Variation in synonymous nucleotide composition among genomes of sarbecoviruses and consequences for the origin of COVID-19

The subgenus Sarbecovirus includes two human viruses, SARS-CoV and SARS-CoV-2, respectively responsible for the SARS epidemic and COVID-19 pandemic, as well as many bat viruses and two pangolin viruses.Here, the synonymous nucleotide composition (SNC) of Sarbecovirus genomes was analysed by examining third codon-positions, dinucleotides, and degenerate codons. The results show evidence for the eigth following groups: (i) SARS-CoV related coronaviruses (SCoVrC including many bat viruses from China), (ii) SARS-CoV-2 related coronaviruses (SCoV2rC; including five bat viruses from Cambodia, Thailand and Yunnan), (iii) pangolin viruses, (iv) three bat viruses showing evidence of recombination between SCoVrC and SCoV2rC genomes, (v) two highly divergent bat viruses from Yunnan, (vi) the bat virus from Japan, (vii) the bat virus from Bulgaria, and (viii) the bat virus from Kenya. All these groups can be diagnosed by specific nucleotide compositional features except the one concerned by recombination between SCoVrC and SCoV2rC. In particular, SCoV2rC genomes are characterised by the lowest percentages of cyosine and highest percentages of uracil at third codon-positions, whereas the genomes of pangolin viruses exhibit the highest percentages of adenine at third codon-positions. I suggest that latitudinal and taxonomic differences in the imbalanced nucleotide pools available in host cells during viral replication can explain the seven groups of SNC here detected among Sarbecovirus genomes. A related effect due to hibernating bats is also considered. I conclude that the two independent host switches from Rhinolophus bats to pangolins resulted in convergent mutational constraints and that SARS-CoV-2 emerged directly from a horseshoe bat virus.

Structural basis for proficient oxidized ribonucleotide insertion in double strand break repair

Reactive oxygen species (ROS) oxidize cellular nucleotide pools and cause double strand breaks (DSBs). Non-homologous end-joining (NHEJ) attaches broken chromosomal ends together in mammalian cells. Ribonucleotide insertion by DNA polymerase (pol) μ prepares breaks for end-joining and this is required for successful NHEJ in vivo. We previously showed that pol μ lacks discrimination against oxidized dGTP (8-oxo-dGTP), that can lead to mutagenesis, cancer, aging and human disease. Here we reveal the structural basis for proficient oxidized ribonucleotide (8-oxo-rGTP) incorporation during DSB repair by pol μ. Time-lapse crystallography snapshots of structural intermediates during nucleotide insertion along with computational simulations reveal substrate, metal and side chain dynamics, that allow oxidized ribonucleotides to escape polymerase discrimination checkpoints. Abundant nucleotide pools, combined with inefficient sanitization and repair, implicate pol μ mediated oxidized ribonucleotide insertion as an emerging source of widespread persistent mutagenesis and genomic instability.

Isonicotinamide extends yeast chronological lifespan through a mechanism that diminishes nucleotides

Chronological lifespan (CLS) of budding yeast, Saccharomyces cerevisiae, is a commonly utilized model for cellular aging of non-dividing cells such as neurons. CLS is strongly extended by isonicotinamide (INAM), a non-metabolized isomer of the NAD+ precursor nicotinamide (NAM), but the underlying mechanisms of lifespan extension remain uncharacterized. To identify potential biochemical INAM targets, we performed a chemical genetic screen with the yeast gene knockout (YKO) strain collection for INAM-hypersensitive mutants. Significantly enriched Gene Ontology terms that emerged included SWR1 and other transcription elongation factors, as well as metabolic pathways converging on one-carbon metabolism and contributing to nucleotide biosynthesis, together suggesting that INAM perturbs nucleotide pools. In line with this model, INAM effects on cell growth were synergistic with mycophenolic acid (MPA), which extends lifespan by reducing guanine nucleotide pools. Direct measurements of nucleotides and precursors by mass spectrometry indicated that INAM reduced nucleotides, including cAMP, at 24- and 96-hour time points post-inoculation. Taken together, we conclude that INAM extends CLS by perturbing nucleotide metabolism, which may be a common functional feature of multiple anti-aging interventions.

