1. Introduction
There is an urgent need for the development of new antifungal agents for the treatment of life-threatening invasive fungal infections (IFI), which are becoming more prevalent due to an increased use of immunosuppressive regimens in medical interventions. IFI are more common among patients with impaired immune function, including acute leukemia patients, solid-organ or hematopoietic stem cell transplant recipients, patients receiving cancer chemotherapy, or patients with other underlying diseases that lead to immunosuppression. Global estimates of life-threatening invasive fungal infections exceed 3 million infections per year and include 3 million cases of chronic pulmonary aspergillosis and >300,000 cases of serious and life-threatening invasive aspergillosis (IA) infections [
1]. The associated mortality of IA has been reported to be 30–80% [
2] or 30–95% [
3] In a study of 983 proven/probable IFI identified in 875 hematopoietic stem cell transplant recipients, IA (43%), invasive candidiasis (28%), and zygomycosis (8%) were the most common [
4]. Of the IA cases,
A. fumigatus was the most common pathogen (44%), with
A. flavus (7%),
A. niger (9%),
A. terreus (5%), other species (3%), multiple species (6%), and unidentified
Aspergillus species (26%) comprising the rest of the 425 aspergillosis infections [
4]. Similar trends were seen in a study of
Aspergillus-positive cultures from 1209 patients:
A. fumigatus (67%),
A. flavus (16%),
A. niger (5%),
A. terreus (3%),
A. nidulans (1%), other species (1%), and not identified (7%) [
5].Current treatment options for IA include azoles (voriconazole, isavuconazole, itraconazole, posaconazole) and polyenes (amphotericin B deoxycholate or lipid formulations); however, despite treatment, mortality rates remain high (30–40%) [
6]. A high percentage of fatalities (>50%) is still observed in invasive pulmonary aspergillosis (IPA) among severely immunosuppressed patients, such as neutropenic, leukemic and transplant patients [
7]. In addition, these therapies are limited by renal and liver toxicity, drug–drug interactions, pharmacokinetic variability resulting in the need for drug monitoring, and emerging drug resistance [
7]. For example, triazole-resistant
A. fumigatus are a growing concern, primarily resulting from prolonged azole exposure in patients with chronic pulmonary aspergillosis and environmental exposure of isolates to triazoles used in agriculture [
8].
Isavuconazole was the most recently approved treatment option for IA (2015); however, the pipeline remains sparse with few antifungals currently in clinical development [
9].GR-2397 (previously ASP2397/Astellas and VL-2397/Vical) is the first of a new class of siderophore-like hexapeptide antifungal agents being developed for the treatment of serious fungal infections. GR-2397 is differentiated by its novel mechanism of action that confers rapid fungal cell killing, a low propensity for cytochrome P450 drug–drug interactions, and activity against difficult-to-treat resistant fungal pathogens. Phase 1 IV single-ascending dose and multiple-ascending clinical trials were successfully completed [
10], and GR-2397 is currently in development by Gravitas Therapeutics, Inc. for the treatment of IA.
3. Patent Filing and In-Licensing Arrangements
United States Patent 8,241,872 was obtained 14 August 2012 by Astellas Pharma, Inc. (Astellas, Tokyo, Japan) for the production of an antifungal agent (compound “B”) from strain
Acremonium persicinum MF-347833 [
11]. Earlier US and Japanese application dates suggest that the original discovery was prior to 2008. Of note is that MEC (minimum effective concentration) was used as the endpoint in the in vitro evaluation in the patent (0.31–0.39 µg/mL for species of
Candida and 0.2–0.78 µg/mL for
Aspergillus species) [
11]; however, since this value was determined for both yeasts and molds, it is not clear whether the endpoint represents conspicuously aberrant growth of hyphae as measured for the echinocandins and manogepix against molds, 50% growth inhibition, or alternatively 100% inhibition as measured for the amphotericin B, itraconazole, posaconazole and voriconazole. The first posters were presented at ICAAC 2014 describing the in vitro and in vivo activity of ASP2397 [
12,
13]. In 2015, Vical Incorporated (Vical) in-licensed ASP2397 from Astellas, renaming it VL-2397. In 2016, Vical conducted Phase 1 clinical studies to evaluate the safety, tolerability and pharmacokinetics of intravenous VL-2397 administered once daily for up to 7 days. In October 2017, Vical announced that the U.S. Food and Drug Administration (FDA) had advised that VL-2397 would be eligible for a Limited Use Indication (LUI) approval assuming a successful outcome of a single Phase 2 trial carried out in accordance with a protocol and statistical analysis plan consistent with the Agency’s advice. In early 2018, Vical initiated a registrational Phase 2 clinical study evaluating VL-2397 as a potential first-line treatment for IA in immunocompromised adults with acute leukemia or recipients of an allogeneic hematopoietic cell transplant. In February 2019, Vical announced that it discontinued the Phase 2 clinical trial, a decision made to conserve cash resources following the unsuccessful completion of a Phase 3 trial for a separate program unrelated to GR-2397, as well as due to low patient accrual rates in the GR-2397 Phase 2 trial. In June 2019, Vical and Brickell Biotech, Inc. (Brickell) announced a merger agreement. Finally, in December 2021, Gravitas Therapeutics Inc. (Gravitas) announced that it had purchased the rights to VL-2397 from Brickell, renaming it GR-2397. Gravitas was founded specifically to acquire and rapidly return GR-2397 to the clinic, for the treatment of immunocompromised patients with serious fungal infections, including patients who are unable to receive one of the currently available antifungal agents due to resistance and/or intolerance.
