triphosphates used by DNA and RNA polymerases, and the tRNA-amino acyl conjugates that supply ribosomes with activated amino acids. Activated monomers are essential because polymerization reactions occur in an aqueous medium and are therefore energetically uphill in the absence of activation.A central problem therefore concerns mechanisms by which prebiotic monomers could have been activated to assemble into polymers. Most biopolymers of life are synthesized when the equivalent of a water molecule is removed to form the ester bonds of nucleic acids, glycoside bonds of polysaccharides, and peptide bonds in proteins. In life today, the removal of water is performed upstream of the actual bond formation. This process involves the energetically downhill transfer of electrons, which is coupled to either substrate-level oxidation or generation of a proton gradient that in turn is the energy source for the synthesis of anhydride pyrophosphate bonds in ATP. The energy stored in the pyrophosphate bond is then distributed throughout the cell to drive most other energy‐dependent reactions. This is a complex and highly evolved process, so here we consider simpler ways in which energy could have been captured from the environment and made available for primitive versions of metabolism and polymer synthesis. Because the atmosphere of the primitive Earth did not contain appreciable oxygen, this review of primitive bioenergetics is limited to anaerobic sources of energy.     

Screening of Lysine-rich Plant Species and Identification of the Purified Proteins

The nutritional quality of seed proteins from cereals, such as wheat and rice, is comparatively low due to its deficency in lysine and some essential amino acids. In this research extensive varieties of plant seed samples were collected and screened by analysis of amino acid composition. Three lysing-rich species which contain more than 6.7% of lysine in total seed proteins were found. 31 kinds of proteins were purified from a species which contains 7.9% of lysine using the modified methods of IEF and SDS electrophoresis. One protein with PI 6.1 and 18 kD was identified which contains 11.4% of lysine and was rich in threonine, valine and isoleucine. This is the first example of the protein which could complement several limiting amino acids of wheat or rice. Further research on the structural gene encoding this protein would have great potential value for improvement of protein quality of these cereals.     

中药鳖甲及两种炮制品的氨基酸营养学

本文报导了鳖甲及其炮制品的氨基酸营养分析情况。结果表明,生品含17种游离氨基酸,传统炮制品含15种游离氨基酸,食用菌炮制品含16种游离氨基酸,且生品总氨基酸的含量明显高于炮制品,经盐酸水解后,炮制前后的样品均测得17种氨基酸,生品的含量略高于炮制品,炮制品前后样品中所测游离氨基酸和水解后氨基酸均含有8种人体必需氨基酸。     

细胞因子FAM3家族研究进展

FAM3家族是2002年新发现的一个细胞因子样基因家族,由FAM3A、FAM3B、FAM3C和FAM3D4个成员组成,分别编码含有224—235个氨基酸残基的多肽,它们在二级结构上都具有4个α螺旋。这种二级结构特征与一些细胞因子相似。本文综述了FAM3家族成员的基因定位及结构、基因表达和分泌的调控,以及生理功能和病理意义的研究进展。     

Structural features of single amino acid repeats in proteins

Single amino acid repeats are found in different kinds of proteins. Some of these repeats are pathogenic. It is striking that some amino acids are able to form such repeats, but other amino acids are not. We suggest an explanation for this fact based on the different tendency of each amino acid to form aggregates. Aggregation may be due to the formation of incipient lamellar crystals as they have been described in poly-alpha-amino acids and in most synthetic polymers.     

Characterization of a sterile dwarf mutant and the cloning of zeaxanthin epoxidase in Asian cotton (<Emphasis Type="Italic">Gossypium arboreum</Emphasis> L.)

