Like the azoles, tetrazoles reversibly and competitively inhibit Erg11p to deplete fungal membranes of ergosterol and disrupt membrane integrity. VT-1129, VT-1598 (quilsecondazole) and VT-1161 (oteseconazole) (Viamet Pharmaceuticals Inc; now Mycovia Pharmaceuticals) were identified as part of a screen for compounds with reduced affinity for human Cyp enzymes (Hoekstra et al., 2014). VT-1161 is more than 1000 times more selective for the C. albicans Cyp51 enzyme compared to the human isoenzyme (Warrilow et al., 2014).

VT-1129, VT-1161, and VT-1598 have potent activity against a broad range of Candida species, including azole and echinocandin-resistant species, at low MICs (Schell et al., 2017a; Break et al., 2018a).

VT-1161 has a low MIC (0.002 μg/ml) against wild-type, fluconazole-sensitive C. albicans (Warrilow et al., 2014) and appears to retain some activity (MIC VT-1161 2 μg/ml) against resistant fluconazole-resistant isolates (MIC FLC 64 μg/ml) and echinocandin-resistant C. albicans, C. glabrata, C. krusei (Garvey et al., 2015; Schell et al., 2017a). In a collection of 68 well-characterised azole-resistant C. albicans isolates, susceptibility to VT-1161 was affected by CDR1 and MDR1 overexpression and the erg11 substitutions Y132F, Y132F and K143R, and Y132 and F145L. Other isolates in this collection with point mutations at additional known azole resistance sites retained VT-1161 sensitivity (e.g. Y132H, F145L) (Nishimoto et al., 2019). Overexpression of CDR1 and MDR1 reduced susceptibility to VT-1161 in C. albicans and C. glabrata in another study (Monk et al., 2019).

VT-1161 treatment significantly reduced fungal burden in murine models of vulvovaginal candidiasis (VVC) and IC due to fluconazole-susceptible and -resistant Candida. VT-1161 was rapidly absorbed in mouse models and extensively distributed to tissues with rapid penetration to vaginal tissues with a long half-life (>48 hours) (Garvey et al., 2015; Break et al., 2018b).

VT-1598 has the broadest spectrum of activity against fungal species, including fluconazole-resistant C. albicans (Break et al., 2018a) and C. auris (MIC 0.03-8 μg/ml) (Wiederhold et al., 2019), with enhanced efficacy in neutropenic murine models compared to either fluconazole or caspofungin.

VT-1129 was designed to treat Cryptococcus, but also has good in vitro activity against many Candida species, including azole- and echinocandin-resistant C. glabrata and C. krusei (Desai et al., 2016; Schell et al., 2017a). No further data on VT-1129 in Candida species are available, however the drug has received FDA fast track orphan drug status for treatment of cryptococcal meningitis.

A phase II dose and duration-ranging placebo-controlled randomised trial (NCT02267382) evaluated the efficacy and safety of lower (150mg) and higher (300mg) 12 or 24-week dosing regimens of oral VT-1161 for recurrent VVC (rVVC) (NCT02267382, 2014). The proportion of subjects with ≥1 acute VVC episodes was superior at 0-7% across the 4 VT-1161 arms vs 52% in the placebo arm. VT-1161 was well-tolerated with a favourable safety profile and importantly, no evidence of hepatoxicity (Brand et al., 2018). Phase III trials in rVVC (NCT03562156 and NCT03561701, VIOLET, and NCT03840616, ultraVIOLET) are ongoing. A press release on July 29^th 2021 reported preliminary findings from the two VIOLET trials in 650 women with efficacy of 90% vs 40% (placebo) against recurrence over 48 weeks and excellent tolerability. VT-1161 has received FDA qualified infectious disease product (QIDP) and fast track designation for treatment of rVVC with full approval expected in the US in early 2022.

VT-1598 is undergoing pre-clinical and phase I evaluation for the treatment of C auris, cryptococcal meningitis and coccidioidomycosis, whilst development of VT-1129 appears to have been halted.

The major advantage of the tetrazoles is their enhanced specificity for fungal Cyp51 making this group of drugs more tolerable.

Rezafungin (Cidara Therapeutics) is a novel β-1,3-glucan synthase inhibitor that is a structural analogue of anidulafungin, but with a much longer half-life, facilitating less frequent dosing.