4. Discovery of GR-2397 and the Activity of Related Analogs
GR-2397 is a non-ribosomally synthesized cyclic hexapeptide natural product (compound B) isolated from the Malaysian leaf litter fungus,
Acremonium persicinum MF-347833 [
14]. It was identified by researchers at Astellas who first screened culture broths of 310 geographically diverse fungal species for in vitro activity against
A. fumigatus FP1305, and then identified active broths in an
A. fumigatus silkworm larvae infection model [
15]. Although attempts to purify the active fraction through in vitro antifungal screening failed, the silkworm model was successfully used to guide the purification of the therapeutically active GR-2397 [
15,
16].
GR-2397 is structurally related to ferrichrome, a low-molecular-weight hydroxamate siderophore (
Figure 1). Siderophores are produced by bacteria, fungi and plants in response to low iron levels, and are taken up by these organisms to scavenge these essential ions from the environment. The GR-2397 cyclic hexapeptide is composed of L-asparagine, L-leucine, D-phenylalanine and three Nε-acyl-Nε-hydroxy-ornithines (background highlighted), the latter of which chelate the aluminum ion [chemical name Cyclo{-Asn-Leu-d-Phe-[(N5-acetyl-N5-hydroxy-Orn)-(N5-acetyl-N5-hydroxy-Orn)-(N5-acetyl-N5-hydroxy-Orn)]-}*Al(III)] (
Table 1) [
14]. In contrast, ferrichrome is a cyclic hexapeptide composed of three L-glycine and three Nε-acyl-Nε-hydroxy-ornithines residues that utilize the same hydroxamic acid groups to bind Fe
3+ (
Figure 1) [
17].
Different strains of
A. persicinum have been shown to produce a number of metabolites related to ferrichrome [
14,
18,
19,
20]. These molecules share the three hydroxy ornithine residues that co-ordinate the metal ion but differ in the sequence of the other three amino acids. They have been referred to as acremonpeptides in some publications [
18,
19,
20]. The apo form of the molecules generally lack or have poor antifungal activity. The first publication identified the structure of GR-2397 derived from
A. persicinum MF-347833 [
14]. Although the isolated GR-2397 active natural product was shown to be a siderophore-like molecule with an Al
3+ chelate, the researchers speculated that
A. persicinum produced the metal-free form of the hexapeptide, but addition of Al
3+ ion to the culture medium increased the production of GR-2397 [
14]. GR-2397 does not inhibit the growth of
A. persicinum, suggesting the producing strain also encodes a resistance mechanism [
20]. Its biological role in the producing strain has been hypothesized to be a defense metabolite [
20].
