Inhibition of the B to Z transition in poly(dGdC).poly(dGdC) by covalent attachment of ethidium: kinetic studies

Sanguinaria canadensis: Traditional Medicine, Phytochemical Composition, Biological Activities and Current Uses

Sanguinaria canadensis, also known as bloodroot, is a traditional medicine used by Native Americans to treat a diverse range of clinical conditions. The plants rhizome contains several alkaloids that individually target multiple molecular processes. These bioactive compounds, mechanistically correlate with the plant’s history of ethnobotanical use. Despite their identification over 50 years ago, the alkaloids of S. canadensis have not been developed into successful therapeutic agents. Instead, they have been associated with clinical toxicities ranging from mouthwash induced leukoplakia to cancer salve necrosis and treatment failure. This review explores the historical use of S. canadensis, the molecular actions of the benzophenanthridine and protopin alkaloids it contains, and explores natural alkaloid variation as a possible rationale for the inconsistent efficacy and toxicities encountered by S.canadensis therapies. Current veterinary and medicinal uses of the plant are studied with an assessment of obstacles to the pharmaceutical development of S. canadensis alkaloid based therapeutics.

Conversions of the left-handed form and the protonated form of DNA back to the bound right-handed form by sanguinarine and ethidium: A comparative study

The interaction of sanguinarine and ethidium with right-handed (B-form), left-handed (Z-form) and left-handed protonated (designated as H(L)-form) structures of poly(dG-dC).poly(dG-dC) and poly(dG-me5dC).poly(dG-me5dC) was investigated by measuring the circular dichroism and UV absorption spectral analysis. Both sanguinarine and ethidium bind strongly to the B-form DNA and convert the Z-form and the H(L)-form back to the bound right-handed form. Circular dichroic data also show that the conformation at the binding site is right-handed, even though adjacent regions of the polymer have a left-handed conformation either in Z-form or in H(L)-form. Both the rate and extent of B-form to Z-form transition were decreased by sanguinarine and ethidium under ionic conditions that otherwise favour the left-handed conformation of the polynucleotides. The rate of decrease is faster in the case of ethidium as compared to that of sanguinarine. Scatchard analysis of the spectrophotometric data shows that sanguinarine binds strongly to both the polynucleotides in a non-cooperative manner under B-form conditions, in sharp contrast to the highly-cooperative binding under Z-form and H(L)-form conditions. Correlation of binding isotherms with circular dichroism data indicates that the cooperative binding of sanguinarine under the Z-form and the H(L)-form conditions is associated with a sequential conversion of the polymer from a left-handed to a bound right-handed conformation. Determination of bound alkaloid concentration by spectroscopic titration technique and the measurement of circular dichroic spectra have enabled us to calculate the number of base pairs of Z-form and H(L)-form that adopt a right-handed conformation for each bound alkaloid. Analysis reveals that 2-3 base pairs (bp) of Z-form of poly(dG-dC).poly(dG-dC) and poly(dG-me5dC).poly(dG-me5dC) switch to the right-handed form for each bound sanguinarine, while approximately same number of base pairs switch to the bound right-handed form in complexes with H(L)-form of these polynucleotides. Comparative binding analysis shows that ethidium also converts approximately 2 bp of Z-form or H(L)-form to bound right-handed form under same experimental conditions. Since sanguinarine binds preferentially to alternating GC sequences, which are capable of undergoing the B to Z or B to H(L) transition, these effects may be an important part in understanding its extensive biological activities.

Chemical cross-linking of ethidium to DNA by glyoxal

Ethidium was found to be efficiently cross-linked to DNA by glyoxal. Kinetic studies showed that the rate of the cross-linking reaction is strongly dependent on the glyoxal concentration. Comparative studies using a series of phenanthridines and acridines showed that NH2 groups at both the 2 and 7 positions on the phenanthridine ring are necessary for efficient cross-linking. Studies using synthetic polydeoxynucleotides showed that the 2-amino group of guanine is absolutely required for cross-linking. Fluorescence contact energy transfer and relative viscosity experiments showed that the cross-linked drug remains intercalated into DNA. DNA gel electrophoresis and melting studies demonstrated that cross-linked ethidium does not dissociate the DNA double helix to single strands.

Tryptophan intercalation in G, C containing polynucleotides: Z to B conversion of poly [d(G-5M C)] in low salt induced by a tetra peptide

Binding of a tetra peptide, lysyl tryptophenyl glycyl lysine O-ter butyl ester (KWGK) with duplex forms of G, C containing polynucleotides, Poly [d(G-C)], Poly [d(G-5M C)], Poly (dG), Poly (dC) and E.coli DNA were studied under low salt conditions using UV absorption, fluorescence, and circular dichroic (C.D) spectroscopy. On addition of the peptide (upto a P/N mole ratio of 0.5), the Poly [d(G-5M C)] under low salt (1 mM Na Cl) conditions, was converted from Z to B-form as shown by the inversion of C.D spectra. The two binding constants (K1 and K2) were determined from fluorescence spectroscopy of which K2 estimates the intercalation of the tryptophenyl side chain between the base pairs of DNA and K1 estimates the electrostatic interactions between the lysyl side chains and phosphate groups. The strength of intercalation is: Z-form of Poly [d(G-5M C)] >> B form of Poly [d(G-5M C)] >> E.Coli DNA > Poly (dG).Poly (dC). This means that peptide seems to have strong preference for Z compared to B-form and for alternating over non-alternating G, C Sequences. This suggests that tryptophan intercalation may act as a discriminating factor in recognizing Z and B-forms and may have a potential role in Protein-Nucleic acid interactions that are important for transcription.

Mitomycin C binding to poly[d(G-m5C)]

Poly[d(G-m5C)] was modified by reductively activated mitomycin C, an anti-tumour drug, under buffer conditions which are known to favour either the B or the Z conformations of DNA. C.d. and 31P-n.m.r. were used to characterize the poly[d(G-m5C)]-mitomycin cross-linked complexes, as well as the effects on the equilibrium between the B and Z forms of the polynucleotide. Mitomycin C appears to inhibit the B-->Z transition, even in the presence of 3 mM MgCl2, while the Z-form of poly[d(G-m5C)] does not interact significantly with the drug under bifunctionally activating conditions; thus no reversion from the Z-form to the B-form of the polynucleotide can be observed under the salt conditions which are required for the Z-form to exist.