Was the initiation of translation in early eukaryotes IRES-driven?

The initiation of translation in eukaryotes generally involves the recognition of a 'cap' structure at the 5' end of the mRNA. However, for some viral and cellular mRNAs, a cap-independent mechanism occurs through an mRNA structure known as the internal ribosome entry site (IRES). Here, I postulate that the first eukaryotic mRNAs were translated in a cap-independent, IRES-driven manner that was then superseded in evolution by the cap-dependent mechanism, rather than vice versa. This hypothesis is supported by the following observations: (i) IRES-dependent, but not cap-dependent, translation can take place in the absence of not only a cap, but also many initiation factors; (ii) eukaryotic initiation factor 4E (eIF4E) and eIF4G, molecules absolutely required for cap-dependent translation, are among the most recently evolved translation factors; and (iii) functional similarities suggest the evolution of IRESs from spliceosomal introns. Thus, the contemporary cellular IRESs might be relics of the past.     

Is gene deletion in eukaryotes sequence-dependent? A study of nine deletion junctions and nineteen other deletion breakpoints in intron 7 of the human dystrophin gene

Although large deletions comprise 65% of the mutations that underlie most cases of Duchenne and Becker muscular dystrophies, the DNA sequence characteristics of the deletions and the molecular processes leading to their formation are largely unknown. Intron 7 of the human dystrophin gene is unusually large (110 kb) and a substantial number of deletions have been identified with endpoints within this intron. The distribution of 28 deletion endpoints was mapped to local sequence elements by PCR. The break points were distributed among unique sequence, LINE-1, Alu, MIR, MER and microsatellite sequences with frequencies expected from the frequency of those sequences in the intron. Thus, deletions in this intron are not associated primarily with any one of those sequences in the intron. Nine deletion junctions were amplified and sequenced. Eight were deletions between DNA sequences with minimal homology (0–4 bp) and are therefore unlikely to be products of homologous recombination. In the ninth case, a complex rearrangement was found to be consistent with unequal recombinational exchange between two Alu sequences coupled with a duplication. We have hypothesized that a paucity of matrix attachment regions in this very large intron expanded by the insertion of many mobile elements might provoke a chromatin structure that stimulates deletions (McNaughton et al., 1997, Genomics 40, 294–304). The data presented here are consistent with that idea and demonstrate that the deletion sequences are not usually produced by homologous DNA misalignments.     

What drives membrane fusion in eukaryotes?

The fusion of biological membranes is the terminal step of all vesicular trafficking reactions in eukaryotic cells. Therefore, this fusion is fundamental for the transfer of proteins and lipids between different compartments, for exocytosis and for the structural integrity of organelles. In the past decade, many parts of the molecular machinery involved in fusion have been uncovered. Although the mechanisms responsible for mutual recognition and binding of membranes inside eukaryotes are becoming reasonably well known, there is considerable uncertainty as to what causes the actual merging of the lipid bilayer. Two classes of mechanisms have been proposed. Proximity models postulate that very close apposition of membranes suffices to induce fusion. By contrast, pore models propose that continuous proteinaceous pores between apposed membranes could be the basis for fusion.     

A novel gene—samfR involved in early stage ofStreptomyces ansochromogenes differentiation

A 4.6 kb DNA fragment was cloned from the DNA library ofStreptomyces ansochromogenes using a partial DNA fragment located in the downstream of promoter-P_TH4 as probe. The experiments revealed that this DNA fragment consists ofsaw D gene and a 1.4 kbPvu II fragment which can accelerate mycelium formation ofS. ansochromogenes. The nucleotide sequence of 1.4 kb DNA fragment was determined and analysed; the result indicated that the fragment contains one complete open reading frame (ORF) which encodes a protein with 213 amino acids, and this gene was designated assamfR. The deduced protein has 36% amino acid identities and 52% amino acid similarities in comparison with that encoded byhppR gene, which is involved in the regulation of catabolism for 3-(3-hydroxyphenyl) propionate (3HPP) inRhodococcus globerulus. The function ofsamfR gene was studied using strategy of gene disruption, and the resultingsamfR mutant failed to form aerial hyphae and spores, its development and differentiation stopped at the stage of substrate mycelium in contrast with wild type strain. The results showed that thesamfR gene is closely related toS. ansochromogenes differentiation.     

