Trouble Brewing for New HCV Meds
Aug24

Trouble Brewing for New HCV Meds

In a blow to the Hepatitic C drug development arena, Bristol-Myers Squibb last night pulled the plug on BMS-986094, an NS5B inhibitor in mid-stage trials. The decision comes just weeks after the company reported a patient suffered from heart failure during a Phase II study of the compound. Nine patients were eventually hospitalized, with varying symptoms of kidney and heart toxicity, according to BMS’s release (See more coverage by Adam Feuerstein at The Street and by Andrew Pollack at the NYT) BMS-986094? You might know this molecule better as Inhibitex’s former nucleoside INX-089. The molecule came to BMS through its $2.5 billion purchase of Inhibitex in 2011, as we wrote last year here at the Haystack. The molecule belongs to a family of new nucleosides with fairly common structural motifs: a central sugar appended to a nitrogen heterocycle (usually purine- or uracil-based) and an elaborate phosphoramidate prodrug. These new drugs’ similarities may also prove to be their Achilles heel – Idenix Pharmaceuticals announced an FDA-requested partial clinical hold on their IDX-184 lead. This cautious approach aims to protect patients; though the drugs are similar, 184’s main structural difference – a thioester-based, slightly more-polar prodrug – seems to be enough to distance it from the cardiac side-effects seen with BMS-986094. For a fairly in-depth look at the chemistry behind these inhibitors, as well as dozens of other analogues that never made it to prime time, check out US Patent 7,951,789 B2, issued to Idenix just last...

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Rigged Reactions: Biocatalysis Meets 13C NMR
Jul19

Rigged Reactions: Biocatalysis Meets 13C NMR

When you think of reaction screening, what comes to mind? Most would say LC-MS, the pharma workhorse, which shows changes in molecular polarity, mass, and purity with a single injection. Some reactions provide conversion clues, like evolved light or heat. In rare cases, we can hook up an in-line NMR analysis – proton (1H) usually works best due to its high natural abundance (99.9%). Please welcome a new screening technique: 13C NMR. How can that work, given the low, low natural abundance of ~1.1% Carbon-13? Researchers at UT-Southwestern Medical Center have the answer: rig the system. Jamie Rogers and John MacMillan report in JACS ASAP 13C-labeled versions of several common drug fragments, which they use to screen new biocatalyzed reactions. Biocatalysis = big business for the pharma world. The recent Codexis / Merck partnership for HCV drug boceprevir brought forth an enzyme capable of asymmetric amine oxidation. Directed evolution of an enzyme made sense here, since they knew their target structure, but what if we just want to see if microbes will alter our molecules? Enter the labeled substrates: the researchers remark that they provide an “unbiased approach to biocatalysis discovery.” They’re not looking to accelerate a certain reaction per se, but rather searching for any useful modifications using the 13C “detector” readout. One such labeled substrate, N-(13C)methylindole, shows proof-of-concept with their bacterial library, producing two different products (2-oxindole and 3-hydroxyindole) depending on the amount of oxygen dissolved in the broth. NMR autosamplers make reaction monitoring a snap, and in short order, the scientists show biotransformations of ten more indole substrates. This paper scratches multiple itches for various chem disciplines. Tracking single peaks to test reactions feels spookily close to 31P monitoring of metal-ligand catalysis. Organickers, no strangers to medicinally-relevant indole natural products, now have another stir-and-forget oxidation method. Biochemists will no doubt wish to tinker with each bacterial strain to improve conversion or expand scope. The real question will be how easily we can incorporate 13C labels into aromatic rings and carbon chains, which would greatly increase the overall...

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Antibacterial Resistance – Learning Bacterial Tricks
Mar23

Antibacterial Resistance – Learning Bacterial Tricks

Virulent bacteria are growing increasingly resilient against our best antibiotics. Each day seems to bring a new story: MRSA outbreaks, resistant salmonella, or tough-to-treat tuberculosis. Just last week, World Health Organization director-general Dr. Margaret Chan delivered an address in Copenhagen, where she cautioned: “We are losing our first-line antimicrobials . . . in terms of replacement antibiotics, the pipeline is virtually dry. The cupboard is nearly bare.” (Click here for The Haystack’s past coverage of the development of new antibacterials). Why have our drugs stopped working? Recent research from St. Jude’s (Science, 2012, 1110) attempted to answer that question. Using X-ray crystallography, a technique used to see structures at the atomic level, the researchers were able to capture a critical moment when a drug binds to DHPS, its bacterial enzyme target. The scientists could then predict how bacteria evolve to dodge further biocidal bullets. The antibacterial medicines caught in the act by the St. Jude’s researchers are the sulfa drugs (see right), former front-line treatments many doctors push to the bottom of treatment regimens, due to increasingly resistant bacterial strains. Researchers knew resistance had something to do with the drugs’ mechanism of action; sulfa drugs mimic the binding of PABA – para-aminobenzoic acid, a compound found in many sunscreens (Chemical Note: PABA occurs naturally as bacterial vitamin H1, and can also be found in yeast and plants. Chemists often borrow naturally-occurring compounds for industrial uses; two prominent examples are vanillin and Vitamin C). Disruption of this PABA binding shuts down bacterial DNA replication, stopping reproduction. Before now, however, no one had succeeded in growing crystals of the active site that actually showed the drugs interacting with the enzymatic intermediate. Let’s take one more step back: how does PABA attach itself? The enzyme we’re discussing, DHPS, catalyzes bond formation between PABA and intermediates known as pterins (see picture, left). Earlier researchers believed that this molecular hook-up operated by an SN2 mechanism, a reaction where the PABA kicks out a small piece of the pterin to form a new C-N bond. We chemists would say that SN2 means concerted bond formation, meaning that PABA would bind at the same time as the leaving group (OPPi), well, leaves. Turns out that picture’s not quite right: it’s more SN1-like, which means that the pterin first forms a positively-charged, enzyme-stabilized species! As you can imagine, this is no small feat, since the reaction works at physiological pH, in water, which could hydrate the intermediate (but doesn’t). Nope – instead, this charged molecule sits around waiting for a PABA – or a sulfa drug – to bind to it. When PABA binds, the complex exits...

