Description
Sold under the trade name Sunvepra®, asunaprevir received
approval in Japan as part of a combination treatment for the hepatitis
C virus (HCV). Working in concert with daclatasvir (IX) (vide
infra), asunaprevir is a unique treatment for HCV, as it is free from both interferon and ribavirin and is administered orally. This
direct-acting anti-viral, which was developed by Bristol–Myers
Squibb (BMS), works as an NS3/4A protease inhibitor, representing
a valuable treatment option for patient populations who are
unable to receive, or do not respond to, the standard course of
treatment—peginterferon/ribavirin.
Synthesis
The preparation of chloroquinoline 27 began with bromination
of commercially available acetophenone 20, which was carefully
carried out on over 1 kg scale in a reactor equipped with an HBr
scrubbing mechanism (bubbler outfitted) to furnish a-bromoketone
21. Next, nucleophilic displacement of the bromide
using sodium diformamide (22) under phase transfer
conditions led to the putative intermediate 23. This system underwent
in situ deprotection of the diformamide functionality followed
by cyclization under mildly acidic conditions to arrive at
isoquinolone 24 in 78% yield across the two-step, one-pot
sequence. Next, methylation of the hydroxyl group at C-4 was carried
out using methanolic methanesulfonic acid at elevated temperatures
followed by treatment with aqueous ammonium
hydroxide to quench any excess acid. Subsequent treatment with
phosphorous oxychloride furnished dichloroisoquinoline 26 in
good yield. A nucleophilic aromatic substitution reaction employing potassium t-butoxide was used to establish an arylpyrrolidino
ether linkage and, upon workup with mildly acidic conditions,
the proline derivative 27 emerged in 59% yield.
Although the synthesis of asunaprevir vinyl cyclopropane subunit
35 has been described by researchers at BMS, it is interesting
to note that this subunit, or structural derivatives of 35, have been found within a number of other antiviral drugs, particularly those
which target inhibition of NS3 protease as its mechanism of action.
For example, researchers at Boehringer-Ingelheim have described a
scale synthesis of (1R,2S)-1-amino-2-vinylcyclopropane carboxylic
acid (des-N-tert-butoxycarbonyl (Boc) 32; also referred
to as ‘vinyl-ACCA’) as a means to incorporate this subunit into that
company’s antiviral agent BILN 2061. A macrocyclic version of
this same cyclopropane-containing system is found in the antiviral
agents paritaprevir hydrate (XXVII) developed by Enanta and Abbvie,
and a saturated version in vaniprevir (XXXVII) developed by
Merck and described later in this review (vide infra). The preparation
of 32 described by Beaulieu and co-workers was performed on
pilot-plant scale and the details surrounding the conversion of 32
to 35 are described by the BMS patent. Beginning with commercially
available methyl glycine HCl (28), condensation with benzaldehyde
in the presence of a dehydrating reagent (trimethyl
orthoformate) and base led to the transient imine 29. This
underwent a highly diastereoselective alkylation reaction whereby
treatment with lithium t-butoxide followed by subjection to 1,4-
dibromo-2-butene facilitated an SN2–SN20 reaction. Subsequent
acidification and Boc protection resulted in 30-rac as a racemate
that existed as a single diastereomer having the vinyl and the ester
groups in a cis configuration. The authors postulate that the lithium
enolate intermediate which forms upon the initial alkylation binds the proximal bromine atom which accounts for the stereoselectivity
of the reaction. Next, selective saponification of the undesired
enantiomer 31b took place via treatment with acalase 2.4 L, which
is a remarkably versatile and relatively inexpensive enzyme capable
of resolving a wide variety of racemic esters,49 under basic
conditions. This enzymatic resolution returned a 49% yield of the
desired ester 31a (theoretical 50%), and a simple aqueous workup
removed the undesired acid 31b. Methyl ester 31a was then
saponified using methanolic lithium hydroxide to give 32, which
was subsequently coupled with cyclopropanesulfonamide 33 to
deliver 34 in excellent yield. Next, removal of the Boc group using
TFA followed by salt formation with ethereal HCl delivered the key
cyclopropane subunit 35.
Cyclopropyl amine 35 was subjected to proline
derivative 27 under conventional amide bond-forming conditions.
This was followed by removal of the pyrrolidine nitrogen Boc
group with acid and subsequent coupling with N-Boc-3-methyl
valine (37) to deliver asunaprevir (IV) in good yield for each of
these steps.
Enzyme inhibitor
This highly selective HCV antiviral (FW = 748.29 g/mol; CAS 630420-16-
5; Symbol: ASV), also named BMS-650032, targets NS3 protease, a serine
proteinase required for Hepatitis C Virus (HCV) polyprotein processing,
showing good antiviral activity against replicons based on HCV Genotype
1a (EC50 = 4 nM), Genotype 1b (EC50 = 1.2 nM), Genotype 4 (EC50 = 1.8
nM), Genotype 5 (EC50 = 1.7 nM), and Genotype 6 (EC50 = 0.9 nM). It
is far less effective against Genotype 2 (EC50 = 67 nM) and Genotype 3
(EC50 = >1100 nM). Asunaprevir is a peptidomimetic that occupies the
active site, inhibiting the HCV NS3/4A serine protease, with little or no
action against related viruses. The average Ki for ASV is approximately
0.4 nM and 0.2 nM for Genotype 1a and Genotype 1b, respectively. Its
acylsulfonamide moeity interacts noncovalently with the NS3 protease –
unlike telaprevir’s α-ketoamide moiety, which is linked covalently to
NS3/4A’s catalytic serine and reverses slowly over time. ASV exhibits an
excellent selectivity index (>40,000x) against all serine/cysteine proteases
evaluated, including human leukocyte elastase, porcine pancreatic elastase,
and three members of the chymotrypsin family. Although ASV shows a
low barrier to resistance, it can be combined with daclatasvir to achieve a
very high rate of viral eradication in both na?ve and treatment-experienced
patients, showing a sustained virological response rate of 80%-90%.
References
[1] scola pm, sun lq, wang ax, chen j, sin n, venables bl, sit sy, chen y, cocuzza a, bilder dm, d'andrea sv, zheng b, hewawasam p, tu y, friborg j, falk p, hernandez d, levine s, chen c, yu f, sheaffer ak, zhai g, barry d, knipe jo, han yh, schartman r, donoso m, mosure k, sinz mw, zvyaga t, good ac, rajamani r, kish k, tredup j, klei he, gao q, mueller l, colonno rj, grasela dm, adams sp, loy j, levesque pc, sun h, shi h, sun l, warner w, li d, zhu j, meanwell na, mcphee f. the discovery of asunaprevir (bms-650032), an orally efficacious ns3 protease inhibitor for the treatment of hepatitis c virus infection. j med chem. 2014 mar 13;57(5):1730-52.
[2] mcphee f, sheaffer ak, friborg j, hernandez d, falk p, zhai g, levine s, chaniewski s, yu f, barry d, chen c, lee ms, mosure k, sun lq, sinz m, meanwell na, colonno rj, knipe j, scola p. preclinical profile and characterization of the hepatitis c virus ns3 protease inhibitor asunaprevir (bms-650032). antimicrob agents chemother. 2012 oct;56(10):5387-96.