Profiling Ribonucleotide and Deoxyribonucleotide Pools Perturbed by Remdesivir in Human Bronchial Epithelial Cells

Remdesivir (RDV) has generated much anticipation for its moderate effect in treating severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) infection. However, the unsatisfactory survival rates of hospitalized patients limit its application to the treatment of coronavirus disease 2019 (COVID-19). Therefore, improvement of antiviral efficacy of RDV is urgently needed. As a typical nucleotide analog, the activation of RDV to bioactive triphosphate will affect the biosynthesis of endogenous ribonucleotides (RNs) and deoxyribonucleotides (dRNs), which are essential to RNA and DNA replication in host cells. The imbalance of RN pools will inhibit virus replication as well. In order to investigate the effects of RDV on cellular nucleotide pools and on RNA transcription and DNA replication, cellular RNs and dRNs concentrations were measured by the liquid chromatography-mass spectrometry method, and the synthesis of RNA and DNA was monitored using click chemistry. The results showed that the IC50 values for BEAS-2B cells at exposure durations of 48 and 72 h were 25.3 ± 2.6 and 9.6 ± 0.7 μM, respectively. Ten (10) μM RDV caused BEAS-2B arrest at S-phase and significant suppression of RNA and DNA synthesis after treatment for 24 h. In addition, a general increase in the abundance of nucleotides and an increase of specific nucleotides more than 2 folds were observed. However, the variation of pyrimidine ribonucleotides was relatively slight or even absent, resulting in an obvious imbalance between purine and pyrimidine ribonucleotides. Interestingly, the very marked disequilibrium between cytidine triphosphate (CTP) and cytidine monophosphate might result from the inhibition of CTP synthase. Due to nucleotides which are also precursors for the synthesis of viral nucleic acids, the perturbation of nucleotide pools would block viral RNA replication. Considering the metabolic vulnerability of endogenous nucleotides, exacerbating the imbalance of nucleotide pools imparts great promise to enhance the efficacy of RDV, which possibly has special implications for treatment of COVID-19.

Development of MTH1-Binding Nucleotide Analogs Based on 7,8-Dihalogenated 7-Deaza-dG Derivatives

MTH1 is an enzyme that hydrolyzes 8-oxo-dGTP, which is an oxidatively damaged nucleobase, into 8-oxo-dGMP in nucleotide pools to prevent its mis-incorporation into genomic DNA. Selective and potent MTH1-binding molecules have potential as biological tools and drug candidates. We recently developed 8-halogenated 7-deaza-dGTP as an 8-oxo-dGTP mimic and found that it was not hydrolyzed, but inhibited enzyme activity. To further increase MTH1 binding, we herein designed and synthesized 7,8-dihalogenated 7-deaza-dG derivatives. We successfully synthesized multiple derivatives, including substituted nucleosides and nucleotides, using 7-deaza-dG as a starting material. Evaluations of the inhibition of MTH1 activity revealed the strong inhibitory effects on enzyme activity of the 7,8-dihalogenated 7-deaza-dG derivatives, particularly 7,8-dibromo 7-daza-dGTP. Based on the results obtained on kinetic parameters and from computational docking simulating studies, these nucleotide analogs interacted with the active site of MTH1 and competitively inhibited the substrate 8-oxodGTP. Therefore, novel properties of repair enzymes in cells may be elucidated using new compounds.

