Acyloxymethyl and 4-acyloxybenzyl diester prodrugs of phosphonoformate

An efficient synthesis of cis-4-hydroxyphosphonic and cis-4-hydroxyphosphinic analogs of pipecolic acid from cyclic enaminones

An expedient synthetic entry to cis-4-hydroxyphosphonic and cis-4-hydroxyphosphinic analogs of cis-4-hydroxypipecolic acid is presented in this paper. The main feature of this methodology is the highly regioselective addition of silyl phosphites or phosphonites to cyclic 1-benzyloxycarbonyl enaminones. Interestingly, the hydride reduction of the resulting 2-phospho-4-oxopiperidine proceeds with high diastereofacial preference using NaBH₄. In the last step, the cleavage of N-Cbz group under hydrogenolysis followed by the hydrolysis of the phosphonate or phosphinate functionalities, led to the target cis-4-hydroxyphosphonic and cis-4-hydroxyphosphinic acids, respectively.

Improving properties of the nucleobase analogs T-705/T-1105 as potential antiviral

In this minireview we describe our work on the improvement of the nucleobase analogs Favipiravir (T-705) und its non-fluorinated derivative T-1105 as influenza and SARS-CoV-2 active compounds. Both nucleobases were converted into nucleotides and then included in our nucleotide prodrugs technologies cycloSal-monophosphates, DiPPro-nucleoside diphosphates and TriPPPro-nucleoside triphosphates. Particularly the DiPPro-derivatives of T-1105-RDP proved to be very active against influenza viruses. T-1105-derivatives in general were found to be more antivirally active as compared to their T-705 counterpart. This may be due to the low chemical stability of all ribosylated derivatives of T-705. The ribosyltriphosphate derivative of T-1105 was studied for the potential to act as a inhibitor of the SARS-CoV-2 RdRp and was found to be an extremely potent compound causing lethal mutagenesis. The pronucleotide technologies, the chemical synthesis, the biophysical properties and the biological effects of the compounds will be addressed as well.

Synthesis and biological activity of phosphonocarboxylate DNA

Oligodeoxynucleotides containing internucleotide phosphonoacetate esters are taken up irreversibly by cells in culture in the absence of cationic lipids. These oligonucleotides also are active in stimulating RNase H and are stable toward nucleases.

Synthesis and in vitro evaluation of S-acyl-3-thiopropyl prodrugs of Foscarnet

A new enzyme-labile group called S-acyl-3-thiopropyl group (SATP) has been synthesized from allylic esters of phosphonate. After demonstration of the enzyme-labile character of the SATP in cellular extracts, it has been introduced onto the phosphonate moiety of PFA (Foscarnet) to obtain potential lipophilic prodrugs. To ponder the lipophilicity of the triesters of PFA, esters of monomethylether of polyethyleneglycols and of thioglycerol were introduced on the PFA carboxylate moiety. The SATP groups were introduced in an attempt to deliver PFA after bioactivation inside the cells. The PFA prodrugs were evaluated in vitro for their activity against human immunodeficiency viruses (HIV-1 and HIV-2).

Comparative study of bis(benzyl)phosphate triesters of 2',3'-dideoxy-2',3'-didehydrothymidine (d4T) and cyclosal-d4TMP--hydrolysis, mechanistic insights and anti-HIV activity

