Is tRNA only a translation factor or also a regulator of other processes?

Hypothesis for Molecular Evolution in the Pre-Cellular Stage of the Origin of Life

Life was originated from inorganic world and had experienced a long period of evolution in about 3.8 billion years. The time for emergence of the pioneer creations on Earth is debatable nowadays, and how the scenario for the prebiotic molecular interactions is still mysterious. Before the spreading of cellular organisms, chemical evolution was perhaps prevailing for millions of years, in which inorganic biosynthesis was ultimately replaced by biochemical reactions. Understanding the major molecular players and their interactions toward cellular life is fundamental for current medical science and extraterrestrial life exploration. In this review, we propose a road map for the primordial molecular evolution in early Earth, which probably occurred adjacent to hydrothermal vents with a strong gradient of organic molecules, temperature, and metal contents. Natural selection of the macromolecules with strong secondary structures and catalytic centers is associated with decreasing of overall entropy of the biopolymers. Our review may shed lights into the important selection of gene-coding RNA with secondary structures from large amounts of random biopolymers and formation of ancient ribosomes with biological machines supporting the basic life processes. Integration of the free environmental ribosomes by the early cellular life as symbiotic molecular machines is probably the earliest symbiosis on Earth.

Self-empowerment of life through RNA networks, cells and viruses

Our understanding of the key players in evolution and of the development of all organisms in all domains of life has been aided by current knowledge about RNA stem-loop groups, their proposed interaction motifs in an early RNA world and their regulative roles in all steps and substeps of nearly all cellular processes, such as replication, transcription, translation, repair, immunity and epigenetic marking. Cooperative evolution was enabled by promiscuous interactions between single-stranded regions in the loops of naturally forming stem-loop structures in RNAs. It was also shown that cooperative RNA stem-loops outcompete selfish ones and provide foundational self-constructive groups (ribosome, editosome, spliceosome, etc.). Self-empowerment from abiotic matter to biological behavior does not just occur at the beginning of biological evolution; it is also essential for all levels of socially interacting RNAs, cells and viruses.

Self-empowerment of life through RNA networks, cells and viruses

Our understanding of the key players in evolution and of the development of all organisms in all domains of life has been aided by current knowledge about RNA stem-loop groups, their proposed interaction motifs in an early RNA world and their regulative roles in all steps and substeps of nearly all cellular processes, such as replication, transcription, translation, repair, immunity and epigenetic marking. Cooperative evolution was enabled by promiscuous interactions between single-stranded regions in the loops of naturally forming stem-loop structures in RNAs. It was also shown that cooperative RNA stem-loops outcompete selfish ones and provide foundational self-constructive groups (ribosome, editosome, spliceosome, etc.). Self-empowerment from abiotic matter to biological behavior does not just occur at the beginning of biological evolution; it is also essential for all levels of socially interacting RNAs, cells and viruses.

The Ribosome as a Missing Link in Prebiotic Evolution III: Over-Representation of tRNA- and rRNA-Like Sequences and Plieofunctionality of Ribosome-Related Molecules Argues for the Evolution of Primitive Genomes from Ribosomal RNA Modules

We propose that ribosomal RNA (rRNA) formed the basis of the first cellular genomes, and provide evidence from a review of relevant literature and proteonomic tests. We have proposed previously that the ribosome may represent the vestige of the first self-replicating entity in which rRNAs also functioned as genes that were transcribed into functional messenger RNAs (mRNAs) encoding ribosomal proteins. rRNAs also encoded polymerases to replicate itself and a full complement of the transfer RNAs (tRNAs) required to translate its genes. We explore here a further prediction of our “ribosome-first” theory: the ribosomal genome provided the basis for the first cellular genomes. Modern genomes should therefore contain an unexpectedly large percentage of tRNA- and rRNA-like modules derived from both sense and antisense reading frames, and these should encode non-ribosomal proteins, as well as ribosomal ones with key cell functions. Ribosomal proteins should also have been co-opted by cellular evolution to play extra-ribosomal functions. We review existing literature supporting these predictions. We provide additional, new data demonstrating that rRNA-like sequences occur at significantly higher frequencies than predicted on the basis of mRNA duplications or randomized RNA sequences. These data support our “ribosome-first” theory of cellular evolution.