CBMT-27. ABERRANT AMINO ACID METABOLISM EXPOSE NOVEL FUNCTIONAL VULNERABILITIES IN GLIOBLASTOMA

Despite advances in molecularly characterizing glioblastoma, metabolic alterations driving its aggressive phenotype are only beginning to be recognized. Integrative cross-platform analyses coupling global metabolomic and gene expression profiling identified aberrant amino acid (AA) metabolism as a central node in glioblastoma. This metabolic phenotype was recapitulated in preclinical models and through a series of investigations designed to determine the biologic consequence of individual AA, we identified branched chain AA (BCAA) and glutamine as the only indispensable AA in glioblastoma, serving as the sole source of nucleotide pools and glutathione, respectively. Although molecularly and/or chemically perturbing these pathways resulted in cytotoxicity in glioblastoma, normal astrocytes demonstrated a similar response, suggesting therapeutic limitations in targeting these core metabolic pathways in cancer. As the glioblastoma microenvironment typically represents a nutrient-deprived state, we went on to determine the capacity of these cells to adapt to AA restricted conditions by only providing these cells with the above-identified indispensable AA. Intriguingly, glioblastoma cells had the unique ability to revert a state of metabolic dormancy. In addition to triggering a reversible proliferative arrest, this dormant phenotype displayed a near-complete shutdown of glycolysis that allowed these cells to adapt and maintain survival in glucose-deprived conditions and elicited profound resistance to ionizing radiation. Studies designed to systemically understand molecular underpinnings driving this unique metabolically dormant state uncovered a functional reliance upon mTOR/p21 signaling to maintain proliferative arrest in nutrient unfavorable conditions. Consistent with these findings, p21 expression was differentially expressed in the perinecrotic core of glioblastoma when compared to the peripheral edge in patient samples. Targeting this novel functional vulnerability through p21 inhibition, thereby, ‘forcing’ proliferation of these cells in nutrient unfavorable conditions, led to robust cytotoxicity specific to dormant cells and enhanced radiation response. Targeting functional vulnerabilities in otherwise therapeutically resistant cells represents a promising clinical strategy in glioblastoma.

Ensemble cryo-EM structures demonstrate human IMPDH2 filament assembly tunes allosteric regulation

SummaryInosine monophosphate dehydrogenase (IMPDH) mediates the first committed step in guanine nucleotide biosynthesis and plays important roles in cellular proliferation and the immune response. The enzyme is heavily regulated to maintain balance between guanine and adenine nucleotide pools. IMPDH reversibly polymerizes in cells and tissues in response to changes in metabolic demand, providing an additional layer of regulatory control associated with increased flux through the guanine synthesis pathway. Here, we report a series of human IMPDH2 cryo-EM structures in active and inactive conformations, and show that the filament resists inhibition by guanine nucleotides. The structures define the mechanism of filament assembly, and reveal how assembly interactions tune the response to guanine inhibition. Filament-dependent allosteric regulation of IMPDH2 makes the enzyme less sensitive to feedback inhibition, explaining why assembly occurs under physiological conditions, like stem cell proliferation and T-cell activation, that require expansion of guanine nucleotide pools.

Deoxyinosine and 7-Deaza-2-Deoxyguanosine as Carriers of Genetic Information in the DNA of Campylobacter Viruses

ABSTRACT Several reports have demonstrated that Campylobacter bacteriophage DNA is refractory to manipulation, suggesting that these phages encode modified DNA. The characterized Campylobacter jejuni phages fall into two phylogenetic groups within the Myoviridae: the genera Firehammervirus and Fletchervirus. Analysis of genomic nucleosides from several of these phages by high-pressure liquid chromatography-mass spectrometry confirmed that 100% of the 2′-deoxyguanosine (dG) residues are replaced by modified bases. Fletcherviruses replace dG with 2′-deoxyinosine, while the firehammerviruses replace dG with 2′-deoxy-7-amido-7-deazaguanosine (dADG), noncanonical nucleotides previously described, but a 100% base substitution has never been observed to have been made in a virus. We analyzed the genome sequences of all available phages representing both groups to elucidate the biosynthetic pathway of these noncanonical bases. Putative ADG biosynthetic genes are encoded by the Firehammervirus phages and functionally complement mutants in the Escherichia coli queuosine pathway, of which ADG is an intermediate. To investigate the mechanism of DNA modification, we isolated nucleotide pools and identified dITP after phage infection, suggesting that this modification is made before nucleotides are incorporated into the phage genome. However, we were unable to observe any form of dADG phosphate, implying a novel mechanism of ADG incorporation into an existing DNA strand. Our results imply that Fletchervirus and Firehammervirus phages have evolved distinct mechanisms to express dG-free DNA. IMPORTANCE Bacteriophages are in a constant evolutionary struggle to overcome their microbial hosts’ defenses and must adapt in unconventional ways to remain viable as infectious agents. One mode of adaptation is modifying the viral genome to contain noncanonical nucleotides. Genome modification in phages is becoming more commonly reported as analytical techniques improve, but guanosine modifications have been underreported. To date, two genomic guanosine modifications have been observed in phage genomes, and both are low in genomic abundance. The significance of our research is in the identification of two novel DNA modification systems in Campylobacter-infecting phages, which replace all guanosine bases in the genome in a genus-specific manner.