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Exploring Rational Drug Design
Feb17

Exploring Rational Drug Design

Medicinal chemists strive to optimize molecules that fit snugly into their proposed targets. But in the quest for potency, we often overlook the local physics that govern drugs’ binding to these receptors. What if we could rationally predict which drugs bind well to their targets? A new review, currently out on J. Med. Chem. ASAP, lays out all the computational backing behind this venture. Three computational chemists (David Huggins, Woody Sherman, and Bruce Tidor) break down five binding events from the point-of-view of the drug target: Shape Complementarity, Electrostatics, Protein Flexibility, Explicit Water Displacement, and Allosteric Modulation….whew! Note: Before we dive into this article, let’s clarify a few terms computational drug-hunters use that bench chemists think of differently: ‘decoy’ – a test receptor used to perform virtual screens; ‘ligand’ – the drug docking into the protein; ‘affinity / selectivity’ – a balance of characteristics, or how tightly something binds vs. which proteins it binds to; ‘allosteric’ – binding of a drug molecule to a different site on an enzyme than the normal active site. Regular readers and fans of compu-centric chem blogs such as The Curious Wavefunction and Practical Fragments will feel right at home! We’ll start at the top. Shape complementarity modeling uses small differences in a binding pocket, such as a methylene spacer in a residue (say, from a Val to Ile swap) to dial-in tighter binding between a target and its decoy. The authors point out that selectivity can often be enhanced by considering a drug that’s literally too big to fit into a related enzymatic cavity. They provide several other examples with a ROCK-1 or MAP kinase flavor, and consider software packages designed to dock drugs into the “biologically active” conformation of the protein. Electrostatic considerations use polar surface maps, the “reds” and “blues” of a receptor’s electronic distribution, to show how molecular contacts can help binding to overcome the desolvation penalty (the energy cost involved in moving water out and the drug molecule in). An extension of this basic tactic, charge optimization screening, can be used to test whole panels of drugs against dummy receptors to determine how mutations might influence drug binding. Because target proteins move and shift constantly, protein flexibility, the ability of the protein to adapt to a binding event, is another factor worth considering. The authors point out that many kinases possess a “DFG loop” region that can shift and move to reveal a deeper binding cavity in the kinase, which can help when designing binders (for a collection of several receptors with notoriously shifty binding pockets – sialidase, MMPs, cholinesterase – see p. 534 of Teague’s NRDD review). But these...

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The HCV Combo Race Just Got Hotter
Jan13

The HCV Combo Race Just Got Hotter

BMS is shelling out $2.5 billion dollars for Inhibitex, a small pharma company with a Phase II molecule for treatment of Hepatitis C (HCV). The deal adds to the scramble for HCV assets in recent months, with Gilead agreeing to pay almost $11 billion for Pharmasset in November, and Roche’s recent purchase of Anadys. While much has been written about the merits (and price tags) of each deal, the Haystack thought it was worth taking a closer look at the chemical composition of the multi-million dollar molecules. So what did BMS get for their money? INX-089, Inhibitex’s lead molecule, has a common antiviral motif: a nucleoside core (the 5-membered ring sugar attached to a nitrogen heterocycle) with an amino acid based prodrug hanging off the left-hand side. Clinically-tested antivirals sharing this basic setup include IDX-184 and NM-283, both from Idenix, and PSI-352938, from Pharmasset  (For an overview of the varied structures currently in development for HCV, see Lisa’s 2010 C&EN story). INX-089 bears a close resemblance to Pharmasset’s lead nucleotide inhibitor PSI-7977. That’s not a mistake, believes ‘089 discoverer Chris McGuigan, of the Welsh School of Pharmacy. In a recent article (J. Med. Chem. 2010, 53, 4949), McGuigan himself comments “The Pharmasset nucleoside [is] rather parallel to our early work on anti-HIV ProTides.” Wait, what are ProTides? Both INX-089 and PSI-7977 aren’t themselves the active viral inhibitor, but phosphoramidate “ProTide” prodrugs: compounds broken down by the body into the active drug (Chem Note: PSI-7977 has single-enantiomer Sp chirality at phosphorus, while INX-189 is a mixture of diastereomers). Once in the body, enzymes cleave the phosphoramidate group to a phosphate (PO42-). Kinases attach two more phosphate groups, and viruses let this dressed-up molecule inside, where the nucleotide warhead inhibits HCV by interfering with RNA replication (Antimicrob. Agents Chemother. 2011, 55, 1843). A few comments on the drug itself: The similarity of the ProTide portion (left-hand side) of the molecule to PSI-7977 really is striking: swap in an isobutyl ester and a phenyl, and it’s the same beast! The more interesting switch comes on the upper-right (“eastern”) part of the structure: a protected guanosine ring. This ring harks back to guanine, one of the four common nucleic acids found in DNA. PSI-7977, meanwhile, shows off a uracil, a nucleic acid found in RNA, not DNA. Although it’s tempting to think such similar compounds all dock into the NS5B polymerase at the active site (in the yellow “palm” of the hand-shaped enzyme), don’t be too sure – a recent paper by Pharmasset scientists (J. Med. Chem. 2012, Just Accepted) shows quite a few “Finger,” “Palm,” and “Thumb” sites.  It’s not yet clear whether...

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