Heterocyclic rimantadine analogues with antiviral activity

2-(1-Adamantyl)-2-methyl-pyrrolidines 3 and 4, 2-(1-adamantyl)-2-methyl-azetidines 5 and 6, and 2-(1-adamantyl)-2-methyl-aziridines 7 and 8 were synthesized and tested for their antiviral activity against influenza A. Parent molecules 3, 5, and 7 contain the alpha-methyl-1-adamantan-methanamine 2 pharmacophoric moiety (rimantadine). The ring size effect on anti-influenza A activity was investigated. Pyrrolidine 3 was the most potent anti-influenza virus A compound, 9-fold more potent than rimantadine 2, 27-fold more potent than amantadine 1, and 22-fold more potent than ribavirin. Azetidines 5 and 6 were both markedly active against influenza A H2N2 virus, 10- to 20-fold more potent than amantadine. Aziridine 7 was almost devoid of any activity against H2N2 virus but exhibited borderline activity against H3N2 influenza A strain. Thus, it appears that changing the five-, to four- to a three-membered ring results in a drop of activity against influenza A virus.     

Design and synthesis of 1,2-annulated adamantane piperidines with anti-influenza virus activity

1–2 Annulated adamantane piperidines 4, 6, 16, 17, 19, 23 and 25 were synthesized and evaluated for anti-influenza A virus activity. The stereoelectronic requirements for optimal antiviral potency were investigated. Piperidine 23 proved to be the most active of the compounds tested against influenza A virus, being 3.5-fold more active than amantadine, equipotent to rimantadine and 15-fold more potent than ribavirin. It is noteworthy that piperidine 23 displayed one of the highest selectivity indexes (SI > 732) among aminoadamantanes or other cage structure amines tested till now.     

Influence of an additional amino group on the potency of aminoadamantanes against influenza virus A. II - Synthesis of spiropiperazines and in vitro activity against influenza A H3N2 virus

Spiro[piperidine-2,2′-adamantane] 4 is one of the most potent synthetic anti-influenza A aminoadamantanes or other cage structure amines tested so far. Based on previous results Tataridis et al. (2007) [5h] which demonstrate the boost of in vitro potency by the presence of an additional amino group, we examined whether the incorporation of a second amino group into this heterocycle would increase the anti-influenza A virus activity. The new synthetic molecules 5–7 are capable of forming two hydrogen bonds within the receptor. We identified the diamino derivatives 5 and 6, which are active against influenza A H3N2 virus although less potent than amantadine and its equipotent spiropiperidine 4.     

Comparisons of the influenza virus A M2 channel binding affinities, anti-influenza virus potencies and NMDA antagonistic activities of 2-alkyl-2-aminoadamantanes and analogues

The new 2-alkyl-2-aminoadamantanes and analogues 4-10 were designed and synthesized by simplification of the structure of the potent anti-influenza virus A spiranic aminoadamantane heterocycles 2 and 3. The aim of the present work was to examine the effects of bulky and extended lipophilic moieties attached to amantadine 1 on binding to the M2 channel and the resulting antiviral potency. The binding affinities of the compounds to the M2 protein of influenza virus A/chicken/Germany/27 (Weybridge strain; H7N7) were measured for the first time using an assay based on quenching of Trp-41 fluorescence by His-37 protonation, and their antiviral potencies were evaluated against the replication of influenza virus A H2N2 and H3N2 subtypes and influenza virus B in MDCK cells. Of the various 2-alkyl-2-aminoadamantanes, and analogues, spiro[piperidine-2,2'-adamantane] 3 had the strongest M2 binding and antiviral potency, which were similar those of amantadine 1. The relative binding affinities suggested that the rigid carbon framework provided by the pyrrolidine or piperidine rings results in a more favorable orientation inside the M2 channel pore as compared to large, freely rotating alkyl groups. The aminoadamantane derivatives exhibited similar NMDA antagonistic activity to amantadine 1. A striking finding was the antiviral activity of the adamantanols 4, and 6, which lack any NMDA antagonist activity.     

