Biosynthesis of the uridine-derived nucleoside antibiotic A-94964: identification and characterization of the biosynthetic gene cluster provide insight into the biosynthetic pathway.

The natural product A-94964 is a uridine-derived nucleoside antibiotic isolated from Streptomyces sp. SANK 60404. In this study, we propose a biosynthetic pathway for A-94964 using gene deletion experiments coupled with in silico analysis of the biosynthetic gene cluster. This study provides insights into the unique biosynthetic pathway for A-94964.

Epitranscriptomic Code and Its Alterations in Human Disease.

Innovations in epitranscriptomics have resulted in the identification of more than 160 RNA modifications to date. These developments, together with the recent discovery of writers, readers, and erasers of modifications occurring across a wide range of RNAs and tissue types, have led to a surge in integrative approaches for transcriptome-wide mapping of modifications and protein-RNA interaction profiles of epitranscriptome players. RNA modification maps and crosstalk between them have begun to elucidate the role of modifications as signaling switches, entertaining the notion of an epitranscriptomic code as a driver of the post-transcriptional fate of RNA. Emerging single-molecule sequencing technologies and development of antibodies specific to various RNA modifications could enable charting of transcript-specific epitranscriptomic marks across cell types and their alterations in disease.

Splicing mutations in human genetic disorders: examples, detection, and confirmation.

Precise pre-mRNA splicing, essential for appropriate protein translation, depends on the presence of consensus "cis" sequences that define exon-intron boundaries and regulatory sequences recognized by splicing machinery. Point mutations at these consensus sequences can cause improper exon and intron recognition and may result in the formation of an aberrant transcript of the mutated gene. The splicing mutation may occur in both introns and exons and disrupt existing splice sites or splicing regulatory sequences (intronic and exonic splicing silencers and enhancers), create new ones, or activate the cryptic ones. Usually such mutations result in errors during the splicing process and may lead to improper intron removal and thus cause alterations of the open reading frame. Recent research has underlined the abundance and importance of splicing mutations in the etiology of inherited diseases. The application of modern techniques allowed to identify synonymous and nonsynonymous variants as well as deep intronic mutations that affected pre-mRNA splicing. The bioinformatic algorithms can be applied as a tool to assess the possible effect of the identified changes. However, it should be underlined that the results of such tests are only predictive, and the exact effect of the specific mutation should be verified in functional studies. This article summarizes the current knowledge about the "splicing mutations" and methods that help to identify such changes in clinical diagnosis.

Aspartate Rescues S-phase Arrest Caused by Suppression of Glutamine Utilization in KRas-driven Cancer Cells.

During G1-phase of the cell cycle, normal cells respond first to growth factors that indicate that it is appropriate to divide and then later in G1 to the presence of nutrients that indicate sufficient raw material to generate two daughter cells. Dividing cells rely on the "conditionally essential" amino acid glutamine (Q) as an anaplerotic carbon source for TCA cycle intermediates and as a nitrogen source for nucleotide biosynthesis. We previously reported that while non-transformed cells arrest in the latter portion of G1 upon Q deprivation, mutant KRas-driven cancer cells bypass the G1 checkpoint, and instead, arrest in S-phase. In this study, we report that the arrest of KRas-driven cancer cells in S-phase upon Q deprivation is due to the lack of deoxynucleotides needed for DNA synthesis. The lack of deoxynucleotides causes replicative stress leading to activation of the ataxia telangiectasia and Rad3-related protein (ATR)-mediated DNA damage pathway, which arrests cells in S-phase. The key metabolite generated from Q utilization was aspartate, which is generated from a transaminase reaction whereby Q-derived glutamate is converted to α-ketoglutarate with the concomitant conversion of oxaloacetate to aspartate. Aspartate is a critical metabolite for both purine and pyrimidine nucleotide biosynthesis. This study identifies the molecular basis for the S-phase arrest caused by Q deprivation in KRas-driven cancer cells that arrest in S-phase in response to Q deprivation. Given that arresting cells in S-phase sensitizes cells to apoptotic insult, this study suggests novel therapeutic approaches to KRas-driven cancers.

Consecutive incorporation of functionalized nucleotides with amphiphilic side chains by novel KOD polymerase mutant.

