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Autofluorescent antimalarials by hybridization of artemisinin and coumarin: in vitro/in vivo studies and live-cell imaging

Lars Herrmann a, Maria Leidenberger b, Adrielle Sacramento de Morais c, Christina Mai a, Aysun Çapci a, Mariana da Cruz Borges Silva c, Fabian Plass de, Axel Kahnt de, Diogo R. M. Moreira *c, Barbara Kappes *b and Svetlana B. Tsogoeva *a
aOrganic Chemistry Chair I and Interdisciplinary Center for Molecular Materials (ICMM), Friedrich-Alexander-Universität Erlangen-Nürnberg, Nikolaus-Fiebiger-Straße 10, 91054 Erlangen, Germany. E-mail: svetlana.tsogoeva@fau.de
bInstitute of Medical Biotechnology, Friedrich-Alexander-Universität Erlangen-Nürnberg, Paul-Gordon-Straße 3, 91052 Erlangen, Germany. E-mail: barbara.kappes@fau.de
cInstituto Gonçalo Moniz, Fundação Oswaldo Cruz, Salvador 40296-710, Brazil. E-mail: diogo.magalhaes@fiocruz.br
dLeibniz Institute of Surface Engineering (IOM), Permoserstrasse 15, 04318 Leipzig, Germany
ePhysical Chemistry Chair I, Friedrich-Alexander-Universität Erlangen-Nürnberg, Egerlandstrasse 3, 91058 Erlangen, Germany

Received 17th July 2023 , Accepted 22nd October 2023

First published on 24th October 2023


Abstract

Malaria is one of our planet's most widespread and deadliest diseases, and there is an ever-consistent need for new and improved pharmaceuticals. Natural products have been an essential source of hit and lead compounds for drug discovery. Antimalarial drug artemisinin (ART), a highly effective natural product, is an enantiopure sesquiterpene lactone and occurs in Artemisia annua L. The development of improved antimalarial drugs, which are highly potent and at the same time inherently fluorescent is particularly favorable and highly desirable since they can be used for live-cell imaging, avoiding the requirement of the drug's linkage to an external fluorescent label. Herein, we present the first antimalarial autofluorescent artemisinin-coumarin hybrids with high fluorescence quantum yields of up to 0.94 and exhibiting excellent activity in vitro against CQ-resistant and multidrug-resistant P. falciparum strains (IC50 (Dd2) down to 0.5 nM; IC50 (K1) down to 0.3 nM) compared to reference drugs CQ (IC50 (Dd2) 165.3 nM; IC50 (K1) 302.8 nM) and artemisinin (IC50 (Dd2) 11.3 nM; IC50 (K1) 5.4 nM). Furthermore, a clear correlation between in vitro potency and in vivo efficacy of antimalarial autofluorescent hybrids was demonstrated. Moreover, deliberately designed autofluorescent artemisinin-coumarin hybrids, were not only able to overcome drug resistance, they were also of high value in investigating their mode of action via time-dependent imaging resolution in living P. falciparum-infected red blood cells.


Introduction

Nature is an excellent source of drugs or their precursors.1 Antimalarial drug artemisinin (Fig. 1a) is a prominent natural product. It is an enantiomerically pure sesquiterpene lactone found in Artemisia annua L. Its discoverer Youyou Tu was awarded the 2015 Nobel Prize in Physiology or Medicine.2,3 Artemisinin and its derivatives are of great interest for their vast range of biological properties.4,5 Target identification experiments have recently been performed, and putative inhibitory mechanisms of artemisinin-related compounds have been studied.6–8 Notably, one of the most powerful tools to address the mode of action of bioactive compounds is an investigation via fluorescence-based techniques.9,10 A fluorescent non-drug label is commonly introduced into a drug molecule to make it suitable for live-cell fluorescence tracking.11,12 In the past, this approach was also applied to artemisinins.13–16 Though fluorescent labeling enables localization imaging, the concept has significant drawbacks. The drug's polarity, solubility, cellular uptake, biological activity, and mode of action can significantly alter as the pristine drugs are heavily altered and enlarged.17,18 One possible pathway to circumnavigate drawbacks accompanied by fluorescent labeling is the design and application of inherently fluorescent bioactive hybrids, which are potent drug compounds and fluorophores at the same time.17,19 The efficacy of hybrid drugs and their potential to overcome even drug resistance has been widely proven.20–29 To our knowledge, no examples of inherently fluorescent antimalarial hybrid drugs have been reported so far. The aim of this work is, therefore, to combine two desired features in one artemisinin-based antimalarial hybrid drug: (i) high in vitro/in vivo activity and (ii) high intrinsic fluorescence. To design fluorescent artemisinin-based antimalarial hybrids, an additional bioactive species is required to gain improved antiplasmodial activity and to enable autofluorescence. We selected bioactive coumarins as prominent and suitable pharmacophores. While few examples of anticancer artemisinin-coumarin hybrids are known,30–32 no examples of antimalarial artemisinin-coumarin hybrid compounds and their in vitro/in vivo analyses and mode of action studies have been reported to date. Coumarin derivatives e.g., scopoletin, showing antimalarial properties, and other derivates naturally occur with artemisinin in Artemisia annua L.33–37 In addition to their antimalarial properties, coumarin derivatives exhibit activities against a broad scope of pathogens38–41 and are highly suitable for synthesizing intrinsically fluorescent hybrids since they can be tuned to be strongly fluorescent by binding to a triazole subunit.42,43
image file: d3sc03661h-f1.tif
Fig. 1 (a) Structures of established antimalarials chloroquine, artemisinin and artesunic acid and their in vitro activity against CQ-resistant and multidrug-resistant P. falciparum strains Dd2 and K1. (b) The first systematic comparison of antimalarial activities of differently linked monomeric and dimeric artemisinin-based hybrid model drugs using in vitro, in vivo and live-cell bioimaging methods.

Artemisinin-derived fluorescence tracers for localization imaging, especially in red blood cells infected with living parasites of P. falciparum, are rare44 and to the best of our knowledge, no time-dependent studies investigating possible changes in subcellular localization of such compounds in dependence on the incubation time have been performed. Herein, we present the first antimalarial autofluorescent artemisinin-coumarin hybrids and their biological in vitro studies against chloroquine-sensitive 3D7 and chloroquine-/multidrug-resistant Dd2 and K1 parasite strains of P. falciparum, and in vivo studies in P. berghei-infected mice (Fig. 1b). The use of triazoles as subunits in hybrid drugs is beneficial apart from their ability to induce fluorescence, as these heterocyclic subunits can easily be formed via click chemistry.45,46

We used the strong autofluorescence of new hybrid drugs (fluorescence quantum yields up to 0.94) to investigate the subcellular localization and to achieve a live-cell P. falciparum parasite imaging under unprecedented conditions that mimic treatment with artemisinin (ART) in humans. Next, the stability of the implemented linkers between the triazole and artemisinin subunit (non-cleavable (ether) vs. cleavable (ester) linkers) has been firmly taken into consideration as it is broadly accepted that artemisinins are relatively short-lived prodrugs primarily metabolized via heme-mediated degradation47,48 and the linker significantly affects the elimination half-lives.49,50