Derivatives were also prepared that contained Fe
3+ (AS2488053), Ga
3+ (AS2529132), or lacked a chelating metal (AS2488059) (
Table 1). A recent study showed that both the Al
3+ chelate (GR-2397) and the Fe
3+ chelate (AS2488053) were produced by
A. persicinum MF-347833, and that incubation in iron-depleted media resulted in an 80-fold increase in the mRNA that encodes
SID1, the genetic locus responsible for the production of these molecules [
20]. Although these two metabolites (Fe
3+ and Al
3+ chelates) were largely secreted into the culture medium, a significant amount was still present in the mycelium. This contrasts with the related siderophore molecule, ferricrocin, produced by the same
A. persicinum strain, where 10-fold higher mRNA levels derived from the corresponding biosynthetic
SID2 locus were induced when this organism was incubated under iron-replete conditions [
20]. Ferricrocin was primarily detected in the mycelia, which the authors suggested served as intracellular/iron sequestering function for this molecule, whereas AS2488059 may primarily serve as an extracellular defensive metabolite and iron courier.
The inhibitory activities of GR-2397 and related molecules vs.
A. fumigatus FP1305 are summarized in
Table 1. Both the Al
3+ and Ga
3+ forms of the molecule showed antifungal activity against this strain when evaluated in RPMI media and RMPI + mouse serum (MS) [
14]. The apo form of the molecule (AS2488059) was active in RPMI, but not active in the presence of mouse serum. Nakamura et al. [
14] suggested that AS2488059 chelated free aluminum or ferrous ion in the RPMI culture medium, whereas there are not enough free metal ions in the presence of mouse serum, resulting in maintenance of the (inactive) apo form. The difference in MIC between the GR-2397 and AS2488053 (the Al
3+ and Fe
3+ forms of the molecule, respectively) suggest the role of Al
3+ in activity. However, AS2524371, which contains a D-Phe to D-Leu substitution, and alumichrome (L-Gly, L-Gly, L-Gly) are also inactive (
Table 1), suggesting that Al
3+ is not solely responsible for the antifungal activity, but instead the composition of the variable three amino acid backbone, and specifically the D-Phe residue of the hexapeptide, plays an important role in antifungal activity. Similarly, the activities of acremonpeptides E and F, along with their apo, Al
3+, Fe
3+, and Ga
3+ hydroxamate siderophore cyclopeptides, were evaluated against
A. fumigatus [
19]. These molecules are similar in structure to GR-2397 in that they all contain three Nε-acyl-Nε-hydroxy-ornithines (
Figure 1) but differ in the sequence of the remaining amino acids (
Table 1). Acremonpeptide E contains L-Ala, L-Leu, D-Phe, whereas acremonpeptide F contains L-Ser, L-Leu, D-Phe. Although activity was measured in non-standard media, the data in
Table 1 shows that the Al
3+ and Ga
3+ chelates demonstrate antifungal activity (1 µm), the apo forms are 10-fold less active (10 µM), and the Fe
3+ versions of these molecules have no antifungal activity (>30 µM), [
19] (
Table 1). Taken together, these data are consistent with the important role of the D-Phe residue in the activity of these molecules.
Acremonpeptides A, B, C, and D have been isolated that contain other amino acid substitutions: A) L-Phe, L-Leu, L-Ser; B) L-Phe, L-Leu, L-Ala; C) L-Phe, L-Leu, L-Phe; and D) L-Phe, L-Leu, L-Trp [
18]. These molecules were reported to have no antibacterial or antifungal activity. However, since they were evaluated against two strains of
C. albicans and not against
A. fumigatus, and since GR-2397 is also inactive against
C. albicans, it is difficult to draw any conclusions about the influence of these amino acid substitutions on activity vs. molds [
18]. Interestingly, these molecules were reported to have low µM activity against Herpes Simplex Virus [
18].
Table 1.
Structure and activity of siderophore analogs.
Table 1.
Structure and activity of siderophore analogs.