Recently, 7-substituted 7-deazapurine nucleoside triphosphates and 5-substituted pyrimidine nucleoside triphosphates (dN(am)TPs) were synthesized to extend enzymatically using commercially available polymerase. However, extension was limited when we attempted to incorporate the substrates consecutively. To address this, we have produced a mutant polymerase that can efficiently accept the modified nucleotide with amphiphilic groups as substrates. Here we show that the KOD polymerase mutant, KOD exo(-)/A485L, had the ability to incorporate dN(am)TP continuously over 50nt, indicating that the mutant is sufficient for generating functional nucleic acid molecules.

One-by-one single-molecule detection of mutated nucleobases by monitoring tunneling current using a DNA tip.

A DNA molecule was utilized as a probe tip to achieve single-molecule genetic diagnoses. Hybridization of the probe and target DNAs resulted in electron tunneling along the emergent double-stranded DNA. Simple stationary monitoring of the tunneling current leads to single-molecule DNA detection and discovery of base mismatches and methylation.

Lie Markov models with purine/pyrimidine symmetry.

Continuous-time Markov chains are a standard tool in phylogenetic inference. If homogeneity is assumed, the chain is formulated by specifying time-independent rates of substitutions between states in the chain. In applications, there are usually extra constraints on the rates, depending on the situation. If a model is formulated in this way, it is possible to generalise it and allow for an inhomogeneous process, with time-dependent rates satisfying the same constraints. It is then useful to require that, under some time restrictions, there exists a homogeneous average of this inhomogeneous process within the same model. This leads to the definition of "Lie Markov models" which, as we will show, are precisely the class of models where such an average exists. These models form Lie algebras and hence concepts from Lie group theory are central to their derivation. In this paper, we concentrate on applications to phylogenetics and nucleotide evolution, and derive the complete hierarchy of Lie Markov models that respect the grouping of nucleotides into purines and pyrimidines-that is, models with purine/pyrimidine symmetry. We also discuss how to handle the subtleties of applying Lie group methods, most naturally defined over the complex field, to the stochastic case of a Markov process, where parameter values are restricted to be real and positive. In particular, we explore the geometric embedding of the cone of stochastic rate matrices within the ambient space of the associated complex Lie algebra.

Gene expression profile of early in vitro biofilms of Streptococcus pneumoniae.

In this study, the gene expression profile of early in vitro Streptococcus pneumoniae biofilm with respect to planktonic cells in cDNA microarray analysis is reported. Microarray analysis with respect to planktonic cells was performed on total RNA extracted from biofilms grown in 24-well microtiter plates. To validate the microarray results, real-time RT-PCR was performed on 13 differentially expressed genes and one constitutively expressed gene. The cDNA-microarray analyses identified 89 genes that were significantly differentially expressed in biofilm and planktonic cells. Genes involved in isoprenoid biosynthesis, cell wall biosynthesis, translation and purine and pyrimidine nucleotide metabolic pathways were exclusively expressed in the biofilms, whereas transcription regulator genes were exclusively expressed in planktonic cells. The real-time RT-PCR results of 13 differentially regulated genes were completely in agreement with the microarray data. The exclusive up regulation in biofilms of genes involved in the mevalonate pathway, cell wall biosynthesis, translation and purine and pyrimidine nucleotide metabolic pathways suggests that expression of these genes may be required for initial biofilm formation, and growth and survival of bacteria in biofilms. The up regulation of related genes suggests that cells in biofilms may be under stress conditions and possibly actively involved in the protein synthesis required to adapt to a new environment.

Genome-wide analysis of mutations in mutant lineages selected following fast-neutron irradiation mutagenesis of Arabidopsis thaliana.

Ionizing radiation has long been known to induce heritable mutagenic change in DNA sequence. However, the genome-wide effect of radiation is not well understood. Here we report the molecular properties and frequency of mutations in phenotypically selected mutant lines isolated following exposure of the genetic model flowering plant Arabidopsis thaliana to fast neutrons (FNs). Previous studies suggested that FNs predominantly induce deletions longer than a kilobase in A. thaliana. However, we found a higher frequency of single base substitution than deletion mutations. While the overall frequency and molecular spectrum of fast-neutron (FN)-induced single base substitutions differed substantially from those of "background" mutations arising spontaneously in laboratory-grown plants, G:C>A:T transitions were favored in both. We found that FN-induced G:C>A:T transitions were concentrated at pyrimidine dinucleotide sites, suggesting that FNs promote the formation of mutational covalent linkages between adjacent pyrimidine residues. In addition, we found that FNs induced more single base than large deletions, and that these single base deletions were possibly caused by replication slippage. Our observations provide an initial picture of the genome-wide molecular profile of mutations induced in A. thaliana by FN irradiation and are particularly informative of the nature and extent of genome-wide mutation in lines selected on the basis of mutant phenotypes from FN-mutagenized A. thaliana populations.