Results

Synthesis of artemisinin-coumarin hybrid compounds

In the past, our and other groups showed the high potential of dimeric artemisinin-based hybrids exhibiting strongly improved activities against malaria and other pathogens.8,51–55 In this study, we first intended to understand the differences in efficacy of dimeric vs. monomeric artemisinin-based hybrids concerning the applied linker moieties (cleavable vs. non-cleavable). For those studies, the monomeric artemisinin-coumarin hybrids 1 and 2 were synthesized via copper(I)-catalyzed azide-alkyne cycloaddition (CuAAC) click reactions (Scheme 1a). The monomeric artemisinin-alkyne precursors were obtained in good yields (7: 74%/9: 94%) via two diverse straightforward one-step procedures,29,56 whereas the coumarin azide 11 was commercially available (Scheme 1).
image file: d3sc03661h-s1.tif
Scheme 1 (a) Synthesis of non-cleavable linker-containing artemisinin-coumarin hybrids 1 and 3 derived from DHA. (b) Synthesis of cleavable linker-containing artemisinin-coumarin hybrids 2 and 4 derived from artesunic acid. (c) Synthesis of reference coumarin-triazoles 5 and 6 bearing no artemisinin unit. Reagents and conditions: (i) H3PW12O40·H2O (10 mol%), DCM, r.t., 6 h; (ii) coumarin-azide 11, CuSO4·5H2O (10 mol%), sodium ascorbate (20 mol%), CH2Cl2[thin space (1/6-em)]:[thin space (1/6-em)]H2O (1[thin space (1/6-em)]:[thin space (1/6-em)]1), r.t., o/n; (iii) BF3·Et2O, Et2O, N2, r.t., 24 h; (iv) coumarin-azide 11, [Cp*Ru(cod)Cl] (2 mol%), DMF, Ar., r.t., 24 h; (v) EDCI, DMAP, DCM, N2, 0 °C to r.t., o/n.; (vi) coumarin-azide 11, CuSO4·5H2O (20 mol%), sodium ascorbate (40 mol%), DMF, Ar., r.t., 1 h; (vii) EDCI, DMAP, DCM/acetonitrile (6/1), 0 °C to r.t., o/n.; (viii) CuSO4·5H2O (20 mol%), sodium ascorbate (40 mol%), DMF, Ar., r.t., 1 h.

Hybrid 1 was prepared in 45% yield via CuAAC between alkyne 7 and the coumarin azide 11 using CuSO4 and sodium ascorbate in a diphasic solvent system (DCM:H2O). On the other hand, a monophasic CuAAC reaction with CuSO4 and ascorbic acid in DMF between the artesunic acid-derived alkyne 9 and coumarin azide 11 was performed to gain hybrid 2 in 38% yield. Two dimeric-artemisinin precursors 8 and 10 with an internal alkyne were prepared to synthesize hybrids 3 and 4 (Scheme 1b) bearing two artemisinin units. The DHA (dihydroartemisinin) based dimeric alkyne precursor 8 was synthesized starting from a 1[thin space (1/6-em)]:[thin space (1/6-em)]1 mixture of C-10α-to C-10β-DHA via a newly developed etherification procedure using BF3·EtO2 (Scheme 1a). The product 8 with two C-10β-DHA units was isolated in a fair yield of 45% and the C-10β configuration was verified with 1H-NMR.57 Alkyne 10 derived from artesunic acid was obtained via a literature-known procedure in 69% yield (Scheme 1b).58 Since internal alkynes have to be activated for the cycloaddition towards hybrids 3 and 4 to take place, a Ru(II) based catalyst ([Cp*Ru(cod)Cl], 2 mol%) was applied instead of the copper-based systems used for the synthesis of hybrids 1 and 2. The hybrid compounds 3 and 4 were synthesized with an identical procedure in anhydrous DMF under argon and isolated in fair yields (3: 40%/4: 61%). The reference compounds 5 and 6 (Scheme 1c) bearing no artemisinin unit were prepared to have a comparison to the artemisinin-derived hybrids 1–4. The corresponding commercially available ether-/ester-bridged alkynes were coupled with coumarin azide 11via CuAAC in DMF to obtain both triazole-coumarins (5: 37% yield/6: 29% yield, Scheme 1c).

Fluorescence properties of the compounds

All compounds 1–6 bear a 7-hydroxo-cumarine fluorophore covalently attached over a triazole moiety which dominates the optical properties of the hybrids. The observed UV-vis absorption and fluorescence spectra (see Fig. S6–11), align with previous results for covalently functionalized 7-hydroxy-cumarine derivatives.59–61 Essentially and in line with previous literature reports59–61 for functionalized 7-hydroxy-cumarine derivatives, all investigated compounds show a red shift of around 15 nm in the long wavelength absorption maximum (see Table 1) compared to pristine 7-hydroxy-cumarine, which exhibits a long-wavelength absorption maximum around 330 nm.62,63 This red shift of the absorption goes hand in hand with a red shift of the fluorescence maximum observed for compounds 1–6 (between 410 and 435 nm – cf.Table 1) in respect to pristine 7-hydroxy-cumarine, which is reported to exhibit a fluorescence maximum around 380 nm in ethanol.64 The fluorescence lifetimes for the compounds 1–6 were determined by time correlated single photon counting (TCSPC) and values between 2.8 and 3.7 ns were received, which reflects a shortening of the fluorescence lifetime in respect to pristine 7-hydroxo-cumarine for which a fluorescence lifetime of around 5.7 ns in protic solvents was reported.65 Taking the observed fluorescence properties of the investigated artemisinin-based hybrid compounds 1–4 and the two reference compounds 5 and 6 into context, all compounds show high quantum yields Φfl of over 0.75 with 1 exhibiting the highest quantum yield with 0.94. These properties make the compounds highly suitable for fluorescence microscopy-based investigations in vitro and flow cytometry analysis.
Table 1 Absorption and emission properties of compounds 1–6 measured in MeOH
λ abs [nm] λ fl [nm] Φ fl τ fl [ns]
a Long-wavelength absorption maximum. b Fluorescence emission maximum; λex = 350 nm (λex = 320 nm for compound 1), slit 2/2 nm. c Fluorescence quantum yield relative to 9,10-diphenylanthracene in cyclohexane with a fluorescence quantum yield of 0.90.66
1 348 435 0.94 3.7
2 347 420 0.75 3.2
3 344/399 410 0.75 2.8
4 342/397 409 0.79 3.0
5 348 421 0.89 3.1
6 347 420 0.79 3.1