Compound | Amino Acid Sequence 1 and Chelation Status | MIC (µg/mL) 2 A. fumigatus FP1305 2 (+MS) | Reference |
---|
Asn, Leu, D-Phe | Asn, Leu, D-Leu | Gly, Gly, Gly | Gly, Ser, Gly | Ala, Leu, D-Phe | Ser, Leu, D-Phe |
---|
AS2488059 | -- | | | | | | 0.78 (>50) | [14] |
AS2488053 | Fe3+ | | | | | | >50 (25) | [14] |
GR-2397 | Al3+ | | | | | | 0.78 (0.39) | [14] |
AS2529132 | Ga3+ | | | | | | 0.78 (0.2) | [14] |
AS2524371 | | Al3+ | | | | | >50 (NT) | [14] |
Ferrichrome | | | Fe3+ | | | | -- | [20] |
Alumichrome | | | Al3+ | | | | “inactive” | [14] |
Deferriferrichrome | | | -- | | | | “inactive” | [14] |
Ferricrocin | | | | Fe3+ | | | -- | [20] |
| | | | | | | MIC (µM) 3 A. fumigatus ATCC 204305 | |
Acremonpeptide E | | | | | -- | | 10 | [19] |
Acremonpeptide E | | | | | Fe3+ | | >30 | [19] |
Acremonpeptide E | | | | | Al3+ | | 1.0 | [19] |
Acremonpeptide E | | | | | Ga3+ | | 1.0 | [19] |
Acremonpeptide F | | | | | | -- | 10 | [19] |
Acremonpeptide F | | | | | | Fe3+ | >30 | [19] |
Acremonpeptide F | | | | | | Al3+ | 1.0 | [19] |
Acremonpeptide F | | | | | | Ga3+ | 1.0 | [19] |
5. Uptake of GR-2397 Is Mediated by the Sit1 Transporter
Although the mechanism of action has not been fully characterized to date, the mechanism of transport of GR-2397 has been identified in
A. fumigatus. Since GR-2397 resembles ferrichrome, Dietl et al. isolated mutants of the siderophore transporters, Sit1 and Sit2 [
22]. They found that an
A. fumigatusΔ
sit1 mutant was resistant to GR-2397 (MIC >16 µg/mL), suggesting that the Δ
sit1 mutant fails to take up GR-2397 [
22]. This is in contrast to the Δ
sit2 mutant, where the GR-2397 MIC was equivalent to wildtype strain (MIC = 1 µg/mL). Importantly, mammalian cells lack a siderophore transport mechanism such as Sit1, which results in an inability to transport GR-2397 by this mechanism, and thus target-based toxicity is predicted to be low. This is consistent with a lack of mammalian cell cytotoxicity at concentrations tested up to 50 μg/mL [
16]. A description of the cell lines utilized for cytotoxicity assessment has not been published. Thus, it is difficult to assess whether this measurement is reflective of effects on normal human tissues.
Additional studies examined antifungal activity in a strain where
SIT1 expression was under control of the xylose-inducible
xylP promoter [
22]. In that strain, the activity of the Fe
3+ analog AS2488053 was equally active as GR-2397 (Al
3+). These data suggested that iron import affects AS2488053 susceptibility. Further, AS2488053 repressed expression of
SIT1 and other iron-repressible genes but increased the iron-inducible
CYCA gene. The authors concluded that iron import mediated by AS2488053 uptake caused repression of
SIT1, further blocking uptake of the drug. Thus, intracellular AS2488053 concentrations would be expected to be significantly lower than that of GR-2397, explaining the differences in antifungal activity between the Al
3+ and Fe
3+ forms of the molecule.
The uptake and activity of GR-2397 was also evaluated against other species [
12]. Whereas both uptake and antifungal activity were observed for
C. glabrata, neither uptake nor antifungal activity were observed for
C. albicans [
12]. Microorganisms produce a variety of siderophore transporters that are differentially regulated, localized, and demonstrate different substrate specificities. Previous analysis showed that the specificity of a transporter for a particular substrate could not be predicted on the basis of protein sequence similarity [
23]. Despite the fact that the
S. cerevisiae genome encodes four siderophore transporters including two that transport ferrichrome (Arn1 and Sit1/Arn3), it is intrinsically resistant to GR-2397 [
22,
24]. When the Sit1 ortholog, derived from either
A. fumigatus or
C. glabrata, was cloned into
S. cerevisiae, concentration-dependent growth inhibition was observed [
22]. These data suggest that although the intracellular target of GR-2397 is present in
S. cerevisiae, the wildtype strain is unable to take it up, resulting in resistance.
C. glabrata and
C. albicans each encode a single Sit1 protein; however,
C. glabrata is susceptible to GR-2397 while
C. albicans is resistant [
22]. BLASTP analysis (
https://blast.ncbi.nlm.nih.gov/Blast.cgi accessed on 17 August 2022) of the Sit1 orthologs
S. cerevisiae Arn1 (NP_011823.1),
S. cerevisiae Arn3/Sit1 (NP_011823),
C. albicans (XP_716020.1),
C. glabrata (XP_445865.1),
A. fumigatus (XP_748904.1) and
A. flavus (XP_041141397.1) demonstrates that the
S. cerevisiae (resistant) and
C. glabrata (susceptible) have greater sequence identity to each other than to the
C. albicans (resistant) sequence (
Table 2).
