Development of potent and selective Cathepsin C inhibitors free of aortic binding liability by application of a conformational restriction strategy.

Cathepsin C plays a key role in the activation of several degradative enzymes linked to tissue destruction in chronic inflammatory and autoimmune diseases. Therefore, Cathepsin C inhibitors could potentially be effective therapeutics for the treatment of diseases such as chronic obstructive pulmonary disease (COPD) or acute respiratory distress syndrome (ARDS). In our efforts towards the development of a novel series of Cathepsin C inhibitors, we started working around AZD5248 (1), an α-amino acid based scaffold having potential liability of aortic binding. A novel series of amidoacetonitrile based Cathepsin C inhibitors were developed by the application of a conformational restriction strategy on 1. In particular, this work led to the development of a potent and selective Cathepsin C inhibitor 3p, free of aortic binding liability.

Discovery of 5-(2-chloro-4'-(1H-imidazol-1-yl)-[1,1'-biphenyl]-4-yl)-1H-tetrazole as potent and orally efficacious S-nitrosoglutathione reductase (GSNOR) inhibitors for the potential treatment of COPD.

Endogenous nitrosothiols (SNOs) including S-nitrosoglutathione (GSNO) serve as reservoir for bioavailable nitric oxide (NO) and mediate NO-based signaling, inflammatory status and smooth muscle function in the lung. GSNOR inhibition increases pulmonary GSNO and induces bronchodilation while reducing inflammation in lung diseases. In this letter, design, synthesis and structure-activity relationships (SAR) of novel imidazole-biaryl-tetrazole based GSNOR inhibitors are described. Many potent inhibitors (30, 39, 41, 42, 44, 45 and 58) were identified with low nanomolar activity (IC50s: <15 nM) along with adequate metabolic stability. Lead compounds 30 and 58 exhibited good exposure and oral bioavailability in mouse pharmacokinetic (PK) study. Compound 30 was selected for further profiling and revealed comparable mouse and rat GSNOR potency, high selectivity against alcohol dehydrogenase (ADH) and carbonyl reductase (CBR1) family of enzymes, low efflux ratio and permeability in PAMPA, a high permeability in CALU-3 assay, significantly low hERG activity and minimal off-target activity. Further, an in vivo efficacy of compound 30 is disclosed in cigarette smoke (CS) induced mouse model for COPD.

Membrane activity of an amphiphilic alpha-helical membrane-proximal cytoplasmic domain of the MoMuLV envelope glycoprotein.

In the Moloney murine leukemia virus (MoMuLV) envelope glycoprotein (Env) we identified a membrane-proximal cytoplasmic domain (residues 598-616) that facilitates the Env incorporation into virions and Env-mediated fusion [Rozenberg, Y., Conner, J., Aguilar-Carreno, H., Chakraborti, S., Dimiter, D.S., Anderson, W.F., 2008. Viral entry: membrane-proximal cytoplasmic domain of MoMuLV envelope tail facilitates fusion. In the same issue. (accompanying paper)]. By biophysical methods (CD, EPR) a corresponding peptide (membrane-proximal peptide, 598-616) was demonstrated to form a membrane-parallel amphiphilic alpha-helix in the presence of membranes. Electrophysiological studies with planar bilayers and liposomes indicate that the membrane-proximal peptide is membrane destabilizing. This peptide and the fusion peptide from the MoMuLV transmembrane (TM) ectodomain were tested for their effect on the bilayer for hexagonal phase transition temperature of dipalmitoleoylphosphatidylethanolamine (T(H)). Importantly, the external fusion peptide and the internal membrane-proximal peptides of MoMuLV env exert opposite effects on membrane curvature. The fusion peptide lowers T(H) while the membrane proximal peptide raises it. These effects on T(H) correlate with the ability of these peptides to induce lipid mixing in large unilamellar vesicles composed of dioleoylphosphatidylethanolamine: dioleoylphosphatidylcholine:cholesterol (1:1:1 mol). When added externally to preformed liposomes, the N-terminal fusion peptide promotes lipid mixing while the cytoplasmic membrane-proximal peptide inhibits this effect. These finding indicate a possible mechanism by which the membrane-proximal domain in MoMuLV Env may affect the formation of membrane fusion intermediates.