In vitro antiplasmodial activity of the hybrid drugs

The antiplasmodial activity of artemisinin-coumarin hybrids 1–4 was determined in vitro against chloroquine-sensitive 3D7 and chloroquine-/multidrug-resistant Dd2 and K1 parasite strains of P. falciparum (Table 2). In general, hybrids 1 and 3 with a non-cleavable ether-based (and shorter) linker between the triazole-coumarin and artemisinin moieties were more potent to inhibit parasite growth compared to their respective hybrid counterparts 2 and 4 with a cleavable ester-linked (and elongated) linker. Moreover, monomeric artemisinin hybrids 1 and 2 were less active than their dimeric artemisinin analogs with comparable linker structure 3/4 (Table 2). For the artemisinin-based hybrids 1–4, IC50 values varied from 0.5 nM for 3, the most potent derivative, to 91.7 nM for 2 when tested against the chloroquine-sensitive strain 3D7. The IC50 values decreased for their effect on parasite growth of the chloroquine-/multidrug-resistant strains Dd2 and K1, with K1 always exhibiting the lowest IC50 values. Notably, the artemisinin-free coumarin compounds (5/6) lacked any pronounced antiplasmodial activity, attested by IC50 values in the μM range. Both derivates 5/6 were slightly more active against the chloroquine-/multidrug-resistant strains (Table 2).
Table 2 In vitro antiplasmodial activity, selectivity index against P. falciparum and in vivo efficacy in P. berghei-infected mice of the hybrid compounds 1–4 and in vitro antiplasmodial activity of coumarin derivatives 5/6
a In vitro inhibitory activity against P. falciparum parasites. IC50 values are the mean ± S.E.M. (nM) and were determined 72 h after drug exposure. b IC50 value has been previously reported.29,67 c Treatment was given after 24 h post-infection once-a-day by subcutaneous injection for four consecutive days. d Parasitemia inhibition was determined in comparison to vehicle (untreated), determined 48 h after the last day of drug administration and values are mean ± standard deviation. e Animal survival was monitored for up to 30 days. Values are from one single experiment, using n = 5/group. f p < 0.05 (Log-rank and Mantel–Cox test) versus vehicle.
image file: d3sc03661h-u1.tif


Furthermore, a comparison of the IC50 values determined after 24 h versus 72 h of drug exposure, presented a comparable plasmodial killing rate for hybrids 1–4 at both incubation times (Table S1 and Fig. S1). The observed killing rate profile is typical for drugs denoted as fast-acting antimalarials, such as DHA, and starkly contrasts the slow-acting drug atovaquone employed as a threshold, which has a decreased potency to inhibit parasite growth for 24 h versus 72 h of drug exposure. Moreover, the presented hybrids achieve rapid parasite growth inhibition without inducing cell toxicity against mammalian cells indicated by high selectivity index (Table 2 and associated Table S1 and Fig. S2).

In vivo efficacy and stability of the hybrid drugs

The in vivo efficacy of hybrid drugs 1–4 was investigated in P. berghei-infected mice (Tables 2, S2 and Fig. S3). While for in vitro assays of antimalarial activity, DHA is employed,68–70 for in vivo assays in mice, artesunate (artesunic acid) is used.71 In line with the in vitro studies, the hybrids 1 and 3 with non-cleavable linkers were most efficacious in suppressing parasitemia and thus increasing animal survival. On the contrary, the hybrid 2 with cleavable linker presented, consistent with its relatively low in vitro potency, the most inferior efficacy among them. In contrast to its strong in vitro potency, cleavable derivative 4 showed a three-fold reduced efficacy than the non-cleavable hybrids 1 and 3. Overall a clear correlation between the in vitro potency and in vivo efficacy of hybrid compounds is observed, as hybrid 3 is the most potent in vitro and proved to be the most efficacious in vivo.

A dissimilarity in the antimalarial activity among endoperoxide drugs may be related to the stability and degradation of the endoperoxide bridge in red blood cells (RBC). To estimate endoperoxide degradation for the hybrid compounds, we implemented a broadly accepted assay method measuring the parasite-mediated drug degradation68–70 as outlined in Fig. 2 (panel a). Uninfected RBC (uRBC) were treated with 500 nM of DHA or hybrids 1–4, supernatants were harvested at indicated times (0.16, 6 and 24 h) and their antimalarial activities were determined against the 3D7 strain of P. falciparum. DHA (due to its fast-acting endoperoxide bridge) was employed as a drug susceptible to parasite-mediated degradation, while amodiaquine (AQ) (bearing no endoperoxide unit) was used as a drug not susceptible to heme-mediated reductive degradation.


image file: d3sc03661h-f2.tif
Fig. 2 Panel (a) shows the experimental design for determining the parasite-mediated drug degradation effect. Panel (b) shows the time-dependency concentration for the controls DHA (short-living) and AQ (long-lasting). Panel (c) shows the time-dependency concentration for the hybrids 1–4. Panel (d) compares the drug concentration remaining in the supernatants harvested after 24 h. For panels (b–d): values are the median ± standard error of the mean (S.E.M.) of three independent experiments (each concentration in duplicate). uRBC = uninfected red blood cells; DHA = dihydroartemisinin; AQ = amodiaquine. Full data is disclosed in Table S3.

As depicted in Fig. 2, panel b, the concentration of DHA decreased over time, whereas the concentration of AQ remained unaltered over time. These observations are consistent with previous literature since DHA is a short-living drug rapidly bioactivated and degraded by heme via endoperoxide reduction. In contrast, the long-lasting drug AQ is inert to a reductive degradation induced by heme.68,69 Having set up this, we evaluated the parasite-mediated degradation for hybrid compounds 1–4 (Fig. 2, panel c). As expected, the concentration of the hybrid compounds decreased over time, which is consistent with the notion that any endoperoxide drug is susceptible to parasite-mediated degradation caused by heme. However, as we can infer in Fig. 2, panel d, the drug concentration of all hybrid compounds was higher than DHA. A closer inspection of the equivalent drug concentrations after 24 h revealed that DHA had the lowest concentration among endoperoxide drugs, while compounds 2 and 4 with cleavable linker had the lesser concentration among all hybrid compounds. This contrasts with the non-cleavable hybrid compounds 1 and 3, which had the highest concentration among endoperoxide drugs, albeit their concentrations were lower than for AQ. Of note, while compound 2 with cleavable linker had the lowest in vitro potency (Table 2), it was surprisingly less susceptible to reductive degradation of the endoperoxide compared to DHA, which suggests that its low potency is not solely caused by parasite-mediated degradation of its endoperoxide moiety. Its products of degradations are possibly not as potent antimalarial agents as other endoperoxide drugs, such as DHA and artesunate.

Fluorescence imaging in living P. falciparum-infected red blood cells

The simplest and readily available hybrid drug 1 with non-cleavable linker, which exhibits an excellent in vitro activity (IC50 of 2.8 nM in P. f. 3D7), high stability, and strong autofluorescence (fluorescence quantum yield of 0.94) was used to assess the localization of the new hybrid compounds in living P. falciparum-infected red blood cells. Parasites of the 3D7 strain were incubated with 200 nM of 1 at 37 °C for 0.5, 2, 4, and 8 h, respectively, and costained with the nuclear tracker Syto 13 (see ESI for detailed information). The fluorescence of 1 was detected using the DAPI filter of an Eclipse Ti microscope for imaging. Uninfected cells were completely unlabeled by 1 (data not shown) under the applied conditions, indicating that accumulation of 1 depends on living parasites. The fluorescence in ring and early trophozoite stages of living parasites was weak and barely detectable. Still, it increased with maturation of the parasite resulting in a peak at the schizont stage.