Rezafungin has similar activity compared to other echinocandins with potent in vivo pharmacodynamic activity against clinically relevant Candida species and greater activity against multidrug resistant strains of C. auris than either caspofungin or micafungin (Pfaller et al., 2016; Pfaller et al., 2017b; Arendrup et al., 2018; Lepak et al., 2018b; Lepak et al., 2018a). Rezafungin retains activity at high doses against echinocandin resistant (fks mutants) Candida species (Berkow and Lockhart, 2018). Rezafungin, but not micafungin, accumulated within intra-abdominal Candida abscesses in a mouse model at a level above the mutant prevention concentration of the infecting strain, which may have implications for resistance (Zhao et al., 2017).

Phase I dose-escalation trials in healthy adults demonstrated that rezafungin was well tolerated and safe with a long half-life and high plasma exposures (Sandison et al., 2017). In a phase II randomised trial (STRIVE) comparing two rezafungin weekly dosing regimens to caspofungin (with fluconazole stepdown) for IC, rezafungin was well tolerated, showed rapid Candida clearance (19.5h) from blood cultures and comparable overall 14-day cure rates (rezafungin 400mg weekly 60.5%, 400mg/200mg weekly 76.1%, caspofungin 70mg/50mg daily 67.2%) (Thompson et al., 2020).

An ongoing phase III trial (RESTORE NCT03667690) in IC is comparing 14-day global cure and 30-day all-cause mortality between weekly rezafungin and daily caspofungin with fluconazole stepdown. Fungal-free survival with rezafungin as prophylaxis against Candida, Aspergillus, and Pneumocytis infection, compared to oral fluconazole or posaconazole, is currently being evaluated in a phase III trial (ResPECT, NCT04368559) in blood or bone marrow transplantation recipients (Cushion et al., 2016; Ong et al., 2016; Cidara Therapeutics, 2020).

The FDA has granted rezafungin QIDP, fast track and orphan drug status for the treatment of candidemia and invasive candidiasis. The long-term effect of the drug’s PK and its relationship to resistance emergence has yet to be investigated.

The major advantage of rezafungin over other echinocandins are its superior pharmacokinetics. Rezafungin has increased stability and solubility with more extensive tissue distribution, with higher plasma exposure and greater gut penetration than other echinocandins, with minimal urinary excretion (Sandison et al., 2017; Zhao et al., 2017). Rezafungin has a longer half-life than any echinocandin (80 hours following a single dose, and 150 hours after three doses) allowing for reduced dosing frequency to as low as once weekly (Sandison et al., 2017), facilitating its use in prophylaxis. A higher loading dose of rezafungin improves efficacy through enhanced killing when fungal burden is greatest and reduces the occurrence of spontaneous fks mutations compared to either caspofungin or anidulafungin (Locke et al., 2016; Sandison et al., 2017; Lakota et al., 2018). However, cross-resistance has been noted between rezafungin and the other echinocandins (Arendrup et al., 2019).

Like other formulations of amphotericin B, MAT2203 sequesters sterols from fungal membranes. The cochleate is absorbed from the GI tract. Once calcium levels within the cochleate drop sufficiently, the spiral unwinds and releases the drug directly onto fungal cells on contact thereby increasing drug delivery directly onto fungal cells and reducing mammalian cell toxicities (Santangelo et al., 2000). The precise interaction between the cochleate and the fungal cell is not yet fully understood.

The MIC of MAT2203 in C. albicans is equivalent to the deoxycholate formulation (0.5 μg/ml) (Zarif et al., 2000). MAT2203 is extensively distributed with good tissue penetration in murine models, where the liver was shown to act as a reservoir for slow release of the drug (Segarra et al., 2002). Mice with systemic candidiasis treated with the encochleated formulation (0.5-20 mg/kg/day) had improved day 16 survival (100%) and reduction in kidney and lung fungal burden relative to intraperitoneal AmB deoxycholeate (70% survival) or liposomal AmB (90% survival) (Santangelo et al., 2000; Hamill, 2013; Shende et al., 2019). No accumulation was observed in healthy mice highlighting the improved fungal specificity of the cochleate formulation.

