A Temperature-Controlled Switch between Fürst-Plattner Rule and Anti-Fürst-Plattner Rule Ring Opening of 2,3-Epoxy-steroids with Various Halide Sources in the Presence of Imidazolium Ionic Liquids.

The ring opening of 2α,3α- and 2ß,3ß-epoxy-5α-androstan-17-one with halide reagents (AlCl3, TMSCl, LiCl, and LiBr) was investigated using imidazolium ionic liquids in the dual role of solvent and catalyst. The application of the ionic liquid was shown to result in an increase in the amount of the unusual diequatorial halohydrins especially at temperatures above 100 °C. With a careful choice of reaction conditions, the latter derivatives could be produced with 43-96% selectivity depending on the nature of the halide ion. Moreover, the usual diaxial products could also be isolated in 70-85% yields by a proper change in the reaction conditions. The reusability of the ionic liquid was demonstrated in both types of reactions. The structures of the products were proved unequivocally by nuclear magnetic resonance (NMR) measurements including two-dimensional (2D) techniques as well as high-resolution mass spectrometry (HRMS). Based on quantum chemical calculations, the effect of the ionic liquid could be explained by the stabilization of the transition state leading to the diequatorial product.

The effect of conjugation on antitumor activity of vindoline derivatives with octaarginine, a cell-penetrating peptide.

Some Vinca alkaloids (eg, vinblastine, vincristine) have been widely used as antitumor drugs for a long time. Unfortunately, vindoline, a main alkaloid component of Catharanthus roseus (L.) G. Don, itself, has no antitumor activity. In our novel research program, we have prepared and identified new vindoline derivatives with moderate cytostatic activity. Here, we describe the effect of conjugation of vindoline derivative with oligoarginine (tetra-, hexa-, or octapeptides) cell-penetrating peptides on the cytostatic activity in vitro and in vivo. Br-Vindoline-(l)-Trp-OH attached to the N-terminus of octaarginine was the most effective compound in vitro on HL-60 cell line. Analysis of the in vitro activity of two isomer conjugates (Br-vindoline-(l)-Trp-Arg8 and Br-vindoline-(d)-Trp-Arg8 suggests the covalent attachment of the vindoline derivatives to octaarginine increased the antitumor activity significantly against P388 and C26 tumour cells in vitro. The cytostatic effect was dependent on the presence and configuration of Trp in the conjugate as well as on the cell line studied. The configuration of Trp notably influenced the activity on C26 and P388 cells: conjugate with (l)-Trp was more active than conjugate with the (d)-isomer. In contrast, conjugates had very similar effect on both the HL-60 and MDA-MB-231 cells. In preliminary experiments, conjugate Br-vindoline-(l)-Trp-Arg8 exhibited some inhibitory effect on the tumor growth in P388 mouse leukemia tumor-bearing mice. Our results indicate that the conjugation of modified vindoline could result in an effective compound even with in vivo antitumor activity.

NMR and quantum chemical analysis of 3-(2-methly-2-phenylhydrazinyl)cyclohex-2-en-1-one.

Two-dimensional representation of a molecular structure is in some cases misleading, since it may not correctly represent important details and may not provide adequate information on the electronic structure of the molecule. In such cases the physical-chemical properties of the molecule will not be properly interpreted on the basis of the molecular formula. For example, the NMR spectrum will differ significantly from what would be intuitively expected on the basis of this formula and one can deduce the correct electronic and steric structure of the molecule from the obtained spectra instead. In this article the NMR and quantum chemical analysis of the title compound 3-(2-methly-2-phenylhydrazinyl)cyclohex-2-en-1-one will be presented. The unusual NMR spectra and surprising protonation site of this compound will be explained based on the delocalization of the π-symmetric orbitals of its molecules. The proposed electronic structure and the observed but unexpected physical-chemical properties have been confirmed by quantum chemical calculations.

NMR and mass spectrometric characterization of vinblastine, vincristine and some new related impurities - part I.

In the course of exploring the possibilities of developing a new, improved process at Gedeon Richter for the production of the "bisindole" alkaloids vinblastine (VLB) and vincristine (VCR), some novel VLB/VCR-related trace impurities were detected by analytical HPLC. Following isolation by preparative HPLC, a combination of 1D and 2D ultra high-field NMR and high-resolution (HR) (LC-)MS/MS studies allowed the structural identification and complete spectral characterization of several hitherto unpublished VLB/VCR-analogue impurities. Since the impurities could not be isolated in entirely pure forms and were available only in minute, mass-limited quantities, accessing the spectral information needed for their ab initio structure determination was met with various practical difficulties. Successful structure determination therefore relied heavily on the availability and use of detailed and definitive spectral data for both VLB and VCR. In particular, the utilization of detailed (1)H, (13)C, and (15)N NMR assignments as well as (1)H-(1)H, (1)H-(13)C and (1)H-(15)N spin-spin connectivities pertaining to different solvents for VLB/VCR base and sulphate salt was required. Although NMR studies on VLB base and other bisindoles were reported earlier in the literature, an NMR characterization of VLB and VCR under the above-mentioned circumstances and using ultra-high field instrumentation is either scarcely available or entirely lacking, therefore the necessary data had to be obtained in-house. Likewise, a modern tandem HR-ESI-MS/MS(n) fragmentation study of VLB and VCR has not been published yet. In the present paper we therefore give a thorough NMR and MS characterization of VLB and VCR specifically with a view to filling this void and to provide sufficiently extensive and solid reference data for the structural investigation of the aforementioned VLB/VCR impurities. Besides being scientifically relevant in its own right, the disclosed data should be useful for anyone interested in VLB/VCR-related molecules at a structural level.