Mechanism of meiotic recombination in eukaryotes—A theory

It is proposed that in meiotic chromosomes single strand breaks of DNA originate either in the delayed regions of replicons or as a result of the excision activity of DNA polymerase during zygotene DNA synthesis. Rejoining of the break points belonging to non-sister chromatids takes place by switching over of the polymerase from one strand of DNA to another non-sister strand of the same polarity and gives rise to recombination intermediates (half-chromatid chiasmata). Strand migration in a recombination intermediate or copying of the same parental strand twice during zygotene as a consequence of a delay in copying the homologous strand would lead to gene conversion. Nicking of the cross strands (parental strands) in any recombination intermediate and subsequent repair leads to recombination for flanking markers. A possible way in which three-strand double crossovers occur and the process of recombination are discussed.     

Lateral gene transfer in eukaryotes: tip of the iceberg or of the ice cube?

Lateral gene transfer (LGT) is the transmission of genes, sometimes across species barriers, outwith the classic vertical inheritance from parent to offspring. LGT is recognized as an important phenomenon that has shaped the genomes and biology of prokaryotes. Whether LGT in eukaryotes is important and widespread remains controversial. A study in BMC Biology concludes that LGT in eukaryotes is neither continuous nor prevalent and suggests a rule of thumb for judging when apparent LGT may reflect contamination.See research article: http://bmcbiol.biomedcentral.com/articles/10.1186/s12915-016-0315-9.     

Do nonribosomal peptide synthetases occur in higher eukaryotes?

Is There An Answer? is intended to serve as a forum in which readers to IUBMB Life may pose questions of the type that intrigue biochemists but for which there may be no obvious answer or one may be available but not widely known or easily accessible. Readers are invited to e-mail ascenzi@uniroma3.it if they have questions to contribute or if they can provide answers to questions that are provided here from time to time. In the latter case, instructions will be sent to interested readers. Answers should be, whenever possible, evidence-based and provide relevant references. Paolo Ascenzi     

A novel gene——samfR involved in early stage of Streptomyces ansochromogenes differentiation

A 4.6 kb DNA fragment was cloned from the DNA library ofStreptomyces ansochromogenes using a partial DNA fragment located in the downstream of promoter-P_TH4 as probe. The experiments revealed that this DNA fragment consists ofsaw D gene and a 1.4 kbPvu II fragment which can accelerate mycelium formation ofS. ansochromogenes. The nucleotide sequence of 1.4 kb DNA fragment was determined and analysed; the result indicated that the fragment contains one complete open reading frame (ORF) which encodes a protein with 213 amino acids, and this gene was designated assamfR. The deduced protein has 36% amino acid identities and 52% amino acid similarities in comparison with that encoded byhppR gene, which is involved in the regulation of catabolism for 3-(3-hydroxyphenyl) propionate (3HPP) inRhodococcus globerulus. The function ofsamfR gene was studied using strategy of gene disruption, and the resultingsamfR mutant failed to form aerial hyphae and spores, its development and differentiation stopped at the stage of substrate mycelium in contrast with wild type strain. The results showed that thesamfR gene is closely related toS. ansochromogenes differentiation. Project supported by the National Natural Science Foundation of China (Grant No. 39830010).     

A novel gene——samfR involved in early stage of Streptomyces ansochromogenes differentiation

A 4.6 kb DNA fragment was cloned from the DNA library of Streptomyces ansochromogenes using a partial DNA fragment located in the downstream of promoter-P_(TH4) as probe. The experiments revealed that this DNA fragment consists of saw D gene and a 1.4 kb Pvu Ⅱ fragment which can accelerate mycelium formation of S. ansochromogerms. The nucleofide sequence of 1.4 kb DNA fragment was determined and analysed; the result indicated that the fragment contains one complete open reading frame (ORF) which encodes a protein with 213 amino acids, and this gene was desiguated as samfR. The deduced protein has 36% amino acid identities and 52% amino acid similarities in comparison with that encoded by hppR gene, which is involved in the regulation of catabolism for 3-(3-hydroxyphenyl) propionate (3HPP) in Rhodococcus globerulus. The function of samfR gene was studied using strategy of gene disruption, and the resulting samfR mutant failed to form aerial hyphae and spores, its development and differentiation stopped     

Seeing is believing? A beginners' guide to practical pitfalls in image acquisition

