7075-11-8Relevant articles and documents
Bisphosphonate derivatives of nucleoside antimetabolites: Hydrolytic stability and hydroxyapatite adsorption of 5′-β,γ-methylene and 5′-β,γ-(1-hydroxyethylidene) triphosphates of 5-fluorouridine and ara-cytidine
Ora, Mikko,Loennberg, Tuomas,Florea-Wang, Diana,Zinnen, Shawn,Karpeisky, Alexander,Loennberg, Harri
, p. 4123 - 4130 (2008/09/21)
(Chemical Equation Presented) Kinetics of the hydrolytic reactions of four bisphosphonate derivatives of nucleoside antimetabolites, viz., 5-fluorouridine 5′-β,γ-(1-hydroxyethylidene) triphosphate (4), 5-fluorouridine 5′-β,γ-methylene triphosphate (5), ara-cytidine 5′-β,γ-(1-hydroxyethylidene) triphosphate (6), and ara-cytidine 5′-β,γ-methylene triphosphate (7), have been studied over a wide pH range (pH 1.0-8.5) at 90°C. With each compound, the disappearance of the starting material was accompanied by formation of the corresponding nucleoside 5′-monophosphate, the reaction being up to 2 orders of magnitude faster with the β,γ-(1-hydroxyethylidene) derivatives (4, 6) than with their β,γ-methylene counterparts (5, 7). With compound 7, deamination of the cytosine base competed with the phosphate hydrolysis at pH 3-6. The measurements at 37°C (pH 7.4) in the absence and presence of divalent alkaline earth metal ions (Mg2+ and Ca2+) showed no sign of metal ion catalysis. Under these conditions, the initial product, nucleoside 5′-monophosphate, underwent rapid dephosphorylation to the corresponding nucleoside. Hydrolysis of the β,γ-methylene derivatives (5, 7) to the corresponding nucleoside 5′-monophosphates was markedly faster in mouse serum than in aqueous buffer (pH 7.4), the rate-acceleration being 5600- and 3150-fold with 5 and 7, respectively. In human serum, the accelerations were 800- and 450-fold compared to buffer. In striking contrast, the β,γ-(1-hydroxyethylidene) derivatives did not experience a similar decrease in hydrolytic stability. The stability in human serum was comparable to that in aqueous buffer (τ1/2 = 17 and 33 h with 4 and 6, respectively), and on going to mouse serum, a 2- to 4-fold acceleration was observed. To elucidate the mineral-binding properties of 4-7, their retention on a hydroxyapatite column was studied and compared to that of zoledronate (1a) and nucleoside mono-, di-, and triphosphates.
Cytotoxic nucleoside-corticosteroid phosphodiesters
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, (2008/06/13)
Nucleotides of nucleosides or bases having known cytotoxic activity are reacted with steroids, preferably corticosteroids, to form corresponding cytotoxic nucleoside-corticosteroid phosphodiester analogues of the formula: STR1 wherein: steroid is the residue formed by removal of a hydroxyl hydrogen atom from a natural or synthetic adrenal corticosteroid containing the characteristic cyclopentanophenanthrene nucleus which is esterified to the phosphate moiety at the 21-position; sugar is a naturally occurring pentose or deoxypentose in the furanose form, preferably ribose, deoxyribose, lyxose, xylose or arabinose and especially ribose, deoxyribose or arabinose, which is esterified to the phosphate moiety at the 5'-position and covalently bonded to the heterocycle moiety at the 1'-position to form a nucleoside; and heterocycle is a purine, pyrimidine, hydrogenated pyrimidine, triazolopurine or similar nucleoside base. The conjugates exhibit an enhanced therapeutic index as compared to the parent nucleoside or base compounds, and are thus useful cytotoxic, antiviral and antineoplastic agents.
Nucleoside conjugates as potential antitumor agents. 2. Synthesis and biological activity of 1-(beta-D-arabinofuranosyl)cytosine conjugates of prednisolone and prednisone.
Hong et al.
, p. 1428,1430, 1431 (2007/10/09)
Two of the new anticancer drugs recently synthesized in our laboratory from conjugation of ara-C2 and several corticosteroids linked through a phosphodiester bond include prednisolone- (I) and prednisone-p-ara-C (II). They were demonstrated to be enzymatically hydrolyzed to the corresponding steroid and ara-CMP and the latter was further shown to be hydrolyzed to ara-C by phosphodiesterase I, snake venom, 5''-nucleotidase, and acid phosphatase. However, the conjugates were shown to be resistant to hydrolysis by alkaline phosphatase. The activity of conjugates I and II against L1210 lymphoid leukemia in female mice (C3D2F1/J) was significantly greater than that of ara-C alone or in combination with the steroid. In fact, when the optimum dosage of 75 (mumol/kg)/day x 5 was used, the administration of ara-C alone was followed by an increased life span (ILS) of 45%. This result is similar to that previously reported. With the same equimolar doses of mixtures of ara-C and either prednisolone or prednisone, the ILS values were 40 and 44%, respectively. However, when the conjugates were used, the ILS values were 89 and 100% respectively. These findings seem promising and have provided the bases for continued study of these new compounds.