Machine Learning Predicts the Yeast Metabolome from the Quantitative Proteome of Kinase Knockouts

A challenge in solving the genotype-to-phenotype relationship is to predict a cell’s metabolome, believed to correlate poorly with gene expression. Using comparative quantitative proteomics, we found that differential protein expression in 97 Saccharomyces cerevisiae kinase deletion strains is non-redundant and dominated by abundance changes in metabolic enzymes. Associating differential enzyme expression landscapes to corresponding metabolomes using network models provided reasoning for poor proteome-metabolome correlations; differential protein expression redistributes flux control between many enzymes acting in concert, a mechanism not captured by one-to-one correlation statistics. Mapping these regulatory patterns using machine learning enabled the prediction of metabolite concentrations, as well as identification of candidate genes important for the regulation of metabolism. Overall, our study reveals that a large part of metabolism regulation is explained through coordinated enzyme expression changes. Our quantitative data indicate that this mechanism explains more than half of metabolism regulation and underlies the interdependency between enzyme levels and metabolism, which renders the metabolome a predictable phenotype.

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The proteome of kinase knockouts is dominated by enzyme abundance changes

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The enzyme expression profiles of kinase knockouts are non-redundant

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Metabolism is regulated by many expression changes acting in concert

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Machine learning accurately predicts the metabolome from enzyme abundance

The widespread occurrence of tRNA-derived fragments in Saccharomyces cerevisiae

Short RNAs derived from the cleavage of tRNA molecules are observed in most organisms. Their occurrence seems to be induced by stress conditions, but still little is known about their biogenesis and functions. We find that the recovery of tRNA fragments depends on the RNA isolation method. Using an optimized RNA extraction protocol and northern blot hybridization technique, we show that the tRNA-derived fragments in yeast are widespread in 12 different growth conditions. We did not observe significant stress-dependent changes in the amounts of tRNA fragments pool. Instead, we show the differential processing of almost all individual tRNAs. We also provide evidence that 3'-part-derived tRNA fragments are as abundant as the 5'- one in Saccharomyces cerevisiae. The resulting set of S. cerevisiae tRNA fragments provides a robust basis for further experimental studies on biological functions of tRFs.

Every little piece counts: the many faces of tRNA transcripts

For over half a century, tRNAs have been exclusively known as decoders of genomic information. However, recent reports evidenced that tRNA transcripts are also bearers of functional RNAs, which are able to execute various tasks through an array of mechanisms. Here, we succinctly review the diversity and functions of RNAs deriving from tRNA loci.

A game of tag: MAPS catches up on RNA interactomes

In the last few decades, small regulatory RNA (sRNA) molecules emerged as key regulators in every kingdom of life. Resolving the full targetome of sRNAs has however remained a challenge. To address this, we used an in vivo tagging MS2-affinity purification protocol coupled with RNA sequencing technology, namely MAPS, to assemble full bacterial small RNAs targetomes. The impressive potential of MAPS has been supported by a number of reports. Here, we concisely overview RNA-tagging history that preceded the development of the MAPS assay and expose the range of possible uses of this technology.

In Vitro/In Vivo Production of tRNA for X-Ray Studies

tRNAs occupy a central role in the cellular life, and they are involved in a broad range of biological processes that relies on their interaction with proteins and RNA. Crystallization and structure resolution of tRNA or/and tRNA/partner complexes can yield in valuable information on structural organizations of key elements of cellular machinery. However, crystallization of RNA, is often challenging. Here we review two methods to produce and purify tRNA in quantity and quality to perform X-ray studies.

RNA sociology: group behavioral motifs of RNA consortia

RNA sociology investigates the behavioral motifs of RNA consortia from the social science perspective. Besides the self-folding of RNAs into single stem loop structures, group building of such stem loops results in a variety of essential agents that are highly active in regulatory processes in cellular and non-cellular life. RNA stem loop self-folding and group building do not depend solely on sequence syntax; more important are their contextual (functional) needs. Also, evolutionary processes seem to occur through RNA stem loop consortia that may act as a complement. This means the whole entity functions only if all participating parts are coordinated, although the complementary building parts originally evolved for different functions. If complementary groups, such as rRNAs and tRNAs, are placed together in selective pressure contexts, new evolutionary features may emerge. Evolution initiated by competent agents in natural genome editing clearly contrasts with statistical error replication narratives.

tRNA modifications: necessary for correct tRNA-derived fragments during the recovery from stress?

Endonuclease-mediated tRNA fragmentation has been observed in many species suggesting functional importance for tRNA fragments. The size distribution of tRNA-derived fragments indicates the existence of mechanisms that protect tRNAs and their fragments from total degradation by exonucleases. Could post-transcriptional modifications be important for the controlled processing of tRNAs?

