Muriel Delepierre

Chapter 80 Magnetic resonance imaging of intracerebral neural grafts

Publisher Summary Intracerebral transplantation may also be applied therapeutically in some neurodegenerative diseases in humans, however, such a therapeutic application will require non-invasive imaging techniques to control and assess the precise location of intracerebral transplants. This chapter explores the potential of magnetic resonance imaging (MRI) to visualize intracerebral neural transplants in the rat. Possible mechanisms, which can account for the reduction of T 2 values of the graft, are also discussed in the chapter with regard to anatomical characteristics of the tissue. The results demonstrate that the T 2 relaxation time is significantly reduced in the neural tissue reconstructed by fetal cells grafted into the CNS of an adult host, with respect to the normal tissue, and may thus be used as a direct indicator of graft localization. The chapter suggests ways to improve the resolution of intracerebral graft imaging, such as by labeling the transplants with MRI-contrast agents. Specific markers like immunospecific Nuclear magnetic resonance (NMR) contrast agents, for example, superparamagnetic particles coupled to monoclonal antibodies or other ligands may be more interesting for the future follow-up of intracerebral neural grafts in that they can be directed specifically against certain populations of cells and, therefore, demonstrate their survival, and possibly, their functional state.

1H and 31P nuclear magnetic resonance studies of the differences in DNA deformation induced by anti-tumoral 7H-pyrido[4,3-c]carbazole dimers

Ditercalinium (2,2-[( 4,4-bipiperidine]-1,1-diyldi-2,1-ethane-diyl) bis-[10-methoxy-7H pyrido[4,3-c]carbazolium)tetramethane sulfonate (NSC 366241], a DNA bis-intercalating compound, is a potent anti-tumoral rigid dimer. Previous studies have shown that a reduced flexibility of the linking chain of such a dimer is essential for its biological activity. In order to understand, at the molecular level, the mechanism of action and the structure-activity relationships of this series of DNA intercalators, new dimers with additional methylene groups between the two piperidine rings have been synthesized. Addition of one methylene group in the chain preserved the activity, whereas addition of two methylene groups reduced the cytotoxicity, which finally disappeared when three methylene groups were inserted. Therefore, the study of the interaction of dimers bearing no (202), two (222) and three (232) methylene groups with the self-complementary hexanucleotide d(CGATCG)2 have been investigated by 1H and 31P nuclear magnetic resonance studies. The results reported here indicate that all dimers bis-intercalate into the minihelix. The intermolecular nuclear Overhauser effects (NOEs) between the dimers and the nucleotide lead to the conclusion that the three dimers intercalate with their rigid bis-ethyl bipiperidine chain fitting the major groove of the helix. Inter-residue nuclear Overhauser effects at the DNA level, as well as induced shifts, are discussed in relation to the conformational changes induced in DNA upon intercalation and to the different activity of the dimers.

Reassessment of structural characteristics of the d(CGCG)2:actinomycin D complex from complete 1H and 31P NMR.

Complexes formed between Actinomycin D (ActD) and the tetranucleotides d(AGCT)2 and d(CGCG)2 were studied in detail by one and two-dimensional 1H and 31P NMR. The 31P two dimensional chemical exchange experiment, at room temperature on saturated complexes (1:1), showed unambiguously that the asymmetrical phenoxazone ring binds to the unique GC site under the two possible orientations in the d(AGCT)2 tetranucleotide but adopts a single orientation in the d(CGCG)2 tetranucleotide. For the d(CGCG)2:Act D saturated complex, complete assignments of all protons and phosphorus signals of the two-nucleotide strands, as well as of the two cyclic pentapeptide chains has allowed us to study in details the conformational features of the complex from NOE and coupling constants analysis. The tetranucleotide remains in a right-handed duplex, but the sugar puckers are modified for residues at the intercalation site. A uniform C2 endo pucker is observed for residues on the strand facing the quinoid side of the phenoxazone ring while a C2 endo-C3-endo equilibrium about 60% of C2 endo is proposed for the two residues on the strand facing the benzenoid side of the phenoxazone ring. In contrast to previous studies on ActD-DNA interactions, we have been able to measure the 3J phosphorus-proton coupling constants at the intercalation site but also adjacent to it, showing that 31P chemical shifts are not simply related to the backbone conformation. Molecular mechanics calculations, using empirical distances deduced from NOE effects as restrained distances during minimizations, led to a model differing mainly from those previously published by orientation of the N methyl groups of both N-Methyl-Valines.

Intercalative Binding of Ditercalinium to d(CpGpCpG)2: A Theoretical Study

The structure of the complex formed between ditercalinium, 2,2-[4,4-bipiperidine-1,1-bis-(ethane-1,2-diyl)]bis(10-me thoxy-7H- pyrido[4,3-c]carbazolium) tetramethane sulfonate (NSC 366241), and the self-complementary tetranucleotide duplex d(CpGpCpG)2 has been investigated by means of a novel theoretical approach for modelling the conformational flexibility of nucleic acids. The methodology used is the JUMNA procedure, a molecular mechanics systematics capable of evaluating the internal energy and the interaction energy of a complex formed from a large number of fragments. In the best energy-minimized structures, the piperidinium chains of ditercalinium are located in the major groove of the right-handed oligonucleotide. Calculations show a distortion of the base-paired d(CpGpCpG)2 minihelix consisting of lateral dislocation of one base pair with respect to another along an axis parallel to the long axis; strong propeller twist and tilt of the end base pairs; a collective motion of all base pairs with respect to the helical axis towards the drug; and an overwinding at the exclusion site. The proposed structure of the complex is in good agreement with reported proton NMR data, supporting the feasibility of such model.

A general procedure for assigning the 31P spectra of drug-oligonucleotide complexes.

Taking advantage of the slow exchange at the NMR time scale occurring in drug oligonucleotides complexes the 31P signals in the bound forms are assigned by using 31P NMR two dimensional chemical exchange. This technique was applied to complexes between Actinomycin D and d[CpGpCpG] or d[m5CpGpm5CpG]. As compared to the labelled 17O, 18O this method proved to be a powerful and unique way to assign 31P in broad spectrum or with long oligonucleotides.

NMR Studies of Tris-Intercalation: Solution Structure and Interaction of d(CTTCGCGCGAAG) with an Acridine Trimer

Tris-intercalation of an acridine trimer into the self-complementary dodecanucleotide d(CTTCGCGCGAAG) has been studied, in solution, by means of 1H and 31P nuclear magnetic resonance. In a first step all the non-exchangeable protons (except H5, H5), the imino protons and seven of the eleven phosphorus have been assigned. The dodecanucleotide is shown to adopt a double helical B-type structure. Most of the sugar puckers are in the O1endo range, those of the internal guanosines being closer to C2endo. Deviations from the canonical B structure are observed in the base stacking and the phosphodiester torsional angles at the 3T4C5G stretch. The addition of an acridine trimer to the base-paired dodecanucleotide leads to the conclusion that the trimer, which is in slow exchange at the NMR time scale, tris-intercalates into the three C(3-5)G sites of the central core, according to the excluded site model. This is evidenced by the large (1.4 ppm) upfield shift experienced by the imino protons of the three internal guanines and the shielding undergone by the acridine ring protons. Tris-intercalation is also supported by the downfield shift experienced by 6 out of the 22 phosphorus. Two of them are shifted by nearly 2 ppm, a shift range reported for oligonucleotides complexed to actinomycin D; this suggests that the structure of the backbone of the dodecanucleotide is altered.