Membrane-proximal cytoplasmic domain of Moloney murine leukemia virus envelope tail facilitates fusion.

Removal of the R peptide (residues 617-632) from the Moloney murine leukemia virus (MoMuLV) envelope protein (Env) cytoplasmic tail potentiates fusion. We examined the role of the membrane-proximal cytoplasmic domain (598-616) of the MoMuLV Env in the Env-mediated membrane fusion and incorporation. The Env truncated at 616 exhibits maximum fusogenicity in cell-to-cell fusion assay. By comparison, full tail Env (632) and the Env truncated to residue 601 mediated fusion at 40%. The Envs truncated to residues 598 or 595 are not fusogenic. Progressive cytoplasmic tail truncation correlated with decreased Env incorporation into virions. Substitution of the domain 598-616 with an amphiphilic alpha-helix from melittin results in maximally fusogenic Envs that efficiently incorporated into transduction competent virions. However, substitution of the domain 598-616 with random or hydrophilic sequences caused loss of the Env fusogenicity and titer while retaining incorporation. Further, a secondary structure prediction analysis of 27 unrelated Env cytoplasmic tails indicates a common (23/27) propensity for an amphiphilic alpha-helical domain at immediate proximity to the viral membrane. These results support the suggestion that viral fusion is enhanced by a membrane-proximal cytoplasmic amphiphilic alpha-helix in Env tail. The model of its action is proposed.

Potent cross-reactive neutralization of SARS coronavirus isolates by human monoclonal antibodies.

The severe acute respiratory syndrome coronavirus (SARS-CoV) caused a worldwide epidemic in late 2002/early 2003 and a second outbreak in the winter of 2003/2004 by an independent animal-to-human transmission. The GD03 strain, which was isolated from an index patient of the second outbreak, was reported to resist neutralization by the human monoclonal antibodies (hmAbs) 80R and S3.1, which can potently neutralize isolates from the first outbreak. Here we report that two hmAbs, m396 and S230.15, potently neutralized GD03 and representative isolates from the first SARS outbreak (Urbani, Tor2) and from palm civets (SZ3, SZ16). These antibodies also protected mice challenged with the Urbani or recombinant viruses bearing the GD03 and SZ16 spike (S) glycoproteins. Both antibodies competed with the SARS-CoV receptor, ACE2, for binding to the receptor-binding domain (RBD), suggesting a mechanism of neutralization that involves interference with the SARS-CoV-ACE2 interaction. Two putative hot-spot residues in the RBD (Ile-489 and Tyr-491) were identified within the SARS-CoV spike that likely contribute to most of the m396-binding energy. Residues Ile-489 and Tyr-491 are highly conserved within the SARS-CoV spike, indicating a possible mechanism of the m396 cross-reactivity. Sequence analysis and mutagenesis data show that m396 might neutralize all zoonotic and epidemic SARS-CoV isolates with known sequences, except strains derived from bats. These antibodies exhibit cross-reactivity against isolates from the two SARS outbreaks and palm civets and could have potential applications for diagnosis, prophylaxis, and treatment of SARS-CoV infections.

Potent knock down of HIV-1 replication by targeting HIV-1 Tat/Rev RNA sequences synergistically with catalytic RNA and DNA.