MAT2203 was well tolerated in healthy volunteers in a single ascending dose phase I study, with mild gastrointestinal adverse events noted (Aigner and Lass-Flörl, 2020). A randomised phase II study (NCT02971007) in women with moderate to severe VVC refractory or intolerant to current therapy yielded disappointing results with MAT2203 (200 mg or 400 mg daily for 5 days) performing poorly compared to a single dose of fluconazole (150 mg): clinical cure at day 12 was significantly lower at 52% and 54.5% compared to 75% for fluconazole. Preliminary data from a small phase II trial (n=16 women) with refractory mucocutaneous candidiasis using higher (400-800mg/d) MAT2203 doses for longer durations (>6 months) suggests all patients eventually achieved a greater than 50% improvement in clinical signs and symptoms and the drug was well tolerated for prolonged periods.

MAT2203 was granted FDA QIDP and fast track status for the treatment of candidiasis in 2015 (BioPharma, 2014).

Oral administration of the cochleate and its improved tolerability profile hold promise, though comparable efficacy to standard of care oral treatments for mucosal candidiasis has yet to be demonstrated. Molecular umbrella technology is a promising method for the development of further formulations of amphotericin B.

Ibrexafungerp (Scynexis) also targets β-1,3-glucan synthase, but is structurally distinct from the echinocandins and represents the inaugural member of a novel class of antifungals, the triterpenoids (Gintjee et al., 2020), which bind at an independent site on the enzyme (Schell et al., 2017b; Wring et al., 2017).

Ibrexafungerp has broad spectrum, fungicidal activity against Candida species with MIC <2 μg/ml for C. albicans, C. glabrata, C tropicalis, and C. parapsilosis, but no activity against C. krusei and C. lusitaniae (Pfaller et al., 2013). Whilst ibrexafungerp retains activity against some echinocandin-resistant Candida strains (fks1/2 mutants), including C. glabrata (Jiménez-Ortigosa et al., 2017; Nunnally et al., 2019) and C. auris (Berkow et al., 2017; Larkin et al., 2017; Pfaller et al., 2017a; Schell et al., 2017b), presumably due to differential binding on the enzyme, deletion of F625 in fks1 or F659 in fks2 were associated with a 40- and 121-fold increase in MIC for ibrexafungerp in C. glabrata, respectively. Furthermore, W715L or A1390D substitutions, positioned outside of the hotspot region in fks2, increase the MIC to ibrexafungerp by 29 and 20-fold, respectively (Jiménez-Ortigosa et al., 2017).

In murine studies, oral and IV formulations of ibrexafungerp showed extensive distribution and tissue penetration, though not into the CNS (Wring et al., 2017). Ibrexafungerp accumulates at sites with a low pH, with extensive accumulation in vaginal tissue and a necrotic liver abscess in murine models (Larkin et al., 2019; Lee et al., 2020). Neutropenic murine systemic candidiasis models have demonstrated efficacy of ibrexafungerp against C. albicans, C. glabrata and C. parapsilosis, including against an echinocandin-resistant strain of C. glabrata (Lepak et al., 2015; Wring et al., 2017; Wiederhold et al., 2018).

Oral ibrexafungerp was well tolerated in phase I studies even at high doses (up to 1600 mg), with an extensive volume of distribution and good tissue penetration and improved biofilm penetration compared to azoles (Wring et al., 2018; Spec et al., 2019; Azie et al., 2020). A phase II randomised trial (NCT02679456) in rVVC demonstrated superiority of ibrexafungerp relative to fluconazole, with 4-month cure rates of 88% and 65%, respectively, and lower recurrence rates of 4% vs 15% (Helou and Angulo, 2017). A phase II dose-ranging acute VVC study (NCT03253094) investigated range of ibrexafungerp dosing regimens compared to single 150 mg dose fluconazole (NCT03253094, 2017), leading onto two recently completed phase III trials of ibrexafungerp 300 mg twice daily for 1 day for the treatment of acute VVC. Ibrexafungerp demonstrated clinical cure rates of 50-63% by day 8-14 against 29-44% with placebo, however gastrointestinal adverse events did occur more commonly in the ibrexafungerp group (VANISH 303 NCT03734991; VANISH 306 NCT03987620). The FDA approved the drug for treatment of VVC in June 2021, marketed as Brexafemme.

A PK study of ibrexafungerp 500 mg or 750 mg as stepdown therapy following IV echinocandin showed that the higher dose would achieve the target PK exposure, was well tolerated and achieved comparable responses to fluconazole (Spec et al., 2019). Two ongoing phase III trials are evaluating ibrexafungerp fungal diseases (including mucocutaneous and invasive candidiasis) refractory to or intolerant of standard antifungal treatment (FURI, NCT03059992, target n=200) and in treating invasive C. auris infection (CARES, NCT03363841). Ibrexafungerp has been given QIDP status by the FDA for invasive candidiasis.