There are several hypotheses that could explain the phenotypic differences observed between susceptible and resistant species: (1) some fungal species may not express Sit1 orthologs under the conditions used to evaluate susceptibility, (2) the Sit1 ortholog may not recognize GR-2397 as a substrate for uptake, or (3) the intracellular target may differ within fungal cells such that GR-2397 interaction occurs in some species and not in others. Additional studies are necessary to differentiate these or other possibilities.
7. Resistance
The potential for development of resistance to GR-2397 has not been fully investigated. Attempts to isolate
A. fumigatus mutants with decreased susceptibility through serial passage (19 passages) on sub-inhibitory concentrations of GR-2397 did not alter susceptibility to the drug [
25]. A Δ
sit1 transporter mutant, isolated after UV mutagenesis, demonstrated GR-2397 MIC values >16 μg/mL in RPMI media, whereas the susceptibility of the mutant to voriconazole was unchanged (0.25 μg/mL) [
24]. This is consistent with a lack of cross-resistance since voriconazole does not use the siderophore mechanism of transport. A mutant constructed with a deletion of another siderophore transporter (Δ
sit2) did not affect the GR-2397 MIC. Additional studies are necessary in key
Aspergillus species to establish the frequency of GR-2397 resistance.
The identification of SIT1 as a mechanism of GR-2397 resistance leads to the question of whether or not these mutants may arise in patients and impact treatment outcomes. The growth phenotype of the
A. fumigatus Δ
sit1 mutant was evaluated in complex media as well as several minimal media including high iron, iron sufficiency and iron starvation, and no differences between mutant and wildtype were observed [
22].
Park et al. evaluated the virulence of
A. fumigatus sit1 and
sit2 deletion strains [
28]. Although they reported that
sit1 and
sit2 mutants did not impact the mouse 10-day survival rate in an immunocompromised intranasal infection model, this failure to reach statistical significance may have resulted from the use of small numbers of animals (reported as
n = 5 mice, although the data suggests additional mice may have been present in some of the cohorts) [
28]. Whereas none of the mice infected with the wildtype strain survived past day 5, ~30% of the
sit1Δ and
sit1Δ/
sit2Δ mice survived to day 10, suggesting that virulence may have been impacted. Median time to death was not reported. This study also evaluated the effects of conidial killing by neutrophil-like or macrophage-like HL-60 cells [
28]. In this assay, statistically significant increases in killing were observed for the
sit1Δ,
sit2Δ and
sit1Δ/
sit2Δ mutants vs. wildtype. These data suggest that
A. fumigatus sit1 mutants arising in vivo may be less virulent.
Similarly, a
C. albicans sit1/
sit1 deletion strain was constructed and virulence was assessed in an in vitro model in which a keratinocyte cell line was allowed to differentiate on an inert supporting membrane, resulting in a multilayered keratinocyte tissue [
29]. While the wildtype strain
SIT1+ strain entered the upper cellular layers eventually causing extensive damage, the
sit1 mutant strain caused minimal damage and few
C. albicans cells were observed in the upper layer of keratinocytes, even at later time points. However, in a mouse systemic infection model of candidiasis, no differences were observed in the virulence of the wildtype strain vs. the
sit1/
sit1 deletion strain [
29]. The authors suggest that a
sit1 Candida mutant may impact epithelial invasion and penetration, whereas in blood or other organs where other sources of iron may be used, there may be less of an impact [
29].
Deletion of the single
SIT1 locus of
C. glabrata resulted in a strain that was unable to grow or use a xenosiderophore-Fe in iron deficient media [
30]. Thus, it is unlikely that a
sit1 mutant would be viable under in vivo conditions where very low iron levels are present. In addition, the study also showed that SIT1 protein mediated ferrichrome utilization provided a survival advantage to phagocytosed
C. glabrata cells [
30].
Taken together, the data suggest that the SIT1 protein may provide a selective advantage during an infection. Additional studies are necessary to assess whether or not sit1 mutants will arise clinically in different species and result in a potential resistance issue. The issue of resistance may be mitigated by the fact that GR-2397 demonstrates a rapid onset of fungal cell killing, which should rapidly lower the fungal burden.