OBJECTIVE: Ribozymes (Rzs) and DNA-enzymes (Dzs) possess the ability to prevent gene expression by cleaving target RNA in a catalytic and sequence-specific manner. Although Rzs or Dzs have been used earlier for HIV-1 gene suppression, the present study explored the possibility of using catalytic RNA and DNA simultaneously in a synergistic manner with the hope that this novel approach will allow more potent inhibition for a longer duration. METHODS: In order to achieve long-term inhibition of HIV-1 replication, a novel non-GUX hammerhead Rz was designed by standard recombinant DNA technology and cloned it under the powerful CMV promoter containing expression vector. A 10-23 catalytic motif containing Dz that was targeted against the conserved second exon of HIV-1 Tat/Rev region was also assembled. RESULTS: Both Rz and Dz possessed sequence-specific cleavage activities individually and simultaneously cleaved target RNA in a synergistic manner under the same in vitro cleavage conditions. These catalytic molecules inhibited HIV-1 replication in macrophages individually and exhibited potent inhibitory effects when used in combination. CONCLUSIONS: The combination strategy described here can be widely used against any target RNA to achieve more effective gene inhibition that exploits the simultaneous sequence-specific cleavage potentials of catalytic RNA and DNA.

Potent inhibition of HIV-1 gene expression and TAT-mediated apoptosis in human T cells by novel mono- and multitarget anti-TAT/Rev/Env ribozymes and a general purpose RNA-cleaving DNA-enzyme.

One of the hallmarks of progression of HIV-1/AIDS is the rapid depletion of CD4+T cells that is known to occur at the late stages of the disease when usually X4 tropic HIV-1 predominates. Besides direct killing of T lymphocytes, HIV-1 infection leads to extensive apoptosis of naïve/uninfected bystander T cells, which is predominantly mediated by HIV-1 TAT protein. Therefore, reduction of HIV-1 TAT protein is likely to reduce substantially the pathogenesis associated with HIV-1 infection. We designed two non-GUX hammerhead ribozymes (Rzs) and a Di-Rz by placing them in direct tandem. These were targeted against the most conserved second exon of HIV-1 TAT/Rev/Env region. Although very impressive in vitro cleavage of the target RNA by the two hammerhead Rzs was obtained under standard conditions of cleavage, only one of them was active under simulated physiological conditions. Sequence-specific cleavage by the Di-Rz was most efficient under standard conditions. Cleavage reactions carried out under simulated physiological conditions by the Di-Rz, however, indicated that both mono-Rzs were functional. We also assembled a 10-23 catalytic motif containing general purpose RNA-cleaving DNA-enzyme (Dz) against the same region, which cleaved the target RNA very efficiently. Both Rzs and Dz showed not only potent inhibition of HIV-1 gene expression but also showed remarkable protection against HIV-1 TAT protein-mediated apoptosis in Jurkat T cells. Possible implications of these findings are discussed.

Development of human monoclonal antibodies against diseases caused by emerging and biodefense-related viruses.

Polyclonal antibodies have a century-old history of being effective against some viruses; recently, monoclonal antibodies (mAbs) have also shown success. The humanized mAb Synagis (palivizumab), which is still the only mAb against a viral disease approved by the US FDA, has been widely used as a prophylactic measure against respiratory syncytial virus infections in neonates and immunocompromised individuals. The first fully human mAbs against two other paramyxoviruses, Hendra and Nipah virus, which can cause high (up to 75%) mortality, were recently developed; one of them, m101, showed exceptional potency against infectious virus. In an amazing pace of research, several potent human mAbs targeting the severe acute respiratory syndrome coronavirus S glycoprotein that can affect infections in animal models have been developed months after the virus was identified in 2003. A potent humanized mAb with therapeutic potential was recently developed against the West Nile virus. The progress in developing neutralizing human mAbs against Ebola, Crimean-Congo hemorrhagic fever, vaccinia and other emerging and biodefense-related viruses is slow. A major problem in the development of effective therapeutic agents against viruses, including therapeutic antibodies, is the viruses' heterogeneity and mutability. A related problem is the low binding affinity of crossreactive antibodies able to neutralize a variety of primary isolates. Combinations of mAbs or mAbs with other drugs, and/or the identification of potent new mAbs and their derivatives that target highly conserved viral structures, which are critical for virus entry into cells, are some of the possible solutions to these problems, and will continue to be a major focus of antiviral research.