Influence of an additional 2-amino substituent of the 1-aminoethyl pharmacophore group on the potency of rimantadine against influenza virus A

We examined whether the incorporation of a second amino group into the 1-aminoethyl pharmacophore of rimantadine 2 and into the piperidine pharmacophore of the heterocyclic rimantadine 4 was compatible with anti-influenza virus A activity. The new synthetic molecules are capable of forming two hydrogen bonds within the receptor. We identified molecules 8 and 16, bearing the adamantyl and 1,2-diaminoethyl groups, which are equipotent to rimantadine 2 bearing the adamantyl and 1-aminoethyl pharmacophore groups. Interestingly, diamino compound 16 is a 4-fold more potent inhibitor than its parent monoamino heterocyclic rimantadine 4 propably because of additional hydrogen bonding interactions with the M2 protein receptor.     

Spiro[pyrrolidine-2,2'-adamantanes]: synthesis,anti-influenza virus activity and conformational properties

Synthetic spiro[pyrrolidine-2,2'-adamantanes] 2, 3, 11, 15, 12, 16, 18, 20 were evaluated in vitro and found to be active anti-influenza virus A compounds; the effect of the position of C-Me pyrrolidine ring substituent on antiviral activity was examined. Pyrrolidine 5-Me substitution appears to be optimal for H(2)N(2) strain activity. From the four different possible protonated conformers, experimental observation using NMR spectroscopy and molecular mechanics calculations demonstrated only a pair of conformers A(+)H (N-Me (ps-ax), C-Me (ps-eq)) and B(+)H ((N-Me ps-ax, C-Me ps-ax)) which can contribute to the biological activity of C-Me, N-Me protonated derivatives 15(+)H, 16(+)H and 20(+)H. The relative populations were calculated from NMR spectra. For compounds 15(+)H and 20(+)H conformer A(+)H (cis dimethyl orientation) is the major one whereas a similar population of conformers A(+)H and B(+)H (trans dimethyl orientation) was observed for compound 16(+)H. Since this new series is characterized by a lipophilic part, that is the pyrrolidine ring, in addition to adamantane, that can interact with influenza A M2 protein, an ultimate future goal would be the in vitro mapping of M2 lipophilic pocket.     

Inhibitors of the Influenza A Virus M2 Proton Channel Discovered Using a High-Throughput Yeast Growth Restoration Assay

The M2 proton channel of the influenza A virus is the target of the anti-influenza drugs amantadine and rimantadine. The effectiveness of these drugs has been dramatically limited by the rapid spread of drug resistant mutations, mainly at sites S31N, V27A and L26F in the pore of the channel. Despite progress in designing inhibitors of V27A and L26F M2, there are currently no drugs targeting these mutated channels in clinical trials. Progress in developing new drugs has been hampered by the lack of a robust assay with sufficient throughput for discovery of new active chemotypes among chemical libraries and sufficient sensitivity to provide the SAR data essential for their improvement and development as drugs. In this study we adapted a yeast growth restoration assay, in which expression of the M2 channel inhibits yeast growth and exposure to an M2 channel inhibitor restores growth, into a robust and sensitive high-throughput screen for M2 channel inhibitors. A screen of over 250,000 pure chemicals and semi-purified fractions from natural extracts identified 21 active compounds comprising amantadine, rimantadine, 13 related adamantanes and 6 non-adamantanes. Of the non-adamantanes, hexamethylene amiloride and a triazine derivative represented new M2 inhibitory chemotypes that also showed antiviral activity in a plaque reduction assay. Of particular interest is the fact that the triazine derivative was not sufficiently potent for detection as an inhibitor in the traditional two electrode voltage clamp assay for M2 channel activity, but its discovery in the yeast assay led to testing of analogues of which one was as potent as amantadine.     

Heterocyclic rimantadine analogues with antiviral activity

2-(1-Adamantyl)pyrrolidines 6, 7, 2-(1-adamantyl)piperidines 10, 12a–c, 15a,b and 2-(1-adamantyl)hexahydroazepines 19, 21, 22 were synthesized and tested for their antiviral activity against influenza A, B viruses and the human immunodeficiency virus type 1 (HIV-1) and type 2 (HIV-2). The synthetic procedure followed for the preparation of the parent piperidine 10 represents a general method for the synthesis of 2-alkyl- or cycloalkyl-substituted piperidine alkaloids. Parent aminoadamantanes 6, 10 and 19 contain the 1-aminoethyl pharmacophore group of rimantadine drug 2, extended into a saturated nitrogen heterocycle: pyrrolidine, piperidine and hexahydroazepine, respectively. The ring size effect in anti-influenza A activity was investigated. Rimantadine analogues 6 and 10 were, respectively, 6- and 4-fold more active than the drug Rimantadine 2, whereas the hexahydroazepine derivative 19 was inactive. Thus, enlargement from a 5-(pyrrolidine)- or 6-(piperidine)- to a 7-(hexahydroazepine)- membered heterocyclic ring dramatically reduced the anti-influenza virus A activity. Substitution of piperidine 10 with a dialkyaminoethyl group led to the active compounds 15a and 15b: compound 15a was active against influenza A virus whereas both 15a and 15b were active against HIV-1.     