After short time incubation of 0.5 h and 2 h, hybrid 1 exhibited a diffuse staining pattern in ring, trophozoite and schizont stages (Fig. 3) and did not colocalize with Syto 13 nuclear staining and only rarely and weakly stained the parasite digestive vacuole, visible as an electron dense area within the parasite.


image file: d3sc03661h-f3.tif
Fig. 3 Bright-field and fluorescence images of ring, trophozoite and schizont stages incubated with 1 for 30 min (rows 1–3) and 2 h (rows 4 and 5) before imaging. Syto 13 staining (blue) indicates the position of nuclei. Column A – bright field image, column B – 1 fluorescence (green), column C – Syto 13 fluorescence (blue); column D – merge of the fluorescence of 1 and Syto 13. White bars represent 5 μm.

Prolonged incubation periods of 4 h and 8 h, partly resulted in an accumulation of 1 in structures of potentially membranous origin (Fig. 4). However, only younger schizonts and no more mature stages could be observed after prolonged incubation times, indicating that 1 seems to abolish the transition to older schizont stages as these parasites were found to be expelled from their host cells. To investigate a possible localization of hybrid 1 in neutral lipid bodies (NLBs44), previously performed with an autofluorescent synthetic endoperoxide as an artemisinin model compound,72 co-staining with Nile Red (a dye that stains lipids and particularly neutral lipid bodies73) was performed (Fig. 4, column E). NLBs are visible as intensely stained spot-like structures adjacent to the food vacuole (Fig. 4, column F, white arrows). In contrast to the rapid accumulation of a fluorescent synthetic endoperoxide in NLBs as described previously,44 our results do not suggest a colocalization with NLBs (Fig. 4). Instead, specific Nile Red-stained membranous structures, not identical to NLBs, colocalize with the 1 staining as indicated by the yellow color of the composite. Staining of a similar membranous structure by Nile Red was also previously observed73 and represents most likely parts of an inner parasitic membrane network. However, compound 1 was also found to stain merozoite membranes (Fig. 4, lane 4).


image file: d3sc03661h-f4.tif
Fig. 4 Bright-field and fluorescence images of schizonts incubated with 1 for 4 h (rows 1 and 2) and 8 h (rows 3 and 4). Syto 13 staining (blue) indicates position of nuclei. Column A – bright field image, column B – 1 fluorescence (green), column C – Syto 13 fluorescence (blue); column D – merge I of the fluorescence of 1 and Syto 13; column E − Nile Red fluorescence: Nile Red stains neutral lipid, in particular neutral lipid bodies; column F – merge II of the fluorescence of 1, Syto 13 and Nile Red; White bars represent 5 μm. The white arrows indicate the position of NLBs.

Although the cellular localization of hybrid 1 in P. falciparum was precisely profiled at clinically relevant nanomolar concentrations by microscopy, it remained uncertain if the lipophilicity of the reported hybrids as well as their ability to enter the cells and become bioavailable inside parasites is comparable to DHA. To interrogate this, we profiled the drug uptake of hybrids and DHA in the parasites by flow cytometry and fluorescence in a microplate reader (Fig. S4 and S5 and associated discussion). The estimated concentration of all hybrids 1–4 inside infected RBC (iRBC) was similar to artemisinin-free coumarin compounds 5/6 and no significant differences were observed among the hybrids. Moreover, hybrids 1 and 2 were significantly more incorporated by iRBC than uRBC, which depends on drug concentration and the time of drug exposure. Importantly, the uptake of hybrid 1 in iRBC and uRBC was significantly reduced when these cells were previously exposed to DHA. A similar finding was documented in prior literature.14

Discussion

Further advances in the combination of high in vitro/in vivo activity and high intrinsic fluorescence in one hybrid drug will contribute to the progress in the drug discovery due to the possibility of gaining insights into the mode of action of the hybrid drugs. The deliberate design of monomeric and dimeric artemisinin-based coumarin hybrids employing cleavable and non-cleavable linkers enabled a step forward toward the formulation of SAR (structure–activity relationship) and the understanding of the mode of action of artemisinin-based compounds. We demonstrated a straightforward two-step synthetic pathway via a key metal-catalyzed click chemistry step to obtain complex artemisinin-coumarin hybrids from commercially available precursors.

The ether-linked artemisinin hybrids 1 and 3 surpass the in vitro potency of artemisinin-based drugs DHA, artemisinin and artesunic acid up to 16-fold and exhibit at very least twice the in vivo efficacy of artesunate. The same phenotype-based activity is not reproduced by ester linked hybrids 2 and 4. Interestingly, the studies revealed that the antiplasmodial activity and cytotoxicity of the hybrids in mammalian cells can be clustered according to the chemical structure of the linker. Hybrids containing a non-cleavable ether linker are more potent antiplasmodial agents and more cytotoxic for mammalian cells than hybrids with a cleavable ester linker. Regarding the importance of one or two endoperoxide units in the composition of hybrids, we concluded from the standard chemosensitivity assays (IC50 values) that a hybrid containing two endoperoxide moieties is more potent than a monomeric hybrid of identical linking type. However, a non-cleavable linked hybrid 1 containing only one endoperoxide warhead can equalize (for P. f. 3D7) or even surpass (for P. f. Dd2) the efficacy of the cleavable linked dimeric hybrid 4. The most potent monomeric hybrid 1 and dimeric hybrid 3 were less prone to undergo parasite-mediated drug degradation. Multiple analyses shed light on the aspect that an enhancement in potency for endoperoxide drugs is achieved when a long-lasting property (i.e., a stronger chemical stability to resist a heme-mediated degradation than DHA has) is achived.69,70 This property can be profoundly tuned by the used linker and the effects were found to be pronounced for hybrids carrying two endoperoxide units in the reported library. Our SAR model dictates that if two endoperoxide moieties are combined using a non-cleavable chemical linker, as for the hybrid 3, a strong and efficacious antimalarial drug with a 10-fold increase in stability and a 7-fold increase in activity compared to DHA is observed.

As previously mentioned, the high intrinsic fluorescence of hybrid 1 (Φfl = 0.94, Table 1) combined with its high in vitro and in vivo potency and efficacy made it most suitable for live-cell imaging, which enabled a precise profiling of the cellular localization of 1 in living P. falciparum parasites by fluorescence microscopy at low nanomolar drug concentrations, reproducing the therapy in humans. The timing of 1-staining and co-staining procedures both revealed a diffusion of 1 over the cytoplasm of parasite cells for short incubation times (0.5 h to 2 h). Even after prolonged incubation times (4 h to 8 h), 1 was not preferentially localized inside the parasite's digestive vacuole, consistent with a precedent report.14 Moreover, we found membranous structures stained by 1 in both mature parasite stages and merozoites. In contrast, previously a synthetic fluorescent artemisinin model compound was found to accumulate in neutral lipid bodies (NLB) at micromolar concentrations.44

As hybrids possess chemical functionalization, this may lead to alterations in their uptake and cellular localization in comparison to artemisinins used in patients, like DHA and artesunate. We found that all compounds 1–6 can become bioavailable for uptake in RBC, as expected to occur in any small molecule able to cross lipid membranes by passive permeability. However, hybrids 1–4 were preferentially accumulated in parasites than host cells. This is consistent with the visualization of hybrid 1 inspected by microscopy. Moreover, we found that the uptake of hybrid 1 in RBC was mitigated in the presence of DHA. Meanwhile, this is not surprising, given that both are endoperoxides derived from the same 1,2,4-trioxane ring and no alteration in the trioxane ring was performed to design hybrids, this supports the reliable and robustness of autofluorescent hybrids for studying artemisinin's cellular localization. Based on these findings, we argue that the cellular localization of 1 likely reflects the artemisinins used in patients. Finally, our data indicates that a stronger potency and efficacy for hybrid 1versus DHA/artesunate is achieved because of its stability to overcome parasite-mediated drug degradation. These data justify further studies in artemisinin-resistant parasites in the future.

