In silico identification and in vitro expression analysis of breast cancer-related m6A-SNPs.

Research on m6A-associated SNPs (m6A-SNPs) has emerged recently due to their possible critical roles in many key biological processes. In this sense, several investigations have identified m6A-SNPs in different diseases. In order to gain a more complete understanding of the role that m6A-SNPs can play in breast cancer, we performed an in silico analysis to identify the m6A-SNPs associated with breast cancer and to evaluate their possible effects. For this purpose, we downloaded SNPs related to breast cancer and a list of m6A-SNPs from public databases in order to identify which ones appear in both. Subsequently, we assessed the identified m6A-SNPs in silico by expression quantitative trait loci (eQTL) analysis and differential gene expression analysis. We genotyped the m6A-SNPs found in the in silico analysis in 35 patients with breast cancer, and we carried out a gene expression analysis experimentally on those that showed differences. Our results identified 981 m6A-SNPs related to breast cancer. Four m6A-SNPs showed an eQTL effect and only three were in genes that presented an altered gene expression. When the three m6A-SNPs were evaluated in the tissue sample of our breast cancer patients, only the m6A-SNP rs76563149 located in ZNF354A gene presented differences in allele frequencies and a low gene expression in breast cancer tissues, especially in luminal B HER2+ subtype. Future investigations of these m6A-SNPs should expand the study in different ethnic groups and increase the sample sizes to test their association with breast cancer and elucidate their molecular function.

Lipid-Assisted Polymerization of Nucleotides.

In addition to being one of the proponents of the "Lipid World hypothesis", David Deamer, together with other colleagues, pioneered studies involving formation of RNA-like oligomers from their 'non-activated', prebiotically plausible monomeric moieties. In particular, the pioneering work in this regard was a publication from 2008 in Origins of Life and Evolution of Biospheres, The Journal of the International Astrobiology Society, wherein we described the formation of RNA-like oligomers from nucleoside 5'-monophosphates. In that study, we had simulated a terrestrial geothermal environment, a niche that is thought to have facilitated the prebiotic non-enzymatic synthesis of polynucleotides. We showed that a mixture of lipids and non-activated mononucleotides resulted in the formation of relatively long strands of RNA-like polymers when subjected to repeated cycles of dehydration and rehydration (DH-RH). Since 2008, terrestrial geothermal niches and DH-RH conditions have been explored in the context of several other prebiotic processes. In this article, we review the work that we and other researchers have carried out since then in this line of research, including the development of new apparatus to carry out the simulation of prebiotic terrestrial geothermal environments.

Miniaturized technology for protein and nucleic acid point-of-care testing.

The field of point-of-care (POC) testing technology is developing quickly and producing instruments that are increasingly reliable, while their size is being gradually reduced. Proteins are a common target for POC analyses and the detection of protein markers typically involves immunoassays aimed at detecting different groups of proteins such as tumor markers, inflammation proteins, and cardiac markers; but other techniques can also be used to analyze plasma proteins. In the case of nucleic acids, hybridization and amplification strategies can be used to record electromagnetic or electric signals. These techniques allow for the identification of specific viral or bacterial infections as well as specific cancers. In this review, we consider some of the latest advances in the analysis of specific nucleic acid and protein biomarkers, taking into account their trend toward miniaturization and paying special attention to the technology that can be implemented in future applications, such as lab-on-a-chip instruments.

Non-enzymatic transfer of sequence information under plausible prebiotic conditions.

We simulated in our laboratory a prebiotic environment where dry and wet periods were cycled. Under anhydrous conditions, lipid molecules present in the medium could form fluid lamellar matrices and work as organizing agents for the condensation of nucleic acid monomers into polymers. We exposed a mixture of 2'-deoxyribonucleoside 5'-monophosphates and a ssDNA oligomer template to this dry environment at 90 °C under a continuous gentle stream of CO(2) and we followed it with rehydration periods. After five dry/wet cycles we were able to detect the presence of a product that was complementary to the template. The reaction had a 0.5% yield with respect to the template, as measured by staining with the Pico Green(®) fluorescent probe. Absent initial template, the product of the reaction remained below the detection limit. In order to characterize the fidelity of replication, the synthesized strand was ligated to adapters, amplified by PCR, and sequenced. The alignment of the sequenced DNA to the expected complementary sequence revealed that the misincorporation rate was 9.9%. We present these results as a proof of concept for the possibility of having non-enzymatic transfer of sequence information in a prebiotically plausible environment.

Processive replication of single DNA molecules in a nanopore catalyzed by phi29 DNA polymerase.

Coupling nucleic acid processing enzymes to nanoscale pores allows controlled movement of individual DNA or RNA strands that is reported as an ionic current/time series. Hundreds of individual enzyme complexes can be examined in single-file order at high bandwidth and spatial resolution. The bacteriophage phi29 DNA polymerase (phi29 DNAP) is an attractive candidate for this technology, due to its remarkable processivity and high affinity for DNA substrates. Here we show that phi29 DNAP-DNA complexes are stable when captured in an electric field across the α-hemolysin nanopore. DNA substrates were activated for replication at the nanopore orifice by exploiting the 3'-5' exonuclease activity of wild-type phi29 DNAP to excise a 3'-H terminal residue, yielding a primer strand 3'-OH. In the presence of deoxynucleoside triphosphates, DNA synthesis was initiated, allowing real-time detection of numerous sequential nucleotide additions that was limited only by DNA template length. Translocation of phi29 DNAP along DNA substrates was observed in real time at Ångstrom-scale precision as the template strand was drawn through the nanopore lumen during replication.