Amino acids are constituents of proteins, precursors of many secondary metabolites and nitrogen carriers in plants. Transport across intracellular membranes and translocation of amino acids within the plant is mediated by membrane amino acid transporters. However, the amino acid transport in tea plant is rarely reported. In this study, six cationic amino acid transporter (CAT) family genes were cloned. Phylogenetic analysis categorized these CsCATs into four subgroups. These CsCATs all contain the 12–14 transmembrane domains and the conserved CAT motifs. Their expression was tissue-specific, with higher expression levels in root and stem and correlated to the abundances of key free amino acids such as Theanine. Some CsCATs expression responded to some abiotic stress conditions and to the exogenous application of theanine (Thea), glutamine or ethylamine hydrochloride, an ethylamine precursor for Thea biosynthesis. Our results indicated that the CsCATs expression is regulated by amino acid contents and is sensitive to abiotic stresses. These findings shed light on the mechanism of amino acid transport in tea plants.     

Two mRNAs that differ by two nontemplated nucleotides encode the amino coterminal proteins P and V of the paramyxovirus SV5

The "P" gene of the paramyxovirus SV5 encodes two known proteins, P (Mr approximately equal to 44,000) and V (Mr approximately equal to 24,000). The complete nucleotide sequence of the "P" gene has been obtained and is found to contain two open reading frames, neither of which is large enough to encode the P protein. We have shown that the P and V proteins are translated from two mRNAs that differ by the presence of two nontemplated G residues in the P mRNA. These two additional nucleotides convert the two open reading frames to one of 392 amino acids. The P and V proteins are amino coterminal and have 164 amino acids in common. The unique C terminus of V consists of a cysteine-rich region that resembles a cysteine-rich metal binding domain. An open reading frame that contains this cysteine-rich region exists in all other paramyxovirus "P" gene sequences examined, which suggests that it may have important biological significance.     

Bioinformatic identification of the most ancient copper protein architecture

Since copper ions participate in many cellular processes and are implicated in pathogenesis of many diseases, copper proteins have important biological significance. Thus, it is of interest to explore their origins, especially to address the following question: which is the most ancient architecture of copper proteins? In this paper, through analyzing the architectural features of copper proteins, we find that the fold-domain relationship of these proteins follows a power law, which can be explained by preferential attachment principle and implicates that the architecture of the most ancient copper proteins belonged to Cupredoxin-like (b.6) fold. According to the chronology of protein folds, this architecture originated rather late, which can be understood in terms of the low abundance of reducing amino acids (e.g., His, Cys and/or Met) in the primordial world, because these amino acids are required by copper proteins to bind copper ions.     

An analysis of the helix-to-strand transition between peptides with identical sequence

An analysis of peptide segments with identical sequence but that differ significantly in structure was performed over non-redundant databases of protein structures. We focus on those peptides, which fold into an alpha-helix in one protein but a beta-strand in another. While the study shows that many such structurally ambivalent peptides contain amino acids with a strong helical preference collocated with amino acids with a strong strand preference, the results overwhelmingly indicate that the peptide's environment ultimately dictates its structure. Furthermore, the first naturally occurring structurally ambivalent nonapeptide from evolutionary unrelated proteins is described, highlighting the intrinsic plasticity of peptide sequences. We even find seven proteins that show structural ambivalence under different conditions. Finally, a computer algorithm has been implemented to identify regions in a given sequence where secondary structure prediction programs are likely to make serious mispredictions.     

红花种子氨基酸分析

本文用日立８３５—５０型氨基酸自动测定仪进行去油后不同地区红花种子粉末氨基酸的测定,实验结果表明,红花种子含１６—１９种氨基酸,其中有７—８种人体必需氨基酸。     

An internal region of the peroxisomal membrane protein PMP47 is essential for sorting to peroxisomes