Advantages of ibrexafungerp over the echinocandins include oral administration, penetration into intraabdominal abscesses and retained activity against some echinocandin resistant isolates.

Fosmanogepix (APX001 and E1211, Amplyx Pharmaceuticals) is the inaugural member of the N-phosphonooxymethylene prodrugs that is efficiently converted to manogepix (APX001A and E1210), an inhibitor of fungal glycosylphosphatidylinositol (GPI) proteins. Manogepix was identified in a screen for compounds that interfere with the correct localisation of cell wall GPI-anchored mannoproteins (Tsukahara et al., 2003). Manogepix is highly specific for fungal, but not human Gwt1, an enzyme that catalyses the acetylation of inositol, an essential step in the early stages of GPI anchor biosynthesis (Miyazaki et al., 2011; Watanabe et al., 2012). Gwt1 is essential for trafficking and anchoring mannoproteins to the cell wall and outer cell membrane to maintain cell wall integrity, adhesion, pathogenicity, and evasion of the host immune system. Inhibition of Gwt1 prevents cell wall reinforcement thereby reducing hyphal formation, virulence, germ tube formation, and biofilm formation, in addition to inducing morphological changes to the cell size and shape resulting in exposure of β-1,3-glucan to host immune cells and ER stress (Watanabe et al., 2012).

Fosmanogepix is highly active against many Candida species: MIC₉₀ C. albicans (0.008-0.06 μg/ml), C. glabrata (0.06-0.12 μg/ml), C. auris (0.03 μg/ml) (Hata et al., 2011; Miyazaki et al., 2011; Pfaller et al., 2011a; Watanabe et al., 2012; Hager et al., 2018; Zhao M. et al., 2018), though lacks activity against C. krusei (MIC₉₀ ≥ 0.5 μg.ml) (Miyazaki et al., 2011). No cross-resistance has been reported between the echinocandins, amphotericin B and fosmanogepix for multiple Candida species (Miyazaki et al., 2011; Pfaller et al., 2011a; Wiederhold et al., 2015b; Zhao, Y et al., 2018), with most studies reporting no cross-resistance to fluconazole-resistant erg11 mutants (Miyazaki et al., 2011; Pfaller et al., 2011a). There does however appear to be a correlation with fluconazole MICs, with a 2-8-fold increase in MIC to fosmanogepix reported in a subset of fluconazole-resistant Candida isolates (Arendrup et al., 2018; Arendrup and Jørgensen, 2020). A recent study of the mechanism of reduced susceptibility to both fosmanogepix and fluconazole identified increased efflux through Cdr11 and Snq2 as a result of a gain-of-function mutation in the transcription factor zcf29 in C. albicans and a mitochondrial DNA deletion activating MDR1 expression in C. parapsilosis (Liston et al., 2020). Despite MIC increases, the MIC of these isolates remained low. Further studies are needed to determine the clinical relevance of these findings and to explore the link with azole cross-resistance via efflux.

In vitro serial passage showed an 8-fold rise in MIC in C. albicans (18 passages) and C. parapilosis (3 passages), with no increase in MIC for C. glabrata, C. auris and C. tropicalis (Kapoor et al., 2020). GWT sequencing of isolates with reduced susceptibility demonstrated a single valine to alanine point mutation in gwt (V163A C. glabrata; V162A C. albicans) which appears to be essential for manogepix binding in all Gwt orthologs. Neither mutation affected susceptibility to echinocandins or azoles. A further study identified enhanced efflux as the mechanism of fosmanogepix resistance in C. parapsilosis and C. albicans that have a 4-8 fold increase in MIC that were not associated with mutations in the GWT gene (Liston et al., 2020).

Fosmanogepix is effective at reducing fungal burden and improving survival in immunosuppressed murine models using wild type, azole- and echinocandin-resistant Candida, including C. auris (Hata et al., 2011; Miyazaki et al., 2011; Wiederhold et al., 2015b; Hager et al., 2018; Zhao et al., 2018). Rodent and primate studies have demonstrated good oral bioavailability and safety and extensive tissue penetration (liver, lungs, spleen, brain, kidney, eye) (Hata et al., 2011; Mansbach et al., 2017). In addition, fosmanogepix has demonstrated synergy with the azoles and echinocandins in animal models (Hata et al., 2011).