Conclusions

We have designed and synthesized first autofluorescent antimalarial artemisinin-coumarin hybrids 1–4, which combine two desired features in one drug compound: high in vitro/in vivo activity and high intrinsic fluorescence suitable for live-cell imaging. These new hybrids, with non-cleavable (ether) and cleavable (ester) linkers and featuring one or two endoperoxide moieties were obtained via metal-catalyzed click chemistry from readily available alkyne and azide precursors. The hybrids exhibit excellent antimalarial activity in vitro against CQ-resistant and multidrug-resistant P. falciparum strains (IC50(Dd2) down to 0.5 nM; IC50(K1) down to 0.33 nM) compared to reference drugs CQ (IC50(Dd2) = 165.3 nM; IC50(K1) = 302.8 nM) and artemisinin (IC50(Dd2) = 11.3 nM; IC50(K1) = 5.4 nM). A combination of photophysical analysis, microscopy, and flow cytometry have revealed the high suitability of hybrids for real-time imaging in living parasite cells at clinically relevant low drug concentration when the parasite-mediated degradation of artemisinins is circumvented. Furthermore, it was found that hybrids featuring two endoperoxide units have improved in vitro/in vivo antimalarial activities compared to hybrids with only one endoperoxide moiety. Notably, a metabolically resistant non-cleavable chemical linker should be employed (e.g., hybrid compound 3) to achieve the best potency. In general, our findings should provide a valuable basis for autofluorescent artemisinin-based antimalarial drug design suitable for cellular uptake visualization and fluorescence imaging in living P. falciparum-infected red blood cells. Our results should also encourage further mechanistic studies and be a stepping stone toward overcoming multidrug resistance.

Ethical statement

Experiments were conducted in 2019–2022 in accordance with the recommendations of ethical issues guidelines and were approved (protocol 020/2018) by the local Animal Ethics Committee at Fiocruz Bahia (IGM,Salvador, Brazil).

Data availability

All data are available from the authors upon reasonable request.

Author contributions

L. H., C. M. and A. Ç. carried out all synthetic work and conducted the click reactions. M. L. performed the in vitro and live-cell imaging studies under the supervision of B. K., A. S. M. and M. C. B. S. performed the in vivo studies under the supervision of D. R. M. M., F. P. and A. K. carried out the photophysical measurements. D. R. M. M., B. K. and S. B. T. designed and supervised the experimental outline of the corresponding studies. L. H., D. R. M. M., B. K., S. B. T. wrote the manuscript with input from all authors. S. B. T. conceived and directed the research.

Conflicts of interest

There are no conflicts to declare.

Acknowledgements

S. B. T. gratefully acknowledges the financial support from the Deutsche Forschungsgemeinschaft (DFG, Grant TS 87/23-1) and the Volkswagen Foundation (Project: Innovative Approaches to Drug Development). D. R. M. M. acknowledges CNPq (Brazil, grant 440227/2022-4) and Fapesb (Brazil, grant PIE0009/2022).