The polypyrimidine/polypurine motif in the mouse mu opioid receptor gene promoter is a supercoiling-regulatory element.

The mu opioid receptor (MOR) is the principle molecular target of opioid analgesics. The polypyrimidine/polypurine (PPy/u) motif enhances the activity of the MOR gene promoter by adopting a non-B DNA conformation. Here, we report that the PPy/u motif regulates the processivity of torsional stress, which is important for endogenous MOR gene expression. Analysis by topoisomerase assays, S1 nuclease digests, and atomic force microscopy showed that, unlike homologous PPy/u motifs, the position- and orientation-induced structural strains to the mouse PPy/u element affect its ability to perturb the relaxation activity of topoisomerase, resulting in polypurine strand-nicked and catenated DNA conformations. Raman spectrum microscopy confirmed that mouse PPy/u containing-plasmid DNA molecules under the different structural strains have a different configuration of ring bases as well as altered Hoogsteen hydrogen bonds. The mouse MOR PPy/u motif drives reporter gene expression fortyfold more effectively in the sense orientation than in the antisense orientation. Furthermore, mouse neuronal cells activate MOR gene expression in response to the perturbations of topology by topoisomerase inhibitors, whereas human cells do not. These results suggest that, interestingly among homologous PPy/u motifs, the mouse MOR PPy/u motif dynamically responds to torsional stress and consequently regulates MOR gene expression in vivo.

Interaction of the diguanylate cyclase YdeH of Escherichia coli with 2',(3')-substituted purine and pyrimidine nucleotides.

Diguanylate cyclases (DGCs) synthesize the bacterial second messenger cyclic 3',5'-diguanosine monophosphate (c-di-GMP), which is degraded by specific phosphodiesterases. c-di-GMP levels control the transition of bacteria from a motile to a biofilm-forming lifestyle. These bacterial communities are highly resistant to antibiotic treatment and represent the predominant lifestyle in most chronic infections. Hence, DGCs serve as starting point for the development of novel therapeutics interfering with the second messenger-signaling network in bacteria. In previous studies, we showed that 2'(3')-O-(N-methylanthraniloyl) (MANT)- and 2',3'-O-(2,4,6-trinitrophenyl) (TNP)-substituted nucleotides are potent adenylyl and guanylyl cyclase inhibitors. The catalytic domain of DGCs is homologous to the mammalian adenylyl cyclase catalytic domain. Therefore, we investigated the interaction of various MANT purine and pyrimidine nucleotides with the model DGC YdeH from Escherichia coli. We observed strong fluorescence resonance energy transfer between tryptophan and tyrosine residues of YdeH and the MANT group of MANT-NTPs (MANT-ATP, -CTP, -GTP, -ITP, -UTP, and -XTP) and an enhanced direct MANT fluorescence upon interaction with YdeH. We assessed the affinity of MANT-NTPs to YdeH by performing competition assays with NTPs. We conducted an amino acid alignment of YdeH with the earlier crystallized Caulobacter crescentus DGC PleD and found high similarities in the nucleotide-binding site of PleD. In vitro mass-spectrometric activity assays with YdeH resulted in the identification of new MANT/TNP nucleotide-based inhibitors of DGC activity. Together, the analysis of interactions between MANT/TNP nucleotides and YdeH provides a new basis for the identification and development of DGC inhibitors and allows insights into nucleotide-protein interactions.

Purification and characterization of Caenorhabditis elegans NTH, a homolog of human endonuclease III: essential role of N-terminal region.