Imaging can be thought of as the most direct of experiments. You see something; you report what you see. If only things were truly this simple. Modern imaging technology has brought about a revolution in the kinds of questions we can approach, but this comes at the price of increasingly complex equipment. Moreover, in an attempt to market competing systems, the microscopes have often been inappropriately described as easy to use and suitable for near-beginners. Insufficient understanding of the experimental manipulations and equipment set-up leads to the introduction of errors during image acquisition. In this feature, I review some of the most common practical pitfalls faced by researchers during image acquisition, and how they can affect the interpretation of the experimental data.This article is targeted neither to the microscopy gurus who push forward the frontiers of imaging technology nor to my imaging specialist colleagues who may wince at the overly simplistic comments and lack of detail. Instead, this is for beginners who gulp with alarm when they hear the word "confocal pinhole" or sigh as they watch their cells fade and die in front of their very eyes time and time again at the microscope. Take heart, beginners, if microscopes were actually so simple then many people (including myself) would suddenly be out of a job!     

Cdc45: the missing RecJ ortholog in eukaryotes?

DNA replication is one of the most ancient of cellular processes and functional similarities among its molecular machinery are apparent across all cellular life. Cdc45 is one of the essential components of the eukaryotic replication fork and is required for the initiation and elongation of DNA replication, but its molecular function is currently unknown. In order to trace its evolutionary history and to identify functional domains, we embarked on a computational sequence analysis of the Cdc45 protein family. Our findings reveal eukaryotic Cdc45 and prokaryotic RecJ to possess a common ancestry and Cdc45 to contain a catalytic site within a predicted exonuclease domain. The likely orthology between Cdc45 and RecJ reveals new lines of enquiry into DNA replication mechanisms in eukaryotes.     

Genetic variation between Helicobacter pylori strains: gene acquisition or loss?

Previously identified strain-specific genes of Helicobacter pylori were analysed for GC content and preference in codon usage. The results indicate that in H. pylori strain specificity is mainly driven by gene uptake. Incoming strains of Helicobacter or other species can occasionally donate genes but the identification of the donor species is hampered by ongoing evolutionary processes and the lack of an adequate number, or indeed a total absence, of gene homologues.     

Evolutionary implications of intron–exon distribution and the properties and sequences of the RPL10A gene in eukaryotes

The RPL10A gene encodes the RPL10 protein, required for joining 40S and 60S subunits into a functional 80S ribosome. This highly conserved gene, ubiquitous across all eukaryotic super-groups, is characterized by a variable number of spliceosomal introns, present in most organisms. These properties facilitate the recognition of orthologs among distant taxa and thus comparative studies of sequences as well as the distribution and properties of introns in taxonomically distant groups of eukaryotes. The present study examined the multiple ways in which RPL10A conservation vs. sequence changes in the gene over the course of evolution, including in exons, introns, and the encoded proteins, can be exploited for evolutionary analysis at different taxonomic levels. At least 25 different positions harboring introns within the RPL10A gene were determined in different taxa, including animals, plants, fungi, and alveolates. Generally, intron positions were found to be well conserved even across different kingdoms. However, certain introns seemed to be restricted to specific groups of organisms. Analyses of several properties of introns, including insertion site, phase, and length, along with exon and intron GC content and exon–intron boundaries, suggested biases within different groups of organisms. The use of a standard primer pair to analyze a portion of the intron-containing RPL10A gene in 12 genera of green algae within Chlorophyta is presented as a case study for evolutionary analyses of introns at intermediate and low taxonomic levels. Our study shows that phylogenetic reconstructions at different depths can be achieved using RPL10A nucleotide sequences from both exons and introns as well as the amino acid sequences of the encoded protein.     

Nuclear actin: ancient clue to evolution in eukaryotes?

Until recently it was widely accepted that the dynamic cytoskeletal matrix is exclusive to the cytoplasm of eukaryotes, evolving before the emergence of the cell nucleus to enable phagocytosis, cell motility and the sophisticated functioning of the endomembrane system within the cytosol. The discovery of the existence of a prokaryotic cytoskeleton has changed this picture significantly. As a result, the idea has taken shape that the appearance of actin occurred in the very first cell; therefore, the emergence of microfilaments precedes that of the eukaryotic cytoskeleton. The discovery of nuclear actin opened new perspective on the field, suggesting that the nuclear activities of actin reflect the functions of primordial actin-like proteins. In this paper, we review the recent literature to explore the evolutionary origin of nuclear actin. We conclude that both ancient and eukaryotic features of the actin world can be detected in the nucleus today, which supports the idea that the cytoskeleton attained significant eukaryotic innovations before the tandem evolution of the cytoskeleton and nucleus occurred.