Lionel Rouge

A Therapeutic Antibody Targeting BACE1 Inhibits Amyloid-β Production in Vivo

A human antibody inhibits BACE1 activity and Aβ peptide production in cultured neurons and in the central nervous system of mouse and monkey. A Trojan Horse Antibody Scales a Mighty Fortress As impenetrable as the walls of ancient Troy, the tight endothelial cell layer of the blood-brain barrier (BBB) allows only a few select molecules to enter the brain. Unfortunately, this highly effective fortress blocks passage of therapeutic antibodies, limiting their usefulness for treating diseases of the brain and central nervous system. Enter Ryan Watts and his team at Genentech with their ambitious dual goal of making a therapeutic antibody against a popular Alzheimer’s disease drug target, the enzyme β-secretase (BACE1), and developing a strategy to boost the amount of this antibody that enters the brain (Atwal et al. and Yu et al.). BACE1 processes the amyloid precursor protein into amyloid-β (Aβ) peptides including those molecular species that aggregate to form the amyloid plaques found in the brains of Alzheimer’s disease patients. By blocking the activity of BACE1, BACE1 inhibitors should reduce production of the aggregation-prone Aβ peptides, thus decreasing amyloid plaque formation and slowing Alzheimer’s disease progression. Although small-molecule inhibitors of BACE1 have been developed and can readily cross the BBB because of their small size, they do not show sufficient specificity and hence may have toxic side effects. Watts envisaged that a better approach to blocking BACE1 activity might be passive immunization with a highly specific anti-BACE1 antibody. So his team engineered an anti-BACE1 antibody that bound to BACE1 with exquisite specificity and blocked its activity (Atwal et al.). The investigators then showed that this antibody could reduce production of aggregation-prone Aβ peptides in cultured primary neurons. Next, Watts and his colleagues injected the antibody into mice and monkeys and demonstrated a sustained decrease in the concentrations of Aβ peptide in the circulation of these animals and to a lesser extent in the brain. The researchers knew that they must find a way to increase the amount of antibody getting into the brain to reduce Aβ peptide concentrations in the brain sufficiently to obtain a therapeutic effect. So Watts teamed up with fellow Genentechie, Mark Dennis, and they devised an ingenious solution (Yu et al.). The Genentech researchers knew that high-affinity antibodies against the transferrin receptor might be able to cross the BBB using a natural process called receptor-mediated transcytosis. However, when they tested their antibody, they found that although it readily bound to the BBB, it could not detach from the transferrin receptor and hence was not released into the brain. So, they made a series of lower-affinity mouse anti-transferrin receptor antibodies and found variants that could cross the BBB by receptor-mediated transcytosis and were released into the mouse brain once they got across the endothelial cell layer. Next, they designed a bispecific mouse antibody with one arm comprising a low-affinity anti-transferrin receptor antibody and the other arm comprising the high-affinity anti-BACE1 antibody that had shown therapeutic promise in their earlier studies. They demonstrated that their bispecific antibody was able to cross the BBB and reach therapeutic concentrations in the mouse brain. They then showed that this bispecific antibody was substantially more effective at reducing Aβ peptide concentrations in the mouse brain compared to the monospecific anti-BACE1 antibody. This elegant pair of papers not only demonstrates the therapeutic potential of an anti-BACE1 antibody for treating Alzheimer’s disease but also provides a strategy worthy of the ancient Greeks that could be applied to other therapeutic antibodies that require safe passage into the human brain. Reducing production of amyloid-β (Aβ) peptide by direct inhibition of the enzymes that process amyloid precursor protein (APP) is a central therapeutic strategy for treating Alzheimer’s disease. However, small-molecule inhibitors of the β-secretase (BACE1) and γ-secretase APP processing enzymes have shown a lack of target selectivity and poor penetrance of the blood-brain barrier (BBB). Here, we have developed a high-affinity, phage-derived human antibody that targets BACE1 (anti-BACE1) and is anti-amyloidogenic. Anti-BACE1 reduces endogenous BACE1 activity and Aβ production in human cell lines expressing APP and in cultured primary neurons. Anti-BACE1 is highly selective and does not inhibit the related enzymes BACE2 or cathepsin D. Competitive binding assays and x-ray crystallography indicate that anti-BACE1 binds noncompetitively to an exosite on BACE1 and not to the catalytic site. Systemic dosing of mice and nonhuman primates with anti-BACE1 resulted in sustained reductions in peripheral Aβ peptide concentrations. Anti-BACE1 also reduces central nervous system Aβ concentrations in mouse and monkey, consistent with a measurable uptake of antibody across the BBB. Thus, BACE1 can be targeted in a highly selective manner through passive immunization with anti-BACE1, providing a potential approach for treating Alzheimer’s disease. Nevertheless, therapeutic success with anti-BACE1 will depend on improving antibody uptake into the brain.