9. In Vivo Efficacy
The efficacy of GR-2397 was examined in early treatment and delayed treatment models of IPA where mice were immunocompromised with cyclophosphamide and fungal conidiospores introduced via an intratracheal route (
Table 3) [
25]. GR-2397 (subcutaneous) and posaconazole (oral) treatments both demonstrated similar efficacy (100% survival) in an early treatment (6 h post-infection) IPA model.
GR-2397 (subcutaneous administration) also demonstrated significant efficacy in 24 h delayed treatment IPA models of infection using both
A. fumigatus azole-refractory strain (20030) and azole-resistant (
CYP51A mutant 25001) strains as the inoculum (
Table 3) [
25]. At day 10 in both models, 100% survival was observed when mice were treated with GR-2397 at 4 mg/kg or 8 mg/kg twice daily, whereas only 40% of the mice infected with the azole-refractory strain and no mice infected with the azole-resistant strain survived on posaconazole (10 mg/kg twice daily). A dose of 10 mg/kg/day posaconazole has been previously used to benchmark the orotomides since it achieves a clinically relevant exposure in mice [
34] and results in suppression of galactomannan in murine models of IPA [
35]. Analysis of lung fungal burden on day 3 of the delayed IPA treatment (azole-refractory) model showed that the twice daily 2, 4, and 8 mg/kg doses of GR-2397 resulted in a significant reduction in colony-forming units (CFU)/g lung versus the untreated control, with the higher two doses both resulting in >1 log
10 CFU reduction [
25].
In the azole refractory delayed treatment model, the combination of GR-2397 (4 mg/kg BID) plus posaconazole (10 mg/kg BID) or GR-2397 alone resulted in significantly improved survival (90%) vs. the untreated control (10%) and posaconazole alone (20% survival). Although these data are consistent with the lack of antagonism for these two drugs, they do not support the use of the two drugs in combination [
25].
GR-2397 was also evaluated in a disseminated model of invasive candidiasis caused by both wildtype and multi-drug resistant
C. glabrata (
Table 3) [
36]. Efficacy was assessed by evaluating kidney fungal burden on day 8 after twice daily doses of 2 mg/kg, 4 mg/kg, and 8 mg/kg doses of GR-2397, 20 mg/kg fluconazole, or 1 mg/kg caspofungin. Against the wild-type strain, a significant reduction of CFU/g of tissue was observed for all GR-2397 dosing groups (range mean 3.62–4.13 log
10 CFU/g) vs. control (5.24 log
10 CFU/g). Caspofungin also resulted in a significant reduction in CFU/g of tissue (3.67 log
10 CFU/g) vs. control. However, fluconazole showed no significant efficacy in this model (4.85 log
10 CFU/g). Against the caspofungin-/fluconazole-resistant MDR isolate, significant reductions in CFUs were also observed with all three doses of GR-2397 (4.30–5.14 log
10 CFU/g) compared to control (6.63 log
10 CFU/g), but not for caspofungin treatment (5.76 log
10 CFU/g). Treatment with fluconazole did result in significant efficacy (5.34 log
10 CFU/g) vs. control, despite a fluconazole MIC of 64 µg/mL against the infecting strain [
30]. The results suggest that GR-2397 has the potential to be used for the treatment of invasive
C. glabrata infections.
Table 3.
Summary of animal models demonstrating GR-2397 efficacy.
Table 3.
Summary of animal models demonstrating GR-2397 efficacy.