Oxidatively damaged bases in DNA cause many types of deleterious effects. The main enzyme that removes such lesions is DNA glycosylase, and accordingly, DNA glycosylase plays an important role in genome stability. Recently, a relationship between DNA glycosylases and aging has been suggested, but it remains controversial. Here, we investigated DNA glycosylases of C. elegans, which is a useful model organism for studying aging. We firstly identified a C. elegans homolog of endonuclease III (NTH), which is a well-conserved DNA glycosylase for oxidatively damaged pyrimidine bases, based on the activity and homology. Blast searching of the Wormbase database retrieved a sequence R10E4.5, highly homologous to the human NTH1. However, the R10E4.5-encoded protein did not have NTH activity, and this was considered to be due to lack of the N-terminal region crucial for the activity. Therefore, we purified the protein encoded by the sequence containing both R10E4.5 and the 117-bp region upstream from it, and found that the protein had the NTH activity. The endogenous CeNTH in the extract of C. elegans showed the same DNA glycosylase activity. Therefore, we concluded that the genuine C. elegans NTH gene is not the R10E4.5 but the sequence containing both R10E4.5 and the 117-bp upstream region. NTH-deficient C. elegans showed no difference from the wild-type in lifespan and was not more sensitive to two oxidizing agents, H2O2 and methyl viologen. This suggests that C. elegans has an alternative DNA glycosylase that repairs pyrimidine bases damaged by these agents. Indeed, DNA glycosylase activity that cleaved thymine glycol containing oligonucleotides was detected in the extract of the NTH-deficient C. elegans.

Strong short-range correlations and dichotomic codon classes in coding DNA sequences.

The study of correlation structures in DNA sequences is of great interest because it allows us to obtain structural and functional information about underlying genetic mechanisms. In this paper we present a study of the correlation structure of protein coding sequences of DNA based on a recently developed mathematical representation of the genetic code. A fundamental consequence of such representation is that codons can be assigned a parity class (odd-even). Such parity can be obtained by means of a nonlinear algorithm acting on the chemical character of the codon bases. In the same setting the Rumer's class can be naturally described and a new dichotomic class, the hidden class, can be defined. Moreover, we show that the set of DNA's base transformations associated to the three dichotomic classes can be put in a compact group-theoretic framework. We use the dichotomic classes as a coding scheme for DNA sequences and study the mutual dependence between such classes. The same analysis is carried out also on the chemical dichotomies of DNA bases. In both cases, the statistical analysis is performed by using an entropy-based dependence metric possessing many desirable properties. We obtain meaningful tests for mutual dependence by using suitable resampling techniques. We find strong short-range correlations between certain combinations of dichotomic codon classes. These results support our previous hypothesis that codon classes might play an active role in the organization of genetic information.

Effect of the GC content of DNA on the distribution of UVB-induced bipyrimidine photoproducts.

Solar UV radiation is a major mutagen that damages DNA through the formation of dimeric photoproducts between adjacent thymine and cytosine bases. A major effect of the GC content of the genome is thus anticipated, in particular in prokaryotes where this parameter significantly varies among species. We quantified the formation of UV-induced photolesions within both isolated and cellular DNA of bacteria of different GC content. First, we could unambiguously show the favored formation of cytosine-containing photoproducts with increasing GC content (from 28 to 72%) in isolated DNA. Thymine-thymine cyclobutane dimer was a minor lesion at high GC content. This trend was confirmed by an accurate and quantitative analysis of the photochemical data based on the exact dinucleotide frequencies of the studied genomes. The observation of the effect of the genome composition on the distribution of photoproducts was then confirmed in living cells, using two marine bacteria exhibiting different GC content. Because cytosine-containing photoproducts are highly mutagenic, it may be predicted that species with genomes exhibiting a high GC content are more susceptible to UV-induced mutagenesis.

Solvable models of neighbor-dependent substitution processes.

We prove that a wide class of Markov models of neighbor-dependent substitution processes on the integer line is solvable. This class contains some models of nucleotidic substitutions recently introduced and studied empirically by molecular biologists. We show that the polynucleotidic frequencies at equilibrium solve some finite-size linear systems. This provides, for the first time up to our knowledge, explicit and algebraic formulas for the stationary frequencies of non-degenerate neighbor-dependent models of DNA substitutions. Furthermore, we show that the dynamics of these stochastic processes and their distribution at equilibrium exhibit some stringent, rather unexpected, independence properties. For example, nucleotidic sites at distance at least three evolve independently, and all the sites, when encoded as purines and pyrimidines, evolve independently.