Fosmanogepix has undergone four phase I trials (NCT03333005; NCT04166669; NCT02956499; NCT02957929) using intravenous and oral administration, showing a low propensity for drug-drug interactions, good tolerability and no serious adverse effects reported in healthy volunteers (Hodges et al., 2017a; Hodges et al., 2017b), with findings in acute myeloid leukaemia patients not yet reported.

In an open label phase II trial (NCT03604705), with a minimum of 3 days’ IV therapy followed by oral stepdown, in non-neutropenic patients (n=20) with suspected or confirmed candidemia, 16/20 patients achieved 14-day treatment success (composite of alive, two negative blood cultures and no rescue antifungal treatment). In a phase II trial in C. auris candidemia or IC (NCT04148287, APEX), 9 participants received IV fosmanogepix on days 1-3 followed by oral fosmanogepix for up to 42 days. However, this trial was terminated early due to COVID19. Fosmanogepix has been granted FDA fast track approval for 7 separate indications including invasive candidiasis.

Fosmanogepix exploits a novel mechanism of action that has limited potential for cross-resistance. It is broad spectrum, effective in animal and early-stage clinical trials, is orally bioavailable and well tolerated, and shows promise for use in infections due to multidrug resistant species such as C. auris.

ATI-2307 (Appili Therapeutics), formerly T-2307 (developed by Toyama Chemical Co), is an arylamidine similar to pentamidine. Its precise mechanism of action remains elusive, however it is selectively taken up into fungal cells via the spermidine transport system (Nishikawa et al., 2010) and initiates the collapse of mitochondrial membrane potential, ultimately inhibiting respiration and energy production resulting in fungicidal activity in C. albicans and C. krusei, but fungistatic activity in C. glabrata and C. parapsilosis (Nishikawa et al., 2010; Shibata et al., 2012; Yamashita et al., 2019).

ATI-2307 is active against a broad spectrum of Candida species including azole and echinocandin-resistant species and C. auris (Mitsuyama et al., 2008; Yamada et al., 2010; Wiederhold et al., 2015a; Wiederhold et al., 2016; Wiederhold et al., 2020) with lower in vitro MICs (0.0005-0.125 μg/ml) compared to azoles, micafungin, and amphotericin B (Mitsuyama et al., 2008). ATI-2307 exerted a more potent effect at equivalent doses of amphotericin B or micafungin in immunocompetent murine models of systemic wild type C. albicans and echinocandin resistant infections (Mitsuyama et al., 2008). ATI-2307 also reduced kidney fungal burden and improved survival in mice infected with C. auris (Wiederhold et al., 2020), as well as neutropenic mice infected with C. glabrata harbouring the Fks2 substitution R1379S (Wiederhold et al., 2016). ATI-2307 had minimal effect on mitochondrial morphology and potential of rat liver cells (Nishikawa et al., 2010; Yamada et al., 2010; Nishikawa et al., 2016).

One report states that ATI-2307 has completed a phase I study in the USA with no adverse effects noted (Nishikawa et al., 2017), however these data are not currently publicly available.

Although this compound remains in the early stages of clinical development, ATI-2307 shows promise as a fungal-selective compound (Nishikawa et al., 2010; Nishikawa et al., 2016) and in vitro and in vivo data highlight its potential in treating a range of Candida species including more resistant isolates.

The hydrazycins, (E)-N′-(3-bromo-6-hydroxybenzylidene)-2-methylbenzohydrazide (BHBM) and benzohydrazide (D0) were identified in a screen for compounds that specifically inhibit the biosynthesis of fungal glucosylceramide. The hydrazycins inhibit the vesicular trafficking of ceramide, a precursor lipid of glucosylceramide, thereby halting glucosylceramide and sphingolipid biosynthesis and disrupting cell division (Mor et al., 2015).

BHBM has variable activity against Candida species with moderate activity against C. krusei and C. glabrata, (MIC 2-32 μg/ml), but poor activity against C. albicans and C parapsilosis (MIC>32 μg/ml) (Mor et al., 2015). A derivative of BHBM, D13, was selected from a screen for enhanced specificity to the fungal target activity and activity, with an MIC of 1 μg/ml in C. albicans and C. krusei (Lazzarini et al., 2018). Synergy of D13 with fluconazole was reported for one of two C. krusei strains (FICI 0.31), and with caspofungin for both isolates, but neither combination was synergistic for fluconazole-sensitive or -resistant C. albicans (Lazzarini et al., 2018).