In Vivo Antiviral Properties of Biologically Active Compounds: II. Studies with Influenza and Vaccinia Viruses

The in vivo anti-influenza virus and antivaccinia virus activity of 156 biologically active compounds was determined. One of two criteria was used for evaluating activity against the influenza virus. The criteria were increase in survivor number and mean survival time, and reduction in virus-induced lung consolidation in treated, infected Swiss mice. Increase in survivor number and mean survival time were the criteria for evaluation of antivaccinia virus activity. Several drug doses were tested against two virus concentrations to demonstrate antiviral activity more clearly. Two compounds were considered significantly active against the influenza virus: DL-noformicin (NSC 72942) and amantadine hydrochloride (NSC 83653). Eleven compounds had reproducible activity against vaccinia virus: isatin-beta-thiosemicarbazone (NSC 721), 6-azauracil (NSC 3425), 9-alpha-fluoro-2alpha-methylhydrocortisone 21-acetate (NSC 12601), 5-[bis(2-chloroethyl)amino]uracil (NSC 34462), 5-iodo-2'-deoxyuridine (NSC 39661), streptonigrin (NSC 45383), N-methylisatin beta-thiosemicarbazone (NSC 69811), cytovirin (NSC 91770), 9-beta-D-arabinofuranosyladenine (NSC 404241), and 5-(mercaptomethyl)uracil (NSC 529351).     

Synthesis of 2-(2-adamantyl)piperidines and structure anti-influenza virus A activity relationship study using a combination of NMR spectroscopy and molecular modeling

The 2-(2-adamantyl)piperidines 13 and 15a-c were synthesized and evaluated for anti-influenza virus A and B activity. The parent N-H compound 13 was 3–4 times more active than amantadine and rimantadine against H₂N₂ influenza A. N-alkylation of 13 resulted in derivatives 15a-c that were devoid of biological activity. This dramatic reduction in biological activity may be attributed to the different conformational properties between N-H and N-alkyl piperidines, as deduced from the combination of computational chemistry and NMR spectroscopy.     

Current status for influenza control

Influenza viruses are responsible for respiratory illness with significant morbidity and mortality. To curb the disease, two-pronged attack on the virus, therapeutic and prophylactic, is being actively pursued. The therapeutic use of existing anti-influenza drugs, such as amantadine and rimantadine, is limited by their significant adverse side effect, emergence of resistant viral strains, and lack of activity against influenza B virus. A new class of antiviral agents designed to inhibit influenza neuraminidase are currently under active development for use in the prophylaxis and treatment of influenza A and B virus infections. Two of these compounds, zanamivir (GG167) and GS4104 have reached clinical trials. Limitations in the effectiveness and application of inactivated vaccines have stimulated development of alternative approaches to influenza immunization. One such approach is a live, intranasally administered vaccine, attenuated by cold-adaptation of a master strain with subsequent genetic reassortment with circulating wild-type strains. Recently developed reverse-genetics techniques have made it possible to use RNA viruses as vector. Besides DNA viral vectors, live influenza virus vectors may emerge as a useful alternative for the vaccination against different pathogens.     

Inhibitory effect of alpha-methyl-1-adamantane methylamine hydrochloride (rimantadine) on RNA-dependent RNA polymerase induction in culture of cells, infected with influenza virus]

An anti-influenza preparation, rimantadine (alpha-methyl-1-adamantane methylamine hydrochloride) at concentrations of 10--25 mkg/ml depresses the RNA-dependent RNA polymerase induction in a culture of cells infected with influenza virus (fowl plague virus). The inhibitory effect is also observed 2 hours following cell infection. In vitro studies have demonstrated that rimantadine has no effect on the activity of virus-induced RNA-dependent RNA polymerase, as well as on that of RNA-dependent RNA polymerase associated with virus particles.     