Pathogen | Infection Type | Tx initiation PI 1 | Efficacy Endpoint | Species | Reference |
---|
A. fumigatus (azole-susceptible) | pulmonary | 6 h | survival | mouse | [25] |
A. fumigatus 20030 (azole-refractory) | pulmonary | delayed treatment 1 day | survival, CFU lung | mouse | [25] |
A. fumigatus 20030 (azole-refractory) | pulmonary | delayed +posaconazole combination treatment 1 day | survival | mouse | [25] |
A. fumigatus 25001 (azole-resistant CYP51A) | pulmonary | delayed treatment 1 day | survival, CFU lung | mouse | [25] |
A. fumigatus | disseminated | 1 h | survival | silkworm larvae | [15] |
A. fumigatus | disseminated | 1 h | survival | mouse | [15] |
C. glabrata | disseminated | 1 day | CFU kidney and spleen | mouse | [36] |
10. Determination of the Pharmacokinetic Driver of Efficacy
A multiple-dose study [
37] of GR-2397 for the treatment of mice in the IPA model of
A fumigatus FP1305 (MIC = 1 μg/mL in human serum [
38]; MIC = 0.125 μg/mL CLSI method), was used to determine the PK/PD parameter that best predicted efficacy [
37]. In this study, mice were immunocompromised with cyclophosphamide (200 mg/kg IP days −4 and +1) and infected intratracheally on day 0 with
A. fumigatus FP1305. GR-2397 was administered subcutaneously on days 1, 2, and 3 post-infection. Daily dose sizes included 1, 2, 4, 8, and 16 mg/kg/day, and doses were fractionated daily, twice daily, and four times daily (a total of 15 doses tested). The lung fungal burden (LFB) was determined after sacrificing animals at day 4 (after 3 days of dosing) and evaluating the CFU/g tissue. LFB decreased in a dose-dependent manner, independent of dose frequency. When survival was examined in the same model (infection day 0, treatment days 1, 2, 3, evaluation of day 10 survival), survival was 0–30% (2 mg/kg/day), 30–70% (4 mg/kg/day) 90–100% (8 mg/kg/day) and 100% (16 mg/kg/day) [
37].
Non-linear PK was observed due to concentration-dependent saturable plasma protein binding [
37]. However, after adjusting for saturable protein binding, unbound PK profiles were linear and well-fitted to a 1-compartment model. The reduction in fungal burden correlated with the total daily dose of GR-2397. The best fit curve among PK parameters and antifungal lung burden (log CFU/g) was found for unbound AUC (r
2 = 0.8978), whereas unbound C
max (r
2 = 0.6904) and T > MIC (r
2 = 0.4512) were less predictive.
12. Phase 1 Clinical Trials
The Phase 1 clinical trial VL2397-101 was conducted by Vical (ClinicalTrials.gov NCT02956499). This first-in-human, randomized, double-blind, placebo-controlled dose-escalation study, was conducted in healthy adults to assess the safety, tolerability, and pharmacokinetics of single- and multiple-ascending intravenous doses [
10]. A total of 96 subjects were enrolled in seven single-ascending dose (SAD) and four multiple-ascending dose (MAD) cohorts. Subjects were randomized in a 3:1 ratio to receive IV infusions of GR-2397 or placebo. Since the drug concentration was kept constant at 0.12 mg/mL (low dose cohorts 1–3) or 1.2 mg/mL (cohorts receiving ≥100 mg dose), infusion times varied from 6–240 min and the total volume administered ranged between 23–1000 mL [
10]. SAD cohorts 1–7 received 3 to 1200 mg as a single dose, whereas MAD cohorts 8–10 received once daily doses of either 300, 600 and 1200 mg for 7 days. For MAD cohort 11, subjects received 300 mg T.I.D daily (total 900 mg) for 7 days followed by 600 mg once daily for an additional 21 days (total 28 days).
Pharmacokinetic analysis showed that AUC
0-24 and C
max values rose less than proportionally with increasing doses (3 to 1200 mg) and AUC
0-24 and C
max values for the 7-day MAD cohorts were comparable to those observed for the corresponding SAD cohorts. AUC
0-24 values were also less than dose-proportional for the 300, 600 and 1200 mg MAD doses, as was the rise in C
max. A low variability in exposures was observed among subjects within a cohort or those given the same daily dose in the SAD and MAD studies. There was no apparent accumulation following multiple doses. Nonclinical plasma protein binding studies had previously showed that the major serum binding protein zinc-α2-glycoprotein (ZAG) bound GR-2397 at a very high affinity, and binding was saturated above the 30-mg dose [
10]. This was confirmed in this Phase 1 study, where protein binding of GR-2397 was saturated between the 30-mg and 100-mg doses [
10]. In a study of population PK, this protein binding was suggested to be the primary source of the nonlinearity [
40].