NMR and mass spectrometric characterization of vinblastine, vincristine and some new related impurities--part II.

In the course of developing a new, improved process at Gedeon Richter for the production of the "bisindole" alkaloids vinblastine (VLB) and vincristine (VCR), some novel VLB/VCR-related trace impurities were detected by analytical HPLC at the production site. Repeated attempts to isolate and purify these unknown impurities by preparative liquid chromatography yielded small amounts of materials whose main components were the unknown impurities, but were still contaminated with other VLB/VCR-related compounds. In spite of these difficulties, by using a combination of high-resolution (LC-)MS/MS and off-line 1D and 2D ultra high-field NMR techniques and leaning on the relevant spectroscopic data for VLB and VCR as discussed in Part 1 [1], we could unambiguously solve the structures of, and could give a complete spectral characterization for, the trace impurities. Among these, although "cyclo-VCR" (impurity-2), "[VCR]-C(16)-COOEt" (impurity-4) and "[VLB]-C(16)-COOEt" (impurity-5) are known synthetic VLB/VCR-derivatives, and "[VLB]-C(14')-OH(α)" is a known natural alkaloid (leurocolombine), they are new VLB/VCR impurities, and "[VCR]-N(4')-C(21')-iminium-salt" (impurity-3) is also a new chemical structure which provides direct proof of a hypothetic metabolic pathway of VLB/VCR. The structure determination of impurity-4 and impurity-5, and the rationalization of their origin was a particularly challenging task: since VCR is produced by the oxidation of VLB, it may be assumed that [VCR]-C(16)-COOEt (impurity-4) originates from the oxidization of [VLB]-C(16)-COOEt (impurity-5). This is consistent with the finding that [VLB]-C(16)-COOEt (impurity-5) could be detected by LC-MS/MS in the raw VLB samples in similar amounts as [VCR]-C(16)-COOEt (impurity-4) in the final VCR product. Our investigations indicate that [VLB]-C(16)-COOEt (impurity-5) does not form directly from VLB during extraction or chromatographic separation, suggesting that it may be a new natural product.

Structure elucidation of indole-indoline type alkaloids: a retrospective account from the point of view of current NMR and MS technology.

In this review our aim is to look back on how the structure elucidation of bisindoles, especially with focus placed on vinblastine and vincristine analogues, has evolved alongside with the development of MS and NMR over the last 60 years from the perspective of our present-day use of state-of-the-art MS and NMR instrumentation and on the basis of our own accumulated views and experience in the field.

Multidimensional NMR identifies the conformational shift essential for catalytic competence in the 60-kDa Drosophila melanogaster dUTPase trimer.

The catalytic mechanism of dUTP pyrophosphatase (dUTPase), responsible for the prevention of uracil incorporation into DNA, involves ordering of the flexible C terminus of the enzyme. This conformational shift is investigated by multidimensional NMR on the Drosophila enzyme. Flexible segments of the homotrimer give rise to sharp resonances in the (1)H-(15)N heteronuclear single-quantum coherence (HSQC) spectra, which are clearly distinguishable from the background resonances of the well folded protein globule. Binding of the product dUMP or the analogues dUDP and alpha,beta-imino-dUTP to the enzyme induces a conformational change reflected in the disappearance of eight sharp resonances. This phenomenon is interpreted as nucleotide binding-induced ordering of some residues upon the folded protein globule. Three-dimensional (15)N-edited (1)H-(15)N HSQC total correlation spectroscopy (TOCSY) and (1)H-(15)N HSQC nuclear Overhauser effect spectroscopy measurements allowed clear assignment of these eight specific resonance peaks. The residues identified correspond to the conserved C-terminal sequence motif, indicating that (i) this conformational shift is amenable to NMR studies in solution even in the large trimeric molecule and (ii) formation of the closed enzyme conformer in the case of the Drosophila enzyme does not require the complete triphosphate chain of the substrate. NMR titration of the enzyme with the nucleotide ligands as well as kinetic data indicated significant deviation from the model of independent active sites within the homotrimer. The results suggest allosterism in the eukaryotic dUTPase.

Altered active site flexibility and a structural metal-binding site in eukaryotic dUTPase: kinetic characterization, folding, and crystallographic studies of the homotrimeric Drosophila enzyme.

dUTPase is responsible for preventive DNA repair via exclusion of uracil. Developmental regulation of the Drosophila enzyme is suggested to be involved in thymine-less apoptosis. Here we show that in addition to conserved dUTPase sequence motifs, the gene of Drosophila enzyme codes for a unique Ala-Pro-rich segment. Kinetic and structural analyses of the recombinant protein and a truncation mutant show that the Ala-Pro segment is flexible and has no regulatory role in vitro. The homotrimer enzyme unfolds reversibly as a trimeric entity with a melting temperature of 54 degrees C, 23 degrees C lower than Escherichia coli dUTPase. In contrast to the bacterial enzyme, Mg(2+) binding modulates conformation of fly dUTPase, as identified by spectroscopy and by increment in melting temperature. A single well folded, but inactive, homotrimeric core domain is generated through three distinct steps of limited trypsinolysis. In fly, but not in bacterial dUTPase, binding of the product dUMP induces protection against proteolysis at the tryptic site reflecting formation of the catalytically competent closed conformer. Crystallographic analysis argues for the presence of a stable monomer of Drosophila dUTPase in crystal phase. The significant differences between prototypes of eukaryotic and prokaryotic dUTPases with respect to conformational flexibility of the active site, substrate specificity, metal ion binding, and oligomerization in the crystal phase are consistent with alteration of the catalytic mechanism and hydropathy of subunit interfaces.