Allosteric activation of the hydrolysis of specific substrates by chymotrypsin.

A variety of azobenzene compounds having bis-quaternary nitrogens have been shown to accelerate the hydrolysis by chymotrypsin of certain specific substrates by an allosteric mechanism. One of the most potent, 2,2'-bis[alpha-(benzyldimethylammonium)methyl]azobenzene dibromide (2,2'-QBzl) accelerated the hydrolysis of glutaryl-L-phenylalanine p-nitroanilide 40-fold at saturating concentration. Acceleration was by increasing kcat without altering Km. The hydrolysis of acetyl-L-tyrosine p-nitroanilide and acetyl-L-tyrosine anilide was also accelerated by Q-Bzl (25-fold and 1.8-fold respectively) while the hydrolysis of hemoglobin, azocoll and a number of esters was not affected. The inactivation of chymotrypsin by diphenylcarbamyl chloride and diphenylcarbamyl fluoride was accelerated by 2,2'-Q-Bzl. Reac;ivation in the presence of NH2OH was also accelerated, but in the absence of added nucleophile (i.e. of NH20H) no increase in rate was detectable. An allosteric effector was covalently attached to chymotrypsinogen A by reaction with 2,2'-bis[alpha-(o-bromomethylbenzyldimethylammonium)methyl]azobenezene dibromide. The product, when converted to active enzyme, was about 4 times more active than chymotrypsin as a result of an increase in kcat of hydrolysis; Km was unaffected. The mechanism of the allosteric acceleration process is not known but, because for all of the substrates affected acylation of the enzyme is rate-limitimg, it is tentatively suggested that the effectors facilitate proton transfer to the leaving group by an inductive effect on the 'charge relay system'. Spectral studies indicate that the allosteric site is a portion of the enzyme with a polarity near that of water, possibly on the outside surface of the enzyme molecule.     

Indolo[3,2-c]cinnolines with antiproliferative, antifungal, and antibacterial activity.

A series of indolo[3,2-c]cinnoline derivatives was prepared and tested to evaluate their biological activity. Most of them inhibited the proliferation of leukemia, lymphoma and solid tumor-derived cell lines at micromolar concentrations, whereas none of the compounds were active against HIV-1. With the exception of 7g, all title compounds showed antibacterial activity against gram-positive bacteria, being up to 200 times more potent than the reference drug streptomycin. Some of the indolo[3,2-c]cinnolines were also endowed with good antifungal activity, particularly against Criptococcus neoformans.     

Potent and prolonged melanotropic activities of the alpha-MSH fragment analog, Ac-[Nle4,D-Phe7]-alpha-MSH4-9-NH2

Ac-[Nle4, D-Phe7]-alpha-MSH4-9-NH2 and Ac-[Nle4]-alpha-MSH4-9-NH2, fragment analogs of the tridecapeptide, alpha-melanocyte stimulating hormone (alpha-MSH, alpha-melanotropin), were synthesized. The potency and prolonged activity of the analogs were compared to alpha-MSH in several melanotropin bioassays. The D-Phe-containing hexapeptide was 10 times more active than alpha-MSH in stimulating melanoma tyrosinase activity. This analog was also 10-fold more potent than alpha-MSH in the lizard skin bioassay and about 10-fold less active in the frog skin bioassay. The melanotropic activity of Ac-[Nle4, D-Phe7]-alpha-MSH4-9-NH2 was considerably prolonged compared to alpha-MSH in each of the bioassays. These results demonstrate that the structural requirements for superpotency and prolonged activity of [Nle4, D-Phe7]-substituted analogs reside within this hexapeptide sequence.     

Characterization of inhibition of M2 ion channel activity by BL-1743, an inhibitor of influenza A virus.