References

  1. D. J. Newman and G. M. Cragg, Natural Products as Sources of New Drugs from 1981 to 2014, J. Nat. Prod., 2016, 79, 629–661 CrossRef CAS PubMed.
  2. X.-Z. Su and L. H. Miller, The discovery of artemisinin and the Nobel Prize in Physiology or Medicine, Sci. China: Life Sci., 2015, 58, 1175–1179 CrossRef PubMed.
  3. Y. Tu, Artemisinin—A Gift from Traditional Chinese Medicine to the World (Nobel Lecture), Angew. Chem., Int. Ed., 2016, 55, 10210–10226 CrossRef CAS PubMed.
  4. T. Efferth, H. Dunstan, A. Sauerbrey, H. Miyachi and C. R. Chitambar, The anti-malarial artesunate is also active against cancer, Int. J. Oncol., 2001, 18, 767–773 CAS.
  5. R. D. Slack, A. M. Jacobine and G. H. Posner, Antimalarial peroxides: advances in drug discovery and design, MedChemComm, 2012, 3, 281–297 RSC.
  6. J. Wang, J. Zhang, Y. Shi, C. Xu, C. Zhang, Y. K. Wong, Y. M. Lee, S. Krishna, Y. He, T. K. Lim, W. Sim, Z. C. Hua, H. M. Shen and Q. Lin, Mechanistic Investigation of the Specific Anticancer Property of Artemisinin and Its Combination with Aminolevulinic Acid for Enhanced Anticolorectal Cancer Activity, ACS Cent. Sci., 2017, 3, 743–750 CrossRef CAS PubMed.
  7. Y. K. Wong, C. Xu, K. A. Kalesh, Y. He, Q. Lin, W. S. F. Wong, H.-M. Shen and J. Wang, Artemisinin as an anticancer drug: Recent advances in target profiling and mechanisms of action, Med. Res. Rev., 2017, 37, 1492–1517 CrossRef CAS PubMed.
  8. T. Fröhlich, F. Hahn, L. Belmudes, M. Leidenberger, O. Friedrich, B. Kappes, Y. Couté, M. Marschall and S. B. Tsogoeva, Synthesis of Artemisinin-Derived Dimers, Trimers and Dendrimers: Investigation of Their Antimalarial and Antiviral Activities Including Putative Mechanisms of Action, Chem.–Eur. J., 2018, 24, 8103–8113 CrossRef PubMed.
  9. B. Golankiewicz, T. Ostrowski, T. Goslinski, P. Januszczyk, J. Zeidler, D. Baranowski and E. de Clercq, Fluorescent Tricyclic Analogues of Acyclovir and Ganciclovir. A Structure−Antiviral Activity Study, J. Med. Chem., 2001, 44, 4284–4287 CrossRef CAS PubMed.
  10. J. Broichhagen and N. Kilian, Chemical Biology Tools To Investigate Malaria Parasites, ChemBioChem, 2021, 22, 2219–2236 CrossRef CAS PubMed.
  11. J. B. Grimm and L. D. Lavis, Caveat fluorophore: an insiders' guide to small-molecule fluorescent labels, Nat. Methods, 2022, 19, 149–158 CrossRef CAS PubMed.
  12. T. Terai and T. Nagano, Small-molecule fluorophores and fluorescent probes for bioimaging, Pflug. Arch. Eur. J. Physiol., 2013, 465, 347–359 CrossRef CAS PubMed.
  13. J. Wang, C. J. Zhang, W. N. Chia, C. C. Loh, Z. Li, Y. M. Lee, Y. He, L. X. Yuan, T. K. Lim, M. Liu, C. X. Liew, Y. Q. Lee, J. Zhang, N. Lu, C. T. Lim, Z. C. Hua, B. Liu, H. M. Shen, K. S. Tan and Q. Lin, Haem-activated promiscuous targeting of artemisinin in Plasmodium falciparum, Nat. Commun., 2015, 6, 10111–10122 CrossRef CAS PubMed.
  14. A. Sissoko, P. Vásquez-Ocmín, A. Maciuk, D. Barbieri, G. Neveu, L. Rondepierre, R. Grougnet, P. Leproux, M. Blaud, K. Hammad, S. Michel, C. Lavazec, J. Clain, S. Houzé and R. Duval, A Chemically Stable Fluorescent Mimic of Dihydroartemisinin, Artemether, and Arteether with Conserved Bioactivity and Specificity Shows High Pharmacological Relevance to the Antimalarial Drugs, ACS Infect. Dis., 2020, 6, 1532–1547 CrossRef CAS PubMed.
  15. H. M. Ismail, V. E. Barton, M. Panchana, S. Charoensutthivarakul, G. A. Biagini, S. A. Ward and P. M. O'Neill, A Click Chemistry-Based Proteomic Approach Reveals that 1,2,4-Trioxolane and Artemisinin Antimalarials Share a Common Protein Alkylation Profile, Angew. Chem., Int. Ed., 2016, 55, 6401–6405 CrossRef CAS PubMed.
  16. U. Eckstein-Ludwig, R. J. Webb, I. D. A. van Goethem, J. M. East, A. G. Lee, M. Kimura, P. M. O'Neill, P. G. Bray, S. A. Ward and S. Krishna, Artemisinins target the SERCA of Plasmodium falciparum, Nature, 2003, 424, 957–961 CrossRef CAS PubMed.
  17. F. E. Held, A. A. Guryev, T. Fröhlich, F. Hampel, A. Kahnt, C. Hutterer, M. Steingruber, H. Bahsi, C. von Bojničić-Kninski, D. S. Mattes, T. C. Foertsch, A. Nesterov-Mueller, M. Marschall and S. B. Tsogoeva, Facile access to potent antiviral quinazoline heterocycles with fluorescence properties via merging metal-free domino reactions, Nat. Commun., 2017, 8, 15071–15080 CrossRef PubMed.
  18. M. M. Lee, Z. Gao and B. R. Peterson, Synthesis of a Fluorescent Analogue of Paclitaxel That Selectively Binds Microtubules and Sensitively Detects Efflux by P-Glycoprotein, Angew. Chem., Int. Ed., 2017, 56, 6927–6931 CrossRef CAS PubMed.
  19. L. Herrmann, F. Hahn, B. W. Grau, M. Wild, A. Niesar, C. Wangen, E. Kataev, M. Marschall and S. B. Tsogoeva, Autofluorescent Artemisinin-Benzimidazole Hybrids via Organo-Click Reaction: Study of Antiviral Properties and Mode of Action in Live Cells, Chem. - Eur. J., 2023, e202301194 CrossRef CAS PubMed.
  20. L. F. Tietze, H. P. Bell and S. Chandrasekhar, Natural Product Hybrids as New Leads for Drug Discovery, Angew. Chem., Int. Ed., 2003, 42, 3996–4028 CrossRef CAS PubMed.
  21. S. B. Tsogoeva, Recent Progress in the Development of Synthetic Hybrids of Natural or Unnatural Bioactive Compounds for Medicinal Chemistry, Mini-Rev. Med. Chem., 2010, 10, 773–793 CrossRef CAS PubMed.
  22. B. Sharma, P. Singh, A. K. Singh and S. K. Awasthi, Advancement of chimeric hybrid drugs to cure malaria infection: An overview with special emphasis on endoperoxide pharmacophores, Eur. J. Med. Chem., 2021, 219, 113408–113444 CrossRef CAS PubMed.
  23. H. M. Sampath Kumar, L. Herrmann and S. B. Tsogoeva, Structural hybridization as a facile approach to new drug candidates, Bioorg. Med. Chem. Lett., 2020, 30, 127514–127528 CrossRef CAS PubMed.
  24. G. Mehta and V. Singh, Hybrid systems through natural product leads: An approach towards new molecular entities, Chem. Soc. Rev., 2002, 31, 324–334 RSC.
  25. J. J. Walsh, D. Coughlan, N. Heneghan, C. Gaynor and A. Bell, A novel artemisinin-quinine hybrid with potent antimalarial activity, Bioorg. Med. Chem., 2007, 17, 3599–3602 CrossRef CAS PubMed.