Replication of individual DNA molecules under electronic control using a protein nanopore.

Nanopores can be used to analyse DNA by monitoring ion currents as individual strands are captured and driven through the pore in single file by an applied voltage. Here, we show that serial replication of individual DNA templates can be achieved by DNA polymerases held at the α-haemolysin nanopore orifice. Replication is blocked in the bulk phase, and is initiated only after the DNA is captured by the nanopore. We used this method, in concert with active voltage control, to observe DNA replication catalysed by bacteriophage T7 DNA polymerase (T7DNAP) and by the Klenow fragment of DNA polymerase I (KF). T7DNAP advanced on a DNA template against an 80-mV load applied across the nanopore, and single nucleotide additions were measured on the millisecond timescale for hundreds of individual DNA molecules in series. Replication by KF was not observed when this enzyme was held on top of the nanopore orifice at an applied potential of 80 mV. Sequential nucleotide additions by KF were observed upon applying controlled voltage reversals.

Mapping the position of DNA polymerase-bound DNA templates in a nanopore at 5 A resolution.

DNA polymerases are molecular motors that catalyze template-dependent DNA replication, advancing along template DNA by one nucleotide with each catalytic cycle. Nanopore-based measurements have emerged as a single molecule technique for the study of these enzymes. Using the alpha-hemolysin nanopore, we determined the position of DNA templates bearing inserts of abasic (1',2'-dideoxy) residues, bound to the Klenow fragment of Escherichia coli DNA polymerase I (KF) or to bacteriophage T7 DNA polymerase. Hundreds of individual polymerase complexes were analyzed at 5 A precision within minutes. We generated a map of current amplitudes for DNA-KF-deoxynucleoside triphosphate (dNTP) ternary complexes, using a series of templates bearing blocks of three abasic residues that were displaced by approximately 5 A in the nanopore lumen. Plotted as a function of the distance of the abasic insert from n = 0 in the active site of the enzyme held atop the pore, this map has a single peak. The map is similar when the primer length, the DNA sequences flanking the abasic insert, and the DNA sequences in the vicinity of the KF active site are varied. Primer extension catalyzed by KF using a three abasic template in the presence of a mixture of dNTPs and 2',3'-dideoxynucleoside triphosphates resulted in a ladder of ternary complexes with discrete amplitudes that closely corresponded to this map. An ionic current map measured in the presence of 0.15 M KCl mirrored the map obtained with 0.3 M KCl, permitting experiments with a broader range of mesophilic DNA and RNA processing enzymes. We used the abasic templates to show that capture of complexes with the KF homologue, T7 DNA polymerase, yields an amplitude map nearly indistinguishable from the KF map.

Stoichiometric analysis of self-maintaining metabolisms.

This paper presents an extension of stoichiometric analysis in systems where the catalytic compounds (enzymes) are also intermediates of the metabolic network (dual property), so they are produced and degraded by the reaction network itself. To take this property into account, we introduce the definition of enzyme-maintaining mode, a set of reactions that produces its own catalyst and can operate at stationary state. Moreover, an enzyme-maintaining mode is defined as elementary with respect to a given reaction if the removal of any of the remaining reactions causes the cessation of any steady state flux through this reference reaction. These concepts are applied to determine the network structure of a simple self-maintaining system.

Lipid-assisted synthesis of RNA-like polymers from mononucleotides.

A fundamental problem in research on the origin of life is the process by which polymers capable of catalysis and replication were produced on the early Earth. Here we show that RNA-like polymers can be synthesized non-enzymatically from mononucleotides in lipid environments. The RNA-like polymers were initially identified by nanopore analysis, a technique with single molecule sensitivity. To our knowledge, this is the first such application of a nanopore instrument to detect RNA synthesis under simulated prebiotic conditions. The synthesis of the RNA-like polymers was confirmed by standard methods of enzymatic end labeling followed by gel electrophoresis. Chemical activation of the mononucleotides is not required. Instead, synthesis of phosphodiester bonds is driven by the chemical potential of fluctuating anhydrous and hydrated conditions, with heat providing activation energy during dehydration. In the final hydration step, the RNA-like polymer is encapsulated within lipid vesicles. This process provides a laboratory model of an early stage of evolution toward an RNA World.

Energetically plausible model of a self-maintaining protocellular system.

Most of the models for cellular origin stress one of these two approaches: "replication-first" or "metabolism-first." The model presented here focuses on the latter, consisting of the combination of kinetic and energetic descriptions of protocellular metabolism. In this model, the membrane plays a very crucial role in the maintenance of the cell and the osmotic stability. The model contains the following elements: structural membrane elements (Lm), transducers (T), molecules (E) that combine enzyme-like activity with the transport of elements through the membrane, energy-rich molecules (A), precursors of each type of molecule (l, t, e, and a, respectively), and an impermeable substance (x). Different kinetic parameters lead to a wide region of stable steady states, as studied through numerical analysis. The system presents stability under different external conditions. Two energy source regimes have been studied: periodic and nonperiodic. The kinetic restrictions that lead to osmotic stability are also addressed in this paper.