The influenza A virus M2 integral membrane protein has ion channel activity that can be inhibited by the antiviral drug amantadine. Recently, a spirene-containing compound, BL-1743 (2-[3-azaspiro (5,5)undecanol]-2-imidazoline), that inhibits influenza virus growth was identified (S. Kurtz, G. Lao, K. M. Hahnenberger, C. Brooks, O. Gecha, K. Ingalls, K.-I. Numata, and M. Krystal, Antimicrob. Agents Chemother. 39:2204-2209, 1995). We have examined the ability of BL-1743 to inhibit the M2 ion channel when expressed in oocytes of Xenopus laevis. BL-1743 inhibition is complete as far as can be measured by electrophysiological methods and is reversible, with a reverse reaction rate constant of 4.0 x 10(-3) s(-1). In contrast, amantadine inhibition is irreversible within the time frame of the experiment. However, BL-1743 inhibition and amantadine inhibition have similar properties. The majority of isolated influenza viruses resistant to BL-1743 are also amantadine resistant. In addition, all known amino acid changes which result in amantadine resistance also confer BL-1743 resistance. However, one BL-1743-resistant virus isolated, designated M2-I35T, contained the change Ile-35-->Thr. This virus is >70-fold more resistant to BL-1743 and only 10-fold more resistant to amantadine than the wild-type virus. When the ion channel activity of M2-I35T was examined in oocytes, it was found that M2-I35T is BL-1743 resistant but is reversibly inhibited by amantadine. These findings suggest that these two drugs interact differently with the M2 protein transmembrane pore region.     

Novel 3-(2-adamantyl)pyrrolidines with potent activity against influenza A virus-identification of aminoadamantane derivatives bearing two pharmacophoric amine groups

The 3-(2-adamantyl)pyrrolidines 8a-g, 14 were synthesized and evaluated for activity against influenza A virus. The parent N-H compound 14 was several times more active than amantadine against H(2)N(2) and H(3)N(2) influenza A virus. The combined use of NMR spectroscopy and computational chemistry showed that the conformation around the pyrrolidine-adamantyl carbon-carbon bond is trans and the pyrrolidine heterocycle has an envelope conformation with C-2 out of the plane of the other ring atoms. N-Dialkylaminoethyl substitution of compound 14 resulted in the potent diamine analogues 8e,f,g. Interestingly, their lactam amine precursors were also active. Compounds 8e,f,g are the first adamantane derivatives, bearing two amine groups, reported to be active against influenza A virus.     

A facile 1,3-dipolar cycloaddition of azomethine ylides to 2-arylidene-1,3-indanediones: synthesis of dispiro-oxindolylpyrrolothiazoles and their antimycobacterial evaluation

A facile 1,3-dipolar cycloaddition of azomethine ylide generated in situ from the reaction of 1,3-thiazolane-4-carboxylic acid and isatin to 2-arylidene-1,3-indanediones furnished novel dispiro-oxindolylpyrrolothiazoles regio- and stereo-selectively in moderate to good yields (60-92%). In vitro antitubercular screening of 27 compounds against Mycobacterium tuberculosis H37Rv (MTB) disclosed that spiro[5.3']-5'-nitrooxindolespiro-[6.3″]-1H-inden-1″,3″(2H)-dione-7-(4-bromophenyl)tetrahydro-1H-pyrrolo[1,2-c][1,3]thiazole has the maximum potency with a minimum inhibitory concentration (MIC) of 1.4 μM against MTB, being 3.4 and 5.4 times more potent than ciprofloxacin and ethambutol, respectively.     

The influence of albumin on vitamin D metabolism in fetal chick osteoblast-like cells

Human pancreatic growth hormone releasing factor (1-29)-amide [hpGRF (1-29)-NH2] and the following analogs: [D-Tyr-1]-hpGRF(1-29)-NH2, [D-Ala-2]-hpGRF(1-29)-NH2, [D-Asp-3]-hpGRF(1-29)-NH2, and [N-Ac-Tyr-1]-hpGRF (1-29)-NH2 were synthesized using solid phase methodology and tested for their ability to stimulate growth hormone (GH) secretion in the rat and the pig in vivo. [D-Ala-2]-hpGRF (1-29)-NH2 was approximately 50 times more potent than the parent molecule in eliciting GH secretion in the rat. The other analogs were less active, but all were more potent than the 1-29 amide in the rat. [D-Tyr-1]-hpGRF(1-29)-NH2 was 10 times more potent, [D-Asp-3]-hpGRF(1-29)-NH2 7 times more potent, and the acetylated molecule approximately 12 times more potent than hpGRF(1-29)-NH2.     

Synthesis and pharmacological evaluation of (2-oxaadamant-1-yl)amines

The synthesis of several (2-oxaadamant-1-yl)amines is reported. They were evaluated as NMDA receptor antagonists and several of them were more active than amantadine, but none was more potent than memantine. None of the tested compounds displayed antiviral activity. Two of the derivatives showed a significant level of trypanocidal activity.