  26. N. Wang, K. J. Wicht, E. Shaban, T. A. Ngoc, M. Q. Wang, I. Hayashi, M. I. Hossain, Y. Takemasa, M. Kaiser, I. E. El Sayed, T. J. Egan and T. Inokuchi, Synthesis and evaluation of artesunate-indoloquinoline hybrids as antimalarial drug candidates, MedChemComm, 2014, 5, 927–931 RSC.
  27. T. Fröhlich, C. Reiter, M. M. Ibrahim, J. Beutel, C. Hutterer, I. Zeitträger, H. Bahsi, M. Leidenberger, O. Friedrich, B. Kappes, T. Efferth, M. Marschall and S. B. Tsogoeva, Synthesis of Novel Hybrids of Quinazoline and Artemisinin with High Activities against Plasmodium falciparum, Human Cytomegalovirus, and Leukemia Cells, ACS Omega, 2017, 2, 2422–2431 CrossRef PubMed.
  28. T. Frohlich, C. Reiter, M. E. M. Saeed, C. Hutterer, F. Hahn, M. Leidenberger, O. Friedrich, B. Kappes, M. Marschall, T. Efferth and S. B. Tsogoeva, Synthesis of Thymoquinone-Artemisinin Hybrids: New Potent Antileukemia, Antiviral, and Antimalarial Agents, ACS Med. Chem. Lett., 2018, 9, 534–539 CrossRef PubMed.
  29. A. Çapcı, M. Lorion, H. Wang, N. Simon, M. Leidenberger, M. Borges Silva, D. Moreira, Y. Zhu, Y. Meng, J. Y. Chen, Y. Lee, O. Friedrich, B. Kappes, J. Wang, L. Ackermann and S. B. Tsogoeva, Artemisinin-(Iso)quinoline Hybrids by C-H Activation and Click Chemistry: Combating Multidrug-Resistant Malaria, Angew. Chem., Int. Ed., 2019, 58, 13066–13079 CrossRef PubMed.
  30. H. Yu, Z. Hou, Y. Tian, Y. Mou and C. Guo, Design, synthesis, cytotoxicity and mechanism of novel dihydroartemisinin-coumarin hybrids as potential anti-cancer agents, Eur. J. Med. Chem., 2018, 151, 434–449 CrossRef CAS PubMed.
  31. C. Zippilli, S. Filippi, S. Cesarini, B. M. Bizzarri, P. Conigliaro, E. De Marchi, L. Botta and R. Saladino, Synthesis of Artesunic Acid–Coumarin Hybrids as Potential Antimelanoma Agents, ACS Med. Chem. Lett., 2023, 14, 599–605 CrossRef CAS PubMed.
  32. Y. Tian, Z. Liang, H. Xu, Y. Mou and C. Guo, Design, Synthesis and Cytotoxicity of Novel Dihydroartemisinin-Coumarin Hybrids via Click Chemistry, Molecules, 2016, 21, 758 CrossRef PubMed.
  33. E.-J. Seo, M. Saeed, B. Y. Law, A. G. Wu, O. Kadioglu, H. J. Greten and T. Efferth, Pharmacogenomics of Scopoletin in Tumor Cells, Molecules, 2016, 21, 496–518 CrossRef PubMed.
  34. P. J. Weathers, M. Towler, A. Hassanali, P. Lutgen and P. O. Engeu, Dried-leaf Artemisia annua: A practical malaria therapeutic for developing countries?, World J. Pharmacol., 2014, 3, 39–55 CrossRef PubMed.
  35. A. Malik, A. Kushnoor, V. Saini, S. Singhal, S. Kumar and Y. C. Yadav, In vitro antioxidant properties of Scopoletin, J. Chem. Pharm. Res., 2011, 3, 659–665 CAS.
  36. K.-M. Li, X. Dong, Y.-N. Ma, Z.-H. Wu, Y.-M. Yan and Y.-X. Cheng, Antifungal coumarins and lignans from Artemisia annua, Fitoterapia, 2019, 134, 323–328 CrossRef CAS PubMed.
  37. D. L. Klayman, Artemisinin: an Antimalarial Drug from China, Science, 1985, 228, 1049–1055 CrossRef CAS PubMed.
  38. G. J. B. Gnonlonfin, A. Sanni and L. Brimer, Review Scopoletin – A Coumarin Phytoalexin with Medicinal Properties, Crit. Rev. Plant Sci., 2012, 31, 47–56 CrossRef CAS.
  39. M. Lončarić, D. Gašo-Sokač, S. Jokić and M. Molnar, Recent Advances in the Synthesis of Coumarin Derivatives from Different Starting Materials, Biomolecules, 2020, 10, 151 CrossRef PubMed.
  40. R. H. Vekariya and H. D. Patel, Recent Advances in the Synthesis of Coumarin Derivatives via Knoevenagel Condensation: A Review, Synth. Commun., 2014, 44, 2756–2788 CrossRef CAS.
  41. A. Bouhaoui, M. Eddahmi, M. Dib, M. Khouili, A. Aires, M. Catto and L. Bouissane, Synthesis and Biological Properties of Coumarin Derivatives. A Review, ChemistrySelect, 2021, 6, 5848–5870 CrossRef CAS.
  42. J. A. Key, S. Koh, Q. K. Timerghazin, A. Brown and C. W. Cairo, Photophysical characterization of triazole-substituted coumarin fluorophores, Dyes Pigm., 2009, 82, 196–203 CrossRef CAS.
  43. K. Sivakumar, F. Xie, B. M. Cash, S. Long, H. N. Barnhill and Q. Wang, A Fluorogenic 1,3-Dipolar Cycloaddition Reaction of 3-Azidocoumarins and Acetylenes, Org. Lett., 2004, 6, 4603–4606 CrossRef CAS PubMed.
  44. C. L. Hartwig, A. S. Rosenthal, J. D'Angelo, C. E. Griffin, G. H. Posner and R. A. Cooper, Accumulation of artemisinin trioxane derivatives within neutral lipids of Plasmodium falciparum malaria parasites is endoperoxide-dependent, Biochem. Pharmacol., 2009, 77, 322–336 CrossRef CAS PubMed.
  45. H. C. Kolb, M. G. Finn and K. B. Sharpless, Click Chemistry: Diverse Chemical Function from a Few Good Reactions, Angew. Chem., Int. Ed., 2001, 40, 2004–2021 CrossRef CAS PubMed.
  46. L. Zhang, X. Chen, P. Xue, H. H. Y. Sun, I. D. Williams, K. B. Sharpless, V. V. Fokin and G. Jia, Ruthenium-Catalyzed Cycloaddition of Alkynes and Organic Azides, J. Am. Chem. Soc., 2005, 127, 15998–15999 CrossRef CAS PubMed.
  47. C. R. Harding, S. M. Sidik, B. Petrova, N. F. Gnädig, J. Okombo, A. L. Herneisen, K. E. Ward, B. M. Markus, E. A. Boydston, D. A. Fidock and S. Lourido, Genetic screens reveal a central role for heme metabolism in artemisinin susceptibility, Nat. Commun., 2020, 11, 4813–4830 CrossRef CAS PubMed.
  48. L. E. Heller, E. Goggins and P. D. Roepe, Dihydroartemisinin–Ferriprotoporphyrin IX Adduct Abundance in Plasmodium falciparum Malarial Parasites and the Relationship to Emerging Artemisinin Resistance, Biochemistry, 2018, 57, 6935–6945 CrossRef CAS PubMed.
  49. B. R. Blank, R. L. Gonciarz, P. Talukder, J. Gut, J. Legac, P. J. Rosenthal and A. R. Renslo, Antimalarial Trioxolanes with Superior Drug-Like Properties and In Vivo Efficacy, ACS Infect. Dis., 2020, 6, 1827–1835 CrossRef CAS PubMed.
  50. F. Bousejra-El Garah, M. H.-L. Wong, R. K. Amewu, S. Muangnoicharoen, J. L. Maggs, J.-L. Stigliani, B. K. Park, J. Chadwick, S. A. Ward and P. M. O'Neill, Comparison of the Reactivity of Antimalarial 1,2,4,5-Tetraoxanes with 1,2,4-Trioxolanes in the Presence of Ferrous Iron Salts, Heme, and Ferrous Iron Salts/Phosphatidylcholine, J. Med. Chem., 2011, 54, 6443–6455 CrossRef CAS PubMed.
