Solution structures of the i-motif tetramers of d(TCC), d(5methylCCT) and d(T5methylCC): novel NOE connections between amino protons and sugar protons

AbstractBackground: At slightly acid or even neutral pH, oligodeoxynucleotides that include a stretch of cytidines form a tetramer structure in which two parallel-stranded duplexes have their hemi-protonated C·C+ base pairs face-to-face and fully intercalated, in a so-called i-motif, first observed serendipitously in [d(TC5 )]4.Results A high-definition structure of [d(TCC)]4 was computed on the basis of inter-residue distances corresponding to 21 NOESY cross-peaks measured at short mixing times. A similarly defined structure of [d(5mCCT)]4 was also obtained. A small number of very characteristic (amino proton)-(sugar proton) cross-peaks entails the intercalation topology. The structure is generally similar to that of [d(TC5 )]4 . The sequence d(T5mCC) forms two tetramers in comparable proportions. The intercalation topologies are read off the two patterns of (amino proton)-(sugar proton) cross-peaks: one is the same as in the d(TCC) tetramer, the other has the intercalated strands shifted by one base, which avoids the steric hindrance between the methyl groups of the 5mC pairs of the two duplexes. .Conclusion The structures obtained in this work and the procedures introduced to characterize them and to solve the problems linked to the symmetry of the structure provide tools for further exploring the conditions required for formation of the i-motif

Terminal Base Pairs of Oligodeoxynucleotides: Imino Proton Exchange and Fraying

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Design and Implementation of a Protection System for NMR Spectrometers

International audienceWe have implemented a scheme, SPECMON, for monitoring various parameters of a spectrometer, such as nitrogen pressure and sample temperature, and taking corrective action. The scheme is based on considerations of protection management which are of general application. Evaluation of the spectrometer state is incorporated in macros of the application software (VNMR) and is therefore very flexible. In contrast, corrective action is limited to the single one which is deemed fully safe: complete shutdown of the spectrometer and logging. Shutdown is implemented by a minor hardware modification of the spectrometer: the introduction of a second input to a relay already present for protection of the spectrometer power supply. Monitoring is handled by the host computer, and the shutdown command is transmitted via control lines of its series port, independent of the standard connection between the host computer and the NMR system console. The monitoring system (software and hardware) is unobtrusive in normal conditions, and it can be tested without affecting the operation of the spectrometer

Terminal Base Pairs of Oligodeoxynucleotides: Imino Proton Exchange and Fraying

International audienceABSTRACT: We have estimated the dissociation constant of the terminal base pairs of the B-DNA duplexes formed by 5'.d(CGCGATCGCG) and 5'-d(TAGCGCTA) by two methods. one based on the change in imino proton chemical shift with temperature and the other on the apparent PK shift of the imino proton, as monitored by the change in chemical shift of aromatic protons. These methods do not rely on imino proton exchange, whose rate was also measured. (1) The effect of ammonia on the imino proton exchange rate of the termlnal pair of the 5'-d(CGCGATCGCG) duplex is 67 times less than on the isolated nucleoside. This provides an upper limit on the exchange rate from the closed pair. In fact, the effect is just as predicted from the dissociation constant, assuming that there is no exchange at all from the closed pair and that, as has been argued previously, external catalysts act on the open state as they do on the isolated nucleoside. The inhibition of catalyzed proton exchange in the closed pair, despite exposure of one face of the pair to solvent, is a new feature of the exchange process. It will allow determination of the dissociation constant of terminal pairs from the exchange rate. (2) Intrinsic catalysis of proton exchange is less efficient for the terminal pair than for an internal one. A possible explanation is that proton transfer across the water bridge responsible for intrinsic catalysis is slower, as expected if the open-state separation of the bases is larger in a terminal pair. This observation may lead to a direct method for the study of fraying. (3) At O cc, the dissociation constant of the second pair of the duplex is close to the square of the constant for the terminal pair, as predicted from a simple model of fraying. The enthalpy and entropy of opening of the terminal pairs may be compared with those of nearest neighbor interactions derived from calorimetry [Breslauer, K. J., el al. (1986) Proc. Natl. Acad Sci. U.S.A. 83, 3746—3750]

Switching and Looping in i-motif Structures

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Innovative integrated system for real-time measurement of hybridization and melting on standard format microarrays

International audienceDespite the great popularity and potential of microarrays, their use for research and clinical applications is still hampered by lengthy and costly design and optimization processes, mainly because the technology relies on the end point measurement of hybridization. Thus, the ability to monitor many hybridization events on a standard microarray slide in real time would greatly expand the use and benefit of this technology, as it would give access to better prediction of probe performance and improved optimization of hybridization parameters. Although real-time hybridization and thermal denaturation measurements have been reported, a complete walk-away system compatible with the standard format of microarrays is still unavailable. To address this issue, we have designed a biochip tool that combines a hybridization station with active mixing capability and temperature control together with a fluorescence reader in a single compact benchtop instrument. This integrated live hybridization machine (LHM) allows measuring in real time the hybridization of target DNA to thousands of probes simultaneously and provides excellent levels of detection and superior sequence discrimination. Here we show on an environmental single nucleotide polymorphism (SNP) model system that the LHM enables a variety of experiments unachievable with conventional biochip tools