Contextualizing context for synthetic biology--identifying causes of failure of synthetic biological systems

Despite the efforts that bioengineers have exerted in designing and constructing biological processes that function according to a predetermined set of rules, their operation remains fundamentally circumstantial. The contextual situation in which molecules and single-celled or multi-cellular organisms find themselves shapes the way they interact, respond to the environment and process external information. Since the birth of the field, synthetic biologists have had to grapple with contextual issues, particularly when the molecular and genetic devices inexplicably fail to function as designed when tested in vivo. In this review, we set out to identify and classify the sources of the unexpected divergences between design and actual function of synthetic systems and analyze possible methodologies aimed at controlling, if not preventing, unwanted contextual issues.

tRNA nucleotidyltransferases: ancient catalysts with an unusual mechanism of polymerization

RNA polymerases are important enzymes involved in the realization of the genetic information encoded in the genome. Thereby, DNA sequences are used as templates to synthesize all types of RNA. Besides these classical polymerases, there exists another group of RNA polymerizing enzymes that do not depend on nucleic acid templates. Among those, tRNA nucleotidyltransferases show remarkable and unique features. These enzymes add the nucleotide triplet C-C-A to the 3'-end of tRNAs at an astonishing fidelity and are described as "CCA-adding enzymes". During this incorporation of exactly three nucleotides, the enzymes have to switch from CTP to ATP specificity. How these tasks are fulfilled by rather simple and small enzymes without the help of a nucleic acid template is a fascinating research area. Surprising results of biochemical and structural studies allow scientists to understand at least some of the mechanistic principles of the unique polymerization mode of these highly unusual enzymes.

Diversity and similarity in the tRNA world: overall view and case study on malaria-related tRNAs

Transfer RNAs (tRNAs) are ancient macromolecules that have evolved under various environmental pressures as adaptors in translation in all forms of life but also towards alternative structures and functions. The present knowledge on both "canonical" and "deviating" signature motifs retrieved from vertical and horizontal sequence comparisons is briefly reviewed. Novel characteristics, proper to tRNAs from a given translation system, are revealed by a case study on the nuclear and organellar tRNA sets from malaria-related organisms. Unprecedented distinctive features for Plasmodium falciparum apicoplastic tRNAs appear, which provide novel routes to be explored towards anti-malarial drugs. The ongoing high-throughput sequencing programs are expected to allow for further horizontal comparisons and to reveal other signatures of either full or restricted sets of tRNAs.

Human D-Tyr-tRNATyr deacylase contributes to the resistance of the cell to D-amino acids

DTD (D-Tyr-tRNATyr deacylase) is known to be able to deacylate D-aminoacyl-tRNAs into free D-amino acids and tRNAs and therefore contributes to cellular resistance against D-amino acids in Escherichia coli and yeast. We have found that h-DTD (human DTD) is enriched in the nuclear envelope region of mammalian cells. Treatment of HeLa cells with D-Tyr resulted in nuclear accumulation of tRNATyr. D-Tyr treatment and h-DTD silencing caused tRNATyr downregulation. Furthermore, inhibition of protein synthesis by D-Tyr treatment and h-DTD silencing were also observed. D-Tyr, D-Asp and D-Ser treatment inhibited mammalian cell viability in a dose-dependent manner; overexpression of h-DTD decreased the inhibition rate, while h-DTD-silenced cells became more sensitive to the D-amino acid treatment. Our results suggest that h-DTD may play an important role in cellular resistance against D-amino acids by deacylating D-aminoacyl tRNAs at the nuclear pore. We have also found that m-DTD (mouse DTD) is specifically enriched in central nervous system neurons, its nuclear envelope localization indicates that D-aminoacyl-tRNA editing may be vital for the survival of neurons under high concentration of D-amino acids.

Relevance of RNA structure for the activity of picornavirus IRES elements

The RNA of all members of the Picornaviridae family initiates translation internally, via an internal ribosome entry site (IRES) element present in their 5' untranslated region. IRES elements consist of cis-acting RNA structures that often operate in association with specific RNA-binding proteins to recruit the translational machinery. This specialized mechanism of translation initiation is shared with other viral RNAs, and represents an alternative to the general cap-dependent initiation mechanism. In this review we discuss recent evidences concerning the relationship between RNA structure and IRES function in the genome of picornaviruses. The biological implications of conserved RNA structural elements for the mechanism of internal translation initiation driven by representative members of enterovirus and rhinovirus (type I IRES) and cardiovirus and aphthovirus (type II IRES) will be discussed.