The SARS coronavirus S glycoprotein receptor binding domain: fine mapping and functional characterization.

The entry of the SARS coronavirus (SCV) into cells is initiated by binding of its spike envelope glycoprotein (S) to a receptor, ACE2. We and others identified the receptor-binding domain (RBD) by using S fragments of various lengths but all including the amino acid residue 318 and two other potential glycosylation sites. To further characterize the role of glycosylation and identify residues important for its function as an interacting partner of ACE2, we have cloned, expressed and characterized various soluble fragments of S containing RBD, and mutated all potential glycosylation sites and 32 other residues. The shortest of these fragments still able to bind the receptor ACE2 did not include residue 318 (which is a potential glycosylation site), but started at residue 319, and has only two potential glycosylation sites (residues 330 and 357). Mutation of each of these sites to either alanine or glutamine, as well as mutation of residue 318 to alanine in longer fragments resulted in the same decrease of molecular weight (by approximately 3 kDa) suggesting that all glycosylation sites are functional. Simultaneous mutation of all glycosylation sites resulted in lack of expression suggesting that at least one glycosylation site (any of the three) is required for expression. Glycosylation did not affect binding to ACE2. Alanine scanning mutagenesis of the fragment S319-518 resulted in the identification of ten residues (K390, R426, D429, T431, I455, N473, F483, Q492, Y494, R495) that significantly reduced binding to ACE2, and one residue (D393) that appears to increase binding. Mutation of residue T431 reduced binding by about 2-fold, and mutation of the other eight residues--by more than 10-fold. Analysis of these data and the mapping of these mutations on the recently determined crystal structure of a fragment containing the RBD complexed to ACE2 (Li, F, Li, W, Farzan, M, and Harrison, S. C., submitted) suggested the existence of two hot spots on the S RBD surface, R426 and N473, which are likely to contribute significant portion of the binding energy. The finding that most of the mutations (23 out of 34 including glycosylation sites) do not affect the RBD binding function indicates possible mechanisms for evasion of immune responses.

Oligomerization of the SARS-CoV S glycoprotein: dimerization of the N-terminus and trimerization of the ectodomain.

Viral envelope glycoproteins are oligomeric and the quaternary structure is critical for their membrane fusion activity. Typically the transmembrane glycoproteins of class I fusion proteins contain the oligomerization domains and the surface glycoproteins (SU) are monomeric. However, it has been previously demonstrated [J. Biol. Chem. 277 (2002) 19727] that the SU of a murine hepatitis coronavirus (MHV) forms dimers, the dimerization domain overlaps the receptor-binding domain (RBD) and that this dimeric state is important for binding to receptor molecules that initiates entry into cells. We have previously expressed various soluble fragments of the SARS-CoV SU and identified stably folded fragments (residues 272-537) that contain the RBD [Biochem. Biophys. Res. Commun. 312 (2003) 1159]. Here, we further characterize these and other fragments in an attempt to identify possible dimerization domains and their role for membrane fusion. We demonstrate that the SU and a shorter 260-amino acid N-terminal fragment (residues 17-276), which folds independently, form dimers. In contrast to the previously characterized MHV SU dimerization, this fragment is upstream and distinct from the RBD. Its deletion abolished S-mediated cell membrane fusion but retained the SU-receptor-binding function indicating the possibility for a role in post-receptor binding steps of the virus entry mechanism. Interestingly, the whole soluble S ectodomain (Se) that contains the dimerization domain but not the transmembrane domain and the cytoplasmic tail forms trimers suggesting the existence of a trimerization domain in the TM subunit in its prefusion state that may lead to a conformation unfavorable for formation of higher-order multimeric structures. These results demonstrate the existence of SU dimers and Se trimers, and indicate the possibility for an unknown mechanism of their role in entry. They also further characterize the S-mediated membrane fusion and could be important for understanding the mechanisms of virus entry, and in the development of therapeutics and vaccines.