Megaprimer-based methodology for deletion of a large fragment within a repetitive polypyrimidine-rich DNA.

Site-directed mutagenesis is often a prerequisite for elucidation of the functional significance of cis- and trans-factors involved in gene regulation. The aim of this study was to delete the primary binding site for heterogeneous nuclear ribonucleoprotein I (hnRNPI) within the inducible nitric oxide synthase (iNOS) 3' untranslated region mRNA. The binding site consists of a 53-nucleotide CU-rich region within a long stretch of polypyrimidines. As a result of primer pair annealing, the repetitive sequence limited the use of several deletion methods based on polymerase chain reaction. Therefore, a megaprimer approach was chosen. The megaprimer was produced by a forward primer outside the polypyrimidine-rich region, and a mutagenic reverse primer annealing to flanking regions of the desired deletion, thereby looping out the target sequence. Subsequently, this megaprimer was used to create the final deletion recombinant. The deletion was verified by sequencing and by ultraviolet cross-linking mouse liver protein extracts with radiolabeled mutant and wild-type RNAs. In conclusion, the megaprimer method offers a solution for generating large internal deletions in repetitive sequences, which facilitates investigations on large repetitive DNA or RNA regions interacting with trans-factors.

Dependence of nucleotide physical properties on their placement in codons and determinative degree.

Various physical properties such as dipole moment, heat of formation and energy of the most stable formation of nucleotides and bases were calculated by PM3 (modified neglect of diatomic overlap, parametric method number 3) and AM1 (austin model 1) methods. As distinct from previous calculations, for nucleotides the interaction with neighbours is taken into account up to gradient of convergence equaling 1. The dependencies of these variables from the place in the codon and the determinative degree were obtained. The difference of these variables for codons and anticodons is shown.

Effect of 3'UTR length on the translational regulation of 5'-terminal oligopyrimidine mRNAs.

In Vertebrates, all genes coding for ribosomal proteins, as well as those for other proteins implicated in the production and function of translation machinery, are regulated by mitogenic and nutritional stimuli, at the translational level. A cis-regulatory element necessary for this regulation is the typical 5'UTR, common to all ribosomal protein mRNAs, which always starts at the 5' end with several pyrimidines. Having noticed that the 3'UTR of all ribosomal protein mRNAs is much shorter than most cellular mRNAs, we have now studied the possible implication of this 3'UTR feature in the translational regulation. For this purpose, we constructed a number of chimeric genes whose transcribed mRNAs contain: (1) the 5'UTR of ribosomal protein S6 mRNA or, as a control, of beta-actin mRNA; (2) the EGFP reporter coding sequence from the starting AUG to the stop codon; (3) different 3'UTRs of various lengths. These constructs have been stably transfected in human HEK293 cells, and the translation regulation of the expressed chimeric mRNAs has been analyzed for translation efficiency, in growing and in serum starved cells, by the polysome association assay. The results obtained indicate that, while the typical growth-associated translational regulation is bestowed on an mRNA by the pyrimidine sequence containing 5'UTR, the stringency of regulation depends on the short size of the 3'UTR.

Regulation of pyrimidine nucleotide formation in Pseudomonas taetrolens ATCC 4683.

The regulation of the de novo pyrimidine biosynthetic enzymes in the food spoilage agent Pseudomonas taetrolens ATCC 4683 was investigated. The de novo pyrimidine biosynthetic enzyme activities were determined in P. taetrolens ATCC 4683 cells and in cells from an auxotroph deficient for orotidine 5'-monophosphate decarboxylase activity. Pyrimidine supplementation to the culture medium affected the biosynthetic enzyme activities in ATCC 4683 cells. Transcriptional regulation of the biosynthetic pathway by pyrimidines was indicated after the auxotroph was subjected to pyrimidine limitation. At the level of enzyme activity, aspartate transcarbamoylase activity was strongly inhibited by pyrophosphate, ADP, ATP, UDP, UTP and GTP. Transcriptional regulation of pyrimidine synthesis in P. taetrolens was not as highly controlled as in the taxonomically-related species Pseudomonas fragi although both species contained transcarbamoylase activities subject to significant nucleotide inhibition.