Two murine systemic candidiasis model studies evaluated the in vivo activity of the hydrazycins. One reported a 75% and 62.5% 21-day survival in the D0 and BHBM arms, respectively (Mor et al., 2015); the other a much lower 20% day 21 survival with either D13 or BHBM against 0% with fluconazole (Lazzarini et al., 2018).

The hydrazycins remain in pre-clinical development. Sphingolipid metabolism is being explored separately for use in fungal vaccines.

BHBM, D0, and D13 are fungal-specific with a novel sphingolipid target. Although current hydrazycins do not show sufficient spectrum against clinically relevant Candida species, the BHBM derivative, D13, represents an improvement and all congeners have all been reported to re-sensitise some azole-resistant species to azoles. Screens for additional daughter compounds of BHBM may identify novel hydrazycins with superior antifungal activity.

Whilst the anticancer properties of AR-12 are attributed to its kinase inhibition, its antifungal activity is via two distinct routes. Firstly, by the specific inhibition of the fungal acetyl CoA (Acs2p) which has a multitude of effects due to the vast range of processes that acetyl CoA is involved with (e.g. carbon metabolism, histone acetylation, ribosome function and autophagy) (Koselny et al., 2016b). Inhibition of Acs2p ultimately induces cell lysis. Secondly, AR-12 also enhances the host antifungal immune response through down-regulation of host chaperone proteins such as Grp89 and Hsp90, although the precise details have not yet been determined (Koselny et al., 2016b).

AR-12 is fungicidal against Candida species (MIC C. albicans, C. glabrata, C. parapsilosis, C. tropicalis, C. krusei 2-4 μg/ml) and retains activity against strains with intermediate or resistant fluconazole MICs (MIC > 128 μg/ml) due to gain-of-function mutations affecting efflux pump activity (Koselny et al., 2016a). In addition, deletion of neither TAC1 nor MRR1 affected susceptibility of isolates to AR-12. Combination of AR-12 with fluconazole re-sensitised some fluconazole-resistant C. albicans and C. glabrata strains. AR-12 remained active against echinocandin-resistant strains containing FKS mutations and synergised with caspofungin in caspofungin-resistant strains of C. glabrata (Koselny et al., 2016a).

Early phase I studies (NCT00978523) for the anticancer activity of AR-12 identified good serum concentrations with limited adverse effects, however development was halted in 2017 when Arno Therapeutics declared bankruptcy (Koselny et al., 2016b).

AR-12 has a broad antifungal spectrum in yeasts and moulds and has been shown to be well tolerated in Phase I human clinical trials at doses relevant for antifungal activity. Commonly occurring mechanisms of azole and echinocandin resistance do not appear to affect susceptibility to AR-12. Combinations with existing antifungals may show potential in tackling drug-resistant candidiasis.

External stressors induce an influx of calcium ions into the fungal cytoplasm, which bind to the calcium-binding protein calmodulin. Calcineurin binds to the calcium-calmodulin complex inducing a conformational change in the phosphatase that removes the autoinhibitory domain, thus activating calcineurin. Calcineurin transmits calcium signals via the dephosphorylation and subsequent nuclear translocation of the transcription factor Crz1 which in turn activates the transcription of calcineurin-dependent genes involved in cellular signalling, growth, vesicular trafficking, and cell wall integrity (Karababa et al., 2006).

FK506 and cyclosporin bind to immunophilins forming a potent calcineurin inhibitor complex thereby preventing the activation of its phosphatase activity and subsequent activation of Crz1 (Liu et al., 1991; Thewes, 2014).

Calcineurin inhibitors abrogate tolerance in Candida and enhance the antifungal activity of current antifungals: Combination of a calcineurin inhibitor with fluconazole renders fungicidal activity in many Candida species with varying levels of tolerance (Marchetti et al., 2000a; Marchetti et al., 2000b; Cruz and Goldstein, 2002; Onyewu et al., 2003). In vitro screens against C. albicans, C. glabrata, and C. krusei using drugs for non-mycological conditions with antifungals identified cyclosporin A and FK506 (tacrolimus) as synergistic with both azole and non-azole inhibitors of ergosterol biosynthesis (e.g. terbinafine). However, cyclosporin A and FK506 are potent immunosuppressants typically prescribed following solid organ transplantation and could thus enhance host susceptibility to Candida infection. FK506 analogues that lack immunosuppressive activity yet retain synergy with antifungals have demonstrated promising in vitro and in vivo results (Lee et al., 2018; Jung and Yoon, 2020).