Overall, GR-2397 dosing appeared to be safe and well tolerated in the healthy male and female subjects in this study. No serious adverse events (SAEs) occurred, and the majority of treatment related adverse events (TEAEs) were mild and self-limited, with the most common TEAE being infusion site reactions. Two of the subjects receiving the highest dose tested (1200 mg, MAD cohort) discontinued dosing due to TEAEs including: (a) elevation in serum creatinine from normal after the second dose of GR-2397, which returned to normal by day 17 without intervention; and (b) a severe generalized rash approximately 10 h after receiving the second dose of GR-2397. No additional subjects in any of the SAD or MAD cohorts who received GR-2397 experienced any laboratory- or vital sign-related TEAE related to the study drug. The results from these studies combined with the lack of CYP inhibition suggest that weight-based dosing, therapeutic drug monitoring, and dose adjustments will not be required [
10,
39].
13. Population PK Modeling, Probability of Target Attainment and Dose Selection for Phase 2 Clinical Trials
A total of 1908 plasma concentrations were collected from sixty-six healthy subjects from the 11 Phase 1 study cohorts (SAD and MAD). Population PK modeling showed that a nonlinear saturable binding model with 3 compartments fit the data well [
40]. PK analysis showed that for the 300, 600 and 1200 mg SAD cohort, a mean AUC
inf (SD) of 104.3 (12.8), 150.6 (17.7) and 236.0 (46.7) mg·h/L were observed, respectively. On day 1, GR-2397 concentrations decreased to approximately 1 µg/mL by hour 16, regardless of QD dose level, with slow clearance over time, suggesting a rapid and saturable distribution phase. However, administration of 300 mg every 8 h achieved concentrations above 1 µg/mL over the entire 24-h period [
40].
To support Phase 2 dose selection, data from the dose fractionation study in an
A. fumigatus FP1305 mouse model of IA, which measured reduction in fungal lung burden on day 4 [
37], and the Phase 1 study in healthy adult volunteers [
10] were used to assess the probability of target attainment for 3 different dosing regimens (300, 600, and 900 mg QD) [
38]. A two-compartment model with linear elimination and concentration-dependent binding in both central and peripheral compartments provided a robust fit to the data. The results of the dose fractionation study in mice indicated that fAUC
0-24/MIC was the most predictive driver of efficacy (r
2 = 0.708). In this model, a fAUC
0-24/MIC ratio of 8.40 on day 1 was associated with a 2-log reduction in fungal lung burden on day 4 [
37]. Target attainment simulations showed that once daily IV dosing of 600 mg would provide a robust (99.9%) target attainment (as measured by 2-log reduction in fungal burden) up to and including an
A. fumigatus MIC of 4 μg/mL [
38].
16. Discussion
GR-2397 is a novel, first-in-class antifungal agent in clinical development to address IA infections, a disease with high mortality [
2,
3]. Although GR-2397 demonstrates in vitro activity against a wide range of clinically important yeast and molds, including
Aspergillus spp.,
C. glabrata, and
F. solani, assessment of antifungal activity remains challenging since tier 2 (multi-laboratory) testing has not been completed, nor have QC strains been defined for this new agent. Thus, the spectrum of activity is not fully understood for this siderophore-like agent whose activity against some species is dependent on iron levels in the media. Despite this limitation, efficacy has been observed in several animal models, including multi-drug resistant and other difficult-to-treat infections such as azole-resistant
A. fumigatus and
C. glabrata. Both improved survival, and reductions in kidney and lung fungal burdens have been assessed. It would be worthwhile to evaluate the efficacy of GR-2397 in additional animal models using other yeasts and mold pathogens to better understand the potential spectrum of this new agent.
The reduction in tissue fungal burden is remarkably rapid; thus, this rapid in vivo fungicidal activity should be considered a significant attribute of this drug if it translates to rapid fungal clearance in human infections. The lack of target-based cross-resistance to the other main classes of antifungal agents is an additional attribute, especially for organisms such as A. fumigatus and A. terreus where azole resistance may limit treatment options.
An IV formulation of GR-2397 has been used in early development. In vitro acid stability experiments have not been performed, nor have PK or oral efficacy been evaluated. Thus, the potential for an oral formulation is unknown. Once-daily dosing in humans, a favorable drug–drug interaction profile with no significant CYP3A4 inhibition, a good nonclinical and Phase 1 safety profile together suggest that GR-2397 may be an important alternative to the treatment of Aspergillus fungal infections, and possibly other invasive infections as well, especially for the treatment of patients who cannot tolerate other marketed antifungal agents.