Discovery of a Potent, Selective, and Orally Available Class I Phosphatidylinositol 3-Kinase (PI3K)/Mammalian Target of Rapamycin (mTOR) Kinase Inhibitor (GDC-0980) for the Treatment of Cancer.

The discovery of 2 (GDC-0980), a class I PI3K and mTOR kinase inhibitor for oncology indications, is described. mTOR inhibition was added to the class I PI3K inhibitor 1 (GDC-0941) scaffold primarily through the substitution of the indazole in 1 for a 2-aminopyrimidine. This substitution also increased the microsomal stability and the free fraction of compounds as evidenced through a pairwise comparison of molecules that were otherwise identical. Highlighted in detail are analogues of an advanced compound 4 that were designed to improve solubility, resulting in 2. This compound, is potent across PI3K class I isoforms with IC(50)s of 5, 27, 7, and 14 nM for PI3Kα, β, δ, and γ, respectively, inhibits mTOR with a K(i) of 17 nM yet is highly selective versus a large panel of kinases including others in the PIKK family. On the basis of the cell potency, low clearance in mouse, and high free fraction, 2 demonstrated significant efficacy in mouse xenografts when dosed as low as 1 mg/kg orally and is currently in phase I clinical trials for cancer.

Wnt antagonists bind through a short peptide to the first β-propeller domain of LRP5/6.

The Wnt pathway inhibitors DKK1 and sclerostin (SOST) are important therapeutic targets in diseases involving bone loss or damage. It has been appreciated that Wnt coreceptors LRP5/6 are also important, as human missense mutations that result in bone overgrowth (bone mineral density, or BMD, mutations) cluster to the E1 propeller domain of LRP5. Here, we report a crystal structure of LRP6 E1 bound to an antibody, revealing that the E1 domain is a peptide recognition module. Remarkably, the consensus E1 binding sequence is a close match to a conserved tripeptide motif present in all Wnt inhibitors that bind LRP5/6. We show that this motif is important for DKK1 and SOST binding to LRP6 and for inhibitory function, providing a detailed structural explanation for the effect of the BMD mutations.

Conformational stabilization of ubiquitin yields potent and selective inhibitors of USP7.

Protein conformation and function are often inextricably linked, such that the states a protein adopts define its enzymatic activity or its affinity for various partners. Here we combine computational design with macromolecular display to isolate functional conformations of ubiquitin that tightly bind the catalytic core of the oncogenic ubiquitin-specific protease 7 (USP7) deubiquitinase. Structural and biochemical characterization of these ubiquitin variants suggest that remodeled backbone conformations and core packing poise these molecules for stronger interactions, leading to potent and specific inhibition of enzymatic activity. A ubiquitin variant expressed in human tumor cell lines binds and inhibits endogenous USP7, thereby enhancing Mdm2 proteasomal turnover and stabilizing p53. In sum, we have developed an approach to rationally target macromolecular libraries toward the remodeling of protein conformation, shown that engineering of ubiquitin conformation can greatly increase its interaction with deubiquitinases and developed powerful tools to probe the cellular role of USP7.

Crystal Structure of Procaspase-1 Zymogen Domain Reveals Insight into Inflammatory Caspase Autoactivation

One key event in inflammatory signaling is the activation of the initiator caspase, procaspase-1. Presented here is the crystal structure of the procaspase-1 zymogen without its caspase recruitment domain solved to 2.05 Å. Although the isolated domain is monomeric in solution, the protein appeared dimeric in crystals. The loop arrangements in the dimer provide insight into the first autoproteolytic events that occur during activation by oligomerization. Additionally, in contrast to other caspases, we demonstrate that autoproteolysis at the second cleavage site, Asp316, is necessary for conversion to a stable dimer in solution. Critical elements of secondary structure are revealed in the crystal structure that explain why a dimeric protein is favored after proteolysis at this aspartic acid. Dimer stabilization is concurrent with a 130-fold increase in kcat, the sole contributing kinetic factor to an activated and efficient mediator of inflammation.

Back Pocket Flexibility Provides Group II p21-Activated Kinase (PAK) Selectivity for Type I 1/2 Kinase Inhibitors.