Calcineurin activity can also be inhibited through depletion of the molecular chaperone heat shock protein 90 (Hsp90). Hsp90 is implicated in the emergence of resistance to fluconazole and echinocandins in C. albicans and C. glabrata and potentiates its activity through binding to the catalytic subunit of calcineurin (Cowen and Lindquist, 2005; Cowen et al., 2006). Hsp90 inhibitors (e.g. geldanamycin and efungumab) induce the degradation of the downstream protein calcineurin and also synergise with azoles and echinocandins in vitro (Singh et al., 2009; Singh-Babak et al., 2012). Moreover, Hsp90 represents a favourable target as it interacts with approximately 10% of the proteome, therefore inhibition could disrupt multiple essential pathways (McClellan et al., 2007). Efungumab (previously Mycograb) is a monoclonal antibody targeting Hsp90 developed by NeuTec Pharma and subsequently acquired by Novartis. Mycograb combined with a lipid formulation of AmB was reported as resulting in faster fungal clearance, improved d10 response rates and reduced mortality in a phase III trial in IC compared to AmB alone (Pachl et al., 2006). However, the study methodology was questioned (Herbrecht et al., 2006) and the European Medicines Agency has subsequently twice refused marketing authorisation for Mycograb, citing product safety and quality issues. Hsp90 inhibitors are currently in development as anti-cancer drugs, however these are precluded from human use due to host toxicities, but recent identification of specific inhibitors of the C. albicans Hsp90 nucleotide binding domain offer a path towards fungal selectivity (Whitesell et al., 2019).

Calcineurin and Hsp90 are promising targets due to their central role in many fungal growth and invasion pathways, priming host cells to antifungal drugs and antifungal immunity. Combinations of azoles with inhibitors or these pathways renders azoles fungicidal and may limit the development of resistance. Calcineurin and Hsp90 are both structurally highly conserved throughout fungal species offering an opportunity for development of a broad-spectrum, non-immunosuppressive derivative of currently licensed inhibitors.

HDAC inhibitors (trichostatin A, apicidin and sodium butyrate) induce apoptosis and cell cycle arrest (Grozinger and Schreiber, 2002). MGCD290 (MethylGene, Mirati Therapeutics) inhibits the fungal histone deacetylase 2 (Hos2) with an additional target through inhibition of the deacetylation of fungal Hsp90, involved in fungal stress adaptation (Robbins et al., 2012) and may have a role in addressing fungal tolerance. Like, MGCD290, Trichostatin A reduced tolerance and inhibited upregulation of C. albicans ERG11 and CDR when co-administered with fluconazole, itraconazole and terbinafine (inhibitors of sterol synthesis), but had little effect on a fluconazole-resistant isolate (Smith and Edlind, 2002).

MGCD290 only has modest antifungal activity against Candida species as monotherapy (MIC 0.5–16 μg/ml for C. albicans, C. glabrata, C. krusei), however synergises with azoles and echinocandins at low doses in susceptible as well as azole- and some echinocandin- resistant Candida species (Pfaller et al., 2009; Pfaller et al., 2015). MGCD290 in combination with fluconazole increased survival and significantly reduced fungal burden in the kidney in murine and rat models of systemic candidiasis relative to fluconazole alone (Besterman et al., 2015).

Four phase I trials in healthy volunteers of oral MGCD290 alone or in combination with fluconazole for 14 days demonstrated a good safety profile and favourable PK (Besterman, 2012). Despite compelling in vitro data, MGCD290’s promising antifungal activity failed to translate: a phase II trial of MGCD20 in combination with fluconazole for VVC showed no significant benefit of the combination over fluconazole alone (NCT01497223).

MGCD290 is an oral agent with a novel target demonstrating potential in vitro through its impact on tolerance, but whose clinical potential has not been realised. Inhibition of Hsp90 through preventing its deacetylation is potentially more attractive given the immunosuppressive consequences of direct Hsp90 pharmacological inhibition.