  51. A. Çapcı, L. Herrmann, H. M. Sampath Kumar, T. Fröhlich and S. B. Tsogoeva, Artemisinin-derived dimers from a chemical perspective, Med. Res. Rev., 2021, 41, 2927–2970 CrossRef PubMed.
  52. B. Zhang, Artemisinin-derived dimers as potential anticancer agents: Current developments, action mechanisms, and structure–activity relationships, Arch. Pharm., 2020, 353, 1900240–19000251 CrossRef CAS PubMed.
  53. V. Tuan Kien, L. Huy Binh, P. Hai Phong, D. Thi Hien, N. Thi Thuy My, N. Hai Nam, D. Thi Thao, M. Baltas and T. Khac Vua, Novel Artemisinin-Derived Dimers: Synthesis and Evaluation of Anti-cancer Activities, Lett. Drug Des. Discovery, 2017, 14, 102–111 CrossRef.
  54. A. N. Pearce, M. Kaiser and B. R. Copp, Synthesis and antimalarial evaluation of artesunate-polyamine and trioxolane-polyamine conjugates, Eur. J. Med. Chem., 2017, 140, 595–603 CrossRef CAS PubMed.
  55. T. Fröhlich, A. Çapcı, C. Reiter and S. B. Tsogoeva, Artemisinin-Derived Dimers: Potent Antimalarial and Anticancer Agents, J. Med. Chem., 2016, 59, 7360–7388 CrossRef PubMed.
  56. P. P. Bora, N. Baruah, G. Bez and N. C. Barua, New Method for the Synthesis of Ether Derivatives of Artemisinin, Synth. Commun., 2012, 42, 1218–1225 CrossRef CAS.
  57. A. Brossi, B. Venugopalan, L. Dominguez Gerpe, H. J. C. Yeh, J. L. Flippen-Anderson, P. Buchs, X. D. Luo, W. Milhous and W. Peters, Arteether, a new antimalarial drug: synthesis and antimalarial properties, J. Med. Chem., 1988, 31, 645–650 CrossRef CAS PubMed.
  58. A. Çapcı, C. Reiter, E. J. Seo, L. Gruber, F. Hahn, M. Leidenberger, V. Klein, F. Hampel, O. Friedrich, M. Marschall, B. Kappes, T. Efferth and S. B. Tsogoeva, Access to new highly potent antileukemia, antiviral and antimalarial agents via hybridization of natural products (homo)egonol, thymoquinone and artemisinin, Bioorg. Med. Chem., 2018, 26, 3610–3618 CrossRef PubMed.
  59. J. R. Heldt, J. Heldt, M. Stoń and H. A. Diehl, Photophysical properties of 4-alkyl- and 7-alkoxycoumarin derivatives. Absorption and emission spectra, fluorescence quantum yield and decay time, Spectrochim. Acta, Part A, 1995, 51, 1549–1563 CrossRef.
  60. M. Chatterjee, S. Chatterjee, M. Basu Roy, S. Ghosh, P. Bandyopadhyay and P. K. Bharadwaj, Photophysical properties of tris-methoxycoumarin derivative of a cryptand, J. Lumin., 2002, 99, 175–183 CrossRef CAS.
  61. W.-C. Sun, K. R. Gee and R. P. Haugland, Synthesis of novel fluorinated coumarins: Excellent UV-light excitable fluorescent dyes, Bioorg. Med. Chem. Lett., 1998, 8, 3107–3110 CrossRef CAS PubMed.
  62. K. Sen and P. Bagchi, Studies on the Ultraviolet Absorption Spectra of Coumarins and Chromones. II. Hydroxy Derivatives1, J. Org. Chem., 1959, 24, 316–319 CrossRef CAS.
  63. M. Hoshiyama, K. Kubo, T. Igarashi and T. Sakurai, Complexation and proton dissociation behavior of 7-hydroxy-4-methylcoumarin and related compounds in the presence of β-cyclodextrin, J. Photochem. Photobiol., A, 2001, 138, 227–233 CrossRef CAS.
  64. J. E. Fortier, P. Even-Hernandez, F. Baros, S. Poulain, N. Martinet, M. Donner, C. Gouyette and M. C. Carré, The synthesis, photophysical properties and energy transfer of a coumarin-based bichromophoric compound, Dyes Pigm., 2009, 80, 115–120 CrossRef CAS.
  65. T. Moriya, Excited-state Reactions of Coumarins in Aqueous Solutions. I. The Phototautomerization of 7-Hydroxycoumarin and Its Derivative, Bull. Chem. Soc. Jpn., 1983, 56, 6–14 CrossRef CAS.
  66. S. Hamai and F. Hirayama, Actinometric determination of absolute fluorescence quantum yields, J. Phys. Chem., 1983, 87, 83–89 CrossRef CAS.
  67. H. C. Quadros, A. Çapcı, L. Herrmann, S. D'Alessandro, D. Fontinha, R. Azevedo, W. Villarreal, N. Basilico, M. Prudêncio, S. B. Tsogoeva and D. R. M. Moreira, Studies of Potency and Efficacy of an Optimized Artemisinin-Quinoline Hybrid against Multiple Stages of the Plasmodium Life Cycle, Pharmaceuticals, 2021, 14, 1129–1146 CrossRef CAS PubMed.
  68. Y. Du, C. Giannangelo, W. He, J. Shami Gerald, W. Zhou, T. Yang, J. Creek Darren, C. Dogovski, X. Li and L. Tilley, Dimeric Artesunate Glycerophosphocholine Conjugate Nano-Assemblies as Slow-Release Antimalarials to Overcome Kelch 13 Mutant Artemisinin Resistance, Antimicrob. Agents Chemother., 2022, 66, e02065-21 CrossRef PubMed.
  69. T. Yang, C. Xie Stanley, P. Cao, C. Giannangelo, J. McCaw, J. Creek Darren, A. Charman Susan, N. Klonis and L. Tilley, Comparison of the Exposure Time Dependence of the Activities of Synthetic Ozonide Antimalarials and Dihydroartemisinin against K13 Wild-Type and Mutant Plasmodium falciparum Strains, Antimicrob. Agents Chemother., 2016, 60, 4501–4510 CrossRef CAS PubMed.
  70. C. Giannangelo, L. Stingelin, T. Yang, L. Tilley, A. Charman Susan and J. Creek Darren, Parasite-Mediated Degradation of Synthetic Ozonide Antimalarials Impacts In Vitro Antimalarial Activity, Antimicrob. Agents Chemother., 2018, 62, e01566-17 CrossRef PubMed.
  71. F. R. Radohery Georges, A. Walz, C. Gumpp, H. Cherkaoui-Rbati Mohammed, N. Gobeau, J. Gower, P. Davenport Miles, M. Rottmann, S. McCarthy James, J. Möhrle Jörg, M. Rebelo, C. Demarta-Gatsi and S. Khoury David, Parasite Viability as a Measure of In Vivo Drug Activity in Preclinical and Early Clinical Antimalarial Drug Assessment, Antimicrob. Agents Chemother., 2022, 66, e00114–e00122 Search PubMed.
  72. G. H. Posner, C. H. Oh, L. Gerena and W. K. Milhous, Extraordinarily potent antimalarial compounds: new, structurally simple, easily synthesized, tricyclic 1,2,4-trioxanes, J. Med. Chem., 1992, 35, 2459–2467 CrossRef CAS PubMed.
  73. K. E. Jackson, N. Klonis, D. J. P. Ferguson, A. Adisa, C. Dogovski and L. Tilley, Food vacuole-associated lipid bodies and heterogeneous lipid environments in the malaria parasite, Plasmodium falciparum, Mol. Microbiol., 2004, 54, 109–122 CrossRef CAS PubMed.

Footnote

Electronic supplementary information (ESI) available: Synthetic procedures, fluorescence and NMR spectra of the hybrid compounds, additional biological data and explanations. See DOI: https://doi.org/10.1039/d3sc03661h

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