A comparative study of three cycloSal-d4TMP 1, 2 and 3 and a variety of bis(benzyl) phosphate triester 4-8 of the antivirally active nucleoside analogue 2',3'-dideoxy-2',3'-didehydrothymidine (d4T) will be described. This study has been initiated by the observation that the introduction of a simple 7-methyl group in the cycloSal-structure (2) led to a completely different hydrolysis pattern as compared to the prototype cycloSal-d4TMP 1. Instead of the selective formation of d4TMP, a phenyl phosphate diester was formed in the case of the 7-methyl-substituted compound 2. The difference in degradation pathway was caused by a change of the reaction mechanism. The phenyl phosphate diester was chemically and enzymatically inert to further cleavage to yield d4TMP. For comparison bis(benzyl)-d4TMP 4, bis(alpha-methylbenzyl)-d4TMP 5, bis(alpha-methoxycarbonylmethyl [MCM]-benzyl)-d4TMP 6 as well as the enzyme-cleavable bis(4-acetoxybenzyl)-d4TMP [bis(AB)-d4TMP(7 and bis(alpha-methoxycarbonylmethyl-4-acetoxybenzyl)-d4TMP [bis(alpha-MCM-AB)-d4TMP] 8 were synthesized. Chemical hydrolysis studies proved that all bis(benzyl) triesters hydrolyze to give the intermediate benzyl phosphate diesters. Moreover, the latter two triesters 7,8 and cycloSal-d4TMPs 1 and 3 led finally to the delivery of d4TMP. The chemical hydrolysis studies allowed a detailed mechanistic interpretation of the degradation pathways of triesters 1-8. Cell extract studies of the bis(benzyl) triesters 4-8 confirmed that only triesters 7 and 8 released d4TMP although with a considerable increase of the reaction rate. Anti-HIV evaluation of the compounds showed that cycloSal-d4TMP 1 and the bis(AB) triesters 7,8 were entirely independent of the presence of cellular thymidine kinase (TK).

Neoglycolipid conjugates of foscarnet with enhanced antiviral activity in cells infected with human cytomegalovirus and herpes simplex virus type 1

The synthesis of a series of neoglycolipid conjugates of foscarnet as potential drug targeting forms or lipophilic prodrugs of foscarnet is described. The compounds were obtained from suitably protected neoglycolipids, in which the lipid chain consisted of 12 to 20 carbon atoms, by ethoxycarbonylphosphonylation at the 6-hydroxyl or 4-hydroxyl group followed by deprotection. The in vitro antiviral activity of the compounds was determined in human foetal lung cells infected with human cytomegalovirus (HCMV) or herpes simplex virus type 1 (HSV-1). Compounds in which the lipid chain consisted of 14 to 20 carbon atoms showed pronounced antiviral activity against HCMV and HSV-1, the highest activity being shown by trans-9-octadecen-1-yl 6-O-carboxyphosphonyl-alpha-D-glucopyranoside against HCMV (approximately 50 times that of foscarnet) and by eicosyl 6-O-carboxyphosphonyl-beta-D-galactopyranoside against HSV-1 (approximately 15 times that of foscarnet). Cytotoxicity was determined by assessing the capability of mitochondrial enzymes to metabolise MTT and gave TC50 values for the compounds that were 30 to 350 times higher than their IC50 values against HCMV and 5 to 15 times higher than their IC50 values against HSV-1. Foscarnet was not liberated on incubation of n-tetradecyl 6-O-carboxyphosphonyl-alpha-D-glucopyranoside with rat liver or intestine homogenate, neither could the neoglycolipid conjugate nor foscarnet be detected in rat plasma following oral administration. Further metabolic and pharmacokinetic studies are required in order to determine whether neoglycolipid conjugates of foscarnet can find a use as drug targeting forms of foscarnet.

Synthesis and antiviral evaluation of SATE-foscarnet prodrugs and new foscarnet-AZT conjugates

The synthesis of a range of di- and triester derivatives of phosphonoformate (PFA; foscarnet) as potential lipophilic, membrane-soluble prodrugs is described. In addition to normal alkyl esters in the carboxylate and phosphonate residues of PFA, the bioreversible S-(pivaloyl)thioethyl (t-butyl-SATE) group was introduced in an attempt to deliver PFA after bioactivation inside the cells. Furthermore, PFA-AZT conjugates were prepared in order to develop combinational drugs. The key synthetic step was in all cases the formation of the P-C bond to build up the different PFA esters. In contrast to the diester derivatives, the triesters of PFA showed high hydrolytic instability during chromatographic purification. The compounds were evaluated in vitro for their ability to inhibit viruses in several tissue culture systems. All PFA alkyl di- and triesters proved poorly active or inactive against human immunodeficiency virus (HIV) and inactive against hepatitis B virus. In contrast, the PFA-AZT conjugates exhibited significant anti-HIV activity. However, this activity was nearly completely lost in thymidine kinase-deficient cells, suggesting a fast unselective chemical hydrolysis of the conjugates to yield the nucleoside analogue AZT in the cell culture medium. Furthermore, no synergistic effect of PFA and AZT was observed.