2--deoxyguanosine-5--phosphate and 2--deoxyadenosine-triphosphate

Solid-state nanopores promise a scalable platform for single-molecule DNA analysis. Direct, real-time identification of nucleobases in DNA strands is still limited by the sensitivity and the spatial resolution of established ionic sensing strategies. Here, we study a different but promising strategy based on optical spectroscopy. We use an optically engineered elongated nanopore structure, a plasmonic nanoslit, to locally enable single-molecule surface enhanced Raman spectroscopy (SERS). Combining SERS with nanopore fluidics facilitates both the electrokinetic capture of DNA analytes and their local identification through direct Raman spectroscopic fingerprinting of four nucleobases. By studying the stochastic fluctuation process of DNA analytes that are temporarily adsorbed inside the pores, we have observed asynchronous spectroscopic behavior of different nucleobases, both individual and incorporated in DNA strands. These results provide evidences for the single-molecule sensitivity and the sub-nanometer spatial resolution of plasmonic nanoslit SERS.

Topics: Adsorption; Deoxyadenine Nucleotides; Deoxycytidine Monophosphate; Deoxyguanine Nucleotides; DNA; Nanopores; Nanotechnology; Spectrum Analysis, Raman

Mitochondrial DNA depletion syndrome, a frequent cause of childhood (hepato)encephalomyopathies, is defined as a reduction of mitochondrial DNA copy number related to nuclear DNA. It was previously shown that mtDNA depletion can be prevented by dAMP/dGMP supplementation in deoxyguanosine kinase-deficient fibroblasts. We investigated myotubes of patients diagnosed with mtDNA depletion carrying pathogenic mutations in DGUOK, POLG1 (Alpers syndrome) and TYMP. Differentiating myotubes of all patients and controls were supplemented with different doses of dAMP/dGMP or dAMP/dGMP/dCMP in TYMP deficiency, and analysed for mtDNA/nDNA ratio and for cytochrome c oxidase (COX) activity. Serum deprivation and myotube formation triggered a decrease in mtDNA copy number in DGUOK or POLG1 deficient myotubes, but not in TYMP deficiency and healthy controls. Supplementation with dAMP/dGMP leads to a significant and reproducible rescue of mtDNA depletion in DGUOK deficiency. POLG1 deficient myotubes also showed a mild, not significant increase in mtDNA copy number. MtDNA depletion did not result in deficient COX staining in DGUOK and POLG1-deficient myotubes. Treatment with ethidium bromide resulted in very severe depletion and absence of COX staining in all cell types, and no recovery was observed after supplementation with dAMP/dGMP. We show that supplementation with dAMP/dGMP increases mtDNA copy number significantly in DGUOK deficient myotubes and, leads to a mild, non-significant improvement of mtDNA depletion in POLG1 deficiency. No adverse effect on mtDNA copy number was observed on high-dose supplementation in vitro. Further studies are needed to determine possible therapeutic implications of dAMP/dGMP supplementation for DGUOK deficiency in vivo.

Topics: Adult; Cells, Cultured; Deoxyadenine Nucleotides; Deoxyguanine Nucleotides; DNA, Mitochondrial; Female; Gene Dosage; Humans; Infant; Male; Mitochondrial Diseases; Muscle Fibers, Skeletal; Myoblasts

When Escherichia coli DNA polymerase I (Pol I) replicates a homopolymer, the excision/polymerization (exo/pol) ratio varies with enzyme and initiator concentration. The study of this effect in the case of poly(dA).oligo(dT) replication led us to propose a mnemonic model for Pol I, in which the 3' to 5' excision activity warms up when the enzyme is actively polymerizing, and cools down when it dissociates from the template. The model predicts that the exo/pol ratio must increase with processivity length and initiator concentration and decrease with enzyme concentration. It predicts also that contact of the enzyme with one template alters its excision efficiency towards another template. The exo/pol ratio and processivities of Pol I and its Klenow fragment were studied on four templates: poly(dA).(dT)10, poly(dT).(dA)10, poly(dC).(dG)10 and poly(dI).(dC)10. We show that the Klenow fragment is usually much less processive than Pol I and when this is the case it has a much lower exo/pol ratio. At equal processivity, the exo/pol ratios are nearly equal. Furthermore, many factors that influence processivity length (e.g. manganese versus magnesium, inorganic pyrophosphate, ionic strength) influence the exo/pol ratio in the same direction. The study of deaminated poly(dC) replication, where we followed incorporation and excision of both G and A residues, allowed us to assign the origin of the dNMP variations to changes in the 3' to 5' proof-reading activity of Pol I. Similarly, the lower dNMP turnover of the Klenow fragment observed with deaminated poly(dC) was specifically assigned to a decreased 3' to 5' exonuclease activity. The exo/pol ratio generally increased with initiator and decreased with enzyme concentration, in agreement with the model, except for poly(dI).oligo(dC), where it decreased with initiator concentration. However, by terminating chain elongation with dideoxy CTP, we showed directly that, even in this system, excision is relatively inefficient at the beginning of synthesis. Interaction of Pol I with poly(dA).(dT) or with poly(dC).(dG) modifies its exo/pol characteristics in the replication of poly(dI).(dC) and poly(dA).(dT), respectively. The Klenow enzyme is not sensitive to such influences and this correlates with its reduced processivity on the influencing templates. Our results reveal the existence of differences between Pol I and its Klenow fragment that are more profound than has been thought previously.(ABSTRACT TRUNCATED AT 400 WORDS)

Topics: Base Composition; Deoxyadenine Nucleotides; Deoxycytidine Monophosphate; Deoxyguanine Nucleotides; DNA Polymerase I; DNA Replication; Escherichia coli; Kinetics; Models, Biological; Poly dA-dT; Templates, Genetic; Thymine Nucleotides