Targeting sequences on peroxisomal membrane proteins have not yet been identified. We have attempted to find such a sequence within PMP47, a protein of the methylotrophic yeast, Candida boidinii. This protein of 423 amino acids shows sequence similarity with proteins in the family of mitochondrial carrier proteins. As such, it is predicted to have six membrane-spanning domains. Protease susceptibility experiments are consistent with a six-membrane-spanning model for PMP47, although the topology for the peroxisomal protein is inverted compared with the mitochondrial carrier proteins. PMP47 contains two potential peroxisomal targeting sequences (PTS1), an internal SKL (residues 320- 322) and a carboxy terminal AKE (residues 421-423). Using a heterologous in vivo sorting system, we show that efficient sorting occurs in the absence of both sequences. Analysis of PMP47- dihydrofolate reductase (DHFR) fusion proteins revealed that amino acids 1-199 of PMP47, which contain the first three putative membrane spans, do not contain the necessary targeting information, whereas a fusion with amino acids 1-267, which contains five spans, is fully competent for sorting to peroxisomes. Similarly, a DHFR fusion construct containing residues 268-423 did not target to peroxisomes while residues 203-420 appeared to sort to that organelle, albeit at lower efficiency than the 1-267 construct. However, DHFR constructs containing only amino acids 185-267 or 203-267 of PMP47 were not found to be associated with peroxisomes. We conclude that amino acids 199-267 are necessary for peroxisomal targeting, although additional sequences may be required for efficient sorting to, or retention by, the organelles.     

Diversity among beta-tubulins: a carboxy-terminal domain of yeast beta-tubulin is not essential in vivo.

Sequences of genes for beta-tubulins from many different organisms demonstrate that they encode highly conserved proteins but that these proteins diverge considerably at their carboxyl termini. The patterns of interspecies conservation of this diversity suggest that it may have functional significance. We have taken advantage of the properties of Saccharomyces cerevisiae to test this hypothesis in vivo. The sole beta-tubulin gene of this species is one of the most divergent of all beta-tubulins and encodes 12 amino acids which extend past the end of most other beta-tubulin molecules. We have constructed strains in which the only beta-tubulin gene is an allele lacking these 12 codons. We show here that this carboxy-terminal extension is not essential. The absence of these 12 amino acids had no effect on a number of microtubule-dependent functions, such as mitotic and meiotic division and mating. It did confer dominant supersensitivity to a microtubule-depolymerizing drug.     

A biophysical basis for the emergence of the genetic code in protocells

The origin of the genetic code is an abiding mystery in biology. Hints of a ‘code within the codons’ suggest biophysical interactions, but these patterns have resisted interpretation. Here, we present a new framework, grounded in the autotrophic growth of protocells from CO₂ and H₂. Recent work suggests that the universal core of metabolism recapitulates a thermodynamically favoured protometabolism right up to nucleotide synthesis. Considering the genetic code in relation to an extended protometabolism allows us to predict most codon assignments. We show that the first letter of the codon corresponds to the distance from CO₂ fixation, with amino acids encoded by the purines (G followed by A) being closest to CO₂ fixation. These associations suggest a purine-rich early metabolism with a restricted pool of amino acids. The second position of the anticodon corresponds to the hydrophobicity of the amino acid encoded. We combine multiple measures of hydrophobicity to show that this correlation holds strongly for early amino acids but is weaker for later species. Finally, we demonstrate that redundancy at the third position is not randomly distributed around the code: non-redundant amino acids can be assigned based on size, specifically length. We attribute this to additional stereochemical interactions at the anticodon. These rules imply an iterative expansion of the genetic code over time with codon assignments depending on both distance from CO₂ and biophysical interactions between nucleotide sequences and amino acids. In this way the earliest RNA polymers could produce non-random peptide sequences with selectable functions in autotrophic protocells.     

Bioinformatic Identification of the Most Ancient Copper Protein Architecture

Abstract

Since copper ions participate in many cellular processes and are implicated in pathogenesis of many diseases, copper proteins have important biological significance. Thus, it is of interest to explore their origins, especially to address the following question: which is the most ancient architecture of copper proteins? In this paper, through analyzing the architectural features of copper proteins, we find that the fold-domain relationship of these proteins follows a power law, which can be explained by preferential attachment principle and implicates that the architecture of the most ancient copper proteins belonged to Cupredoxin-like (b.6) fold. According to the chronology of protein folds, this architecture originated rather late, which can be understood in terms of the low abundance of reducing amino acids (e.g., His, Cys and/or Met) in the primordial world, because these amino acids are required by copper proteins to bind copper ions.