Structure-based methods were used to design a potent and highly selective group II p21-activated kinase (PAK) inhibitor with a novel binding mode, compound 17. Hydrophobic interactions within a lipophilic pocket past the methionine gatekeeper of group II PAKs approached by these type I 1/2 binders were found to be important for improving potency. A structure-based hypothesis and strategy for achieving selectivity over group I PAKs, and the broad kinome, based on unique flexibility of this lipophilic pocket, is presented. A concentration-dependent decrease in tumor cell migration and invasion in two triple-negative breast cancer cell lines was observed with compound 17.

USP7 small-molecule inhibitors interfere with ubiquitin binding

The ubiquitin system regulates essential cellular processes in eukaryotes. Ubiquitin is ligated to substrate proteins as monomers or chains and the topology of ubiquitin modifications regulates substrate interactions with specific proteins. Thus ubiquitination directs a variety of substrate fates including proteasomal degradation. Deubiquitinase enzymes cleave ubiquitin from substrates and are implicated in disease; for example, ubiquitin-specific protease-7 (USP7) regulates stability of the p53 tumour suppressor and other proteins critical for tumour cell survival. However, developing selective deubiquitinase inhibitors has been challenging and no co-crystal structures have been solved with small-molecule inhibitors. Here, using nuclear magnetic resonance-based screening and structure-based design, we describe the development of selective USP7 inhibitors GNE-6640 and GNE-6776. These compounds induce tumour cell death and enhance cytotoxicity with chemotherapeutic agents and targeted compounds, including PIM kinase inhibitors. Structural studies reveal that GNE-6640 and GNE-6776 non-covalently target USP7 12 Å distant from the catalytic cysteine. The compounds attenuate ubiquitin binding and thus inhibit USP7 deubiquitinase activity. GNE-6640 and GNE-6776 interact with acidic residues that mediate hydrogen-bond interactions with the ubiquitin Lys48 side chain, suggesting that USP7 preferentially interacts with and cleaves ubiquitin moieties that have free Lys48 side chains. We investigated this idea by engineering di-ubiquitin chains containing differential proximal and distal isotopic labels and measuring USP7 binding by nuclear magnetic resonance. This preferential binding protracted the depolymerization kinetics of Lys48-linked ubiquitin chains relative to Lys63-linked chains. In summary, engineering compounds that inhibit USP7 activity by attenuating ubiquitin binding suggests opportunities for developing other deubiquitinase inhibitors and may be a strategy more broadly applicable to inhibiting proteins that require ubiquitin binding for full functional activity.

Structure-based optimization of pyrazolo-pyrimidine and -pyridine inhibitors of PI3-kinase.

Starting from HTS hit 1a, X-ray co-crystallization and molecular modeling were used to design potent and selective inhibitors of PI3-kinase. Bioavailablity in this series was improved through careful modulation of physicochemical properties. Compound 12 displayed in vivo knockdown of PI3K pharmacodynamic markers such as pAKT, pPRAS40, and pS6RP in a PC3 prostate cancer xenograft model.

Design of Synthetic Autonomous VH Domain Libraries and Structural Analysis of a VH Domain Bound to Vascular Endothelial Growth Factor

We compared the capacity of an autonomous heavy chain variable (VH) domain (VH-B1a) to support diversity within its antigen-binding site relative to the conventional antigen-binding fragment (Fab) from which it was derived. We find that VH-B1a can tolerate significant diversity within all three complementarity-determining regions (CDRs) and also within framework 3, and thus, VH-B1a and the Fab are similar in terms of the regions of the antigen-binding site that can tolerate diversity without compromising stability. We constructed libraries of synthetic VH domains and isolated binders with moderate affinity for vascular endothelial growth factor (VEGF) from a library in which only CDR3 was randomized. One binder was subjected to affinity maturation to derive an autonomous VH domain (VH-V1a) that recognized both human and mouse VEGF with high affinity (KD=16nM or 10nM, respectively). Structural analysis revealed that VH-V1a binds to an epitope that is distinct from the epitopes of a natural VEGF receptor and six different anti-VEGF Fabs. Moreover, VH-V1a recognizes VEGF by using an unusual paratope consisting predominantly of CDR3 but with significant contributions from framework residues within the former light chain interface. These results suggest that VH-B1a and other autonomous VH domains may be useful scaffolds to support both conventional libraries with antigen-binding sites built from the three CDR loops and, also, nonconventional libraries with antigen-binding sites built from CDR3 and the former light chain interface.

Structure-based design of thienobenzoxepin inhibitors of PI3-kinase

Starting from thienobenzopyran HTS hit 1, co-crystallization, molecular modeling and metabolic analysis were used to design potent and metabolically stable inhibitors of PI3-kinase. Compound 15 demonstrated PI3K pathway suppression in a mouse MCF7 xenograft model.