In vitro selected RNA-cleaving DNA enzymes from combinatorial libraries.

The selective inactivation of a target gene by antisense mechanisms is an important biological tool in the delineation of gene functions. Ribozymes and RNA-cleaving DNA enzymes-mediated approaches are more attractive because of their ability to catalytically cleave the target RNA. DNA enzymes have recently gained great importance because they are short DNA molecules with simple structures that are expected to be stable to the nucleases present inside a mammalian cell. We have designed a strategy to identify accessible cleavage sites in human immunodeficiency virus-1 (HIV-1) gag RNA from a pool of random DNA enzymes, and for isolation of DNA enzymes. A pool of random sequences 29 nucleotides long that contained the previously identified 10-23 catalytic motif were tested for their ability to cleave the target RNA. When the pool of random DNA enzymes was targeted to cleave between A and U nucleotides, a DNA enzyme 1836 was identified. Although several DNA enzymes were identified using a pool of DNA enzyme that was completely randomized with respect to its substrate-binding properties, DNA enzyme-1810 was selected for further characterization. Both the DNA enzymes showed target-specific cleavage activities in the presence of Mg2+ only. These strategies could be applied for the selection of desired target sites in any target RNA.

The SARS-CoV S glycoprotein: expression and functional characterization.

We have cloned, expressed, and characterized the full-length and various soluble fragments of the SARS-CoV (Tor2 isolate) S glycoprotein. Cells expressing S fused with receptor-expressing cells at neutral pH suggesting that the recombinant glycoprotein is functional, its membrane fusogenic activity does not require other viral proteins, and that low pH is not required for triggering membrane fusion; fusion was not observed at low receptor concentrations. S and its soluble ectodomain, S(e), were not cleaved to any significant degree. They ran at about 180-200kDa in SDS gels suggesting post-translational modifications as predicted by previous computer analysis and observed for other coronaviruses. Fragments containing the N-terminal amino acid residues 17-537 and 272-537 but not 17-276 bound specifically to Vero E6 cells and purified soluble receptor, ACE2, recently identified by M. Farzan and co-workers [Nature 426 (2003) 450-454]. Together with data for inhibition of binding by antibodies developed against peptides from S, these findings suggest that the receptor-binding domain is located between amino acid residues 303 and 537. These results also confirm that ACE2 is a functional receptor for the SARS virus and may help in the elucidation of the mechanisms of SARS-CoV entry and in the development of vaccine immunogens and entry inhibitors.

Inhibition of HIV-1 gene expression by novel DNA enzymes targeted to cleave HIV-1 TAR RNA: potential effectiveness against all HIV-1 isolates.

Nucleic acid-based antiviral approaches have been tried against multiple HIV-1 genes with the purpose of down-regulating its replication. A unique stem-loop structure called TAR is present at the 5'-end of all HIV-1 transcripts; Tat and other cellular proteins bind to TAR and thus govern transcription. Therefore, HIV-1 TAR is an attractive target against which various antiviral approaches could be tried. We screened several DNA enzymes (Dz's) containing the 10-23 catalytic motif and a single Dz containing the 8-17 catalytic motif against the HIV-1 TAR RNA. Dz's directed against the predicted single-stranded bulge regions showed sequence-specific cleavage activities. One of the two Dz's, namely Dz-475, showed moderate cleavage activity in complete absence of Mg(2+). Addition of unrelated sequences at the 5'-end of the HIV-1 TAR RNA rendered it susceptible to four additional Dz-mediated cleavages. Both Dz's (470 and 475) showed significant intracellular reduction of HIV-1 gene expression. Dz-475-treated cells showed significant protection against T-tropic and macrophage-tropic HIV-1 challenge. Dz-475-transfected T-lymphocytes, human PBMCs, or chronically infected cell lines showed marked viral resistance. Unique features of this antiviral strategy with respect to HIV-1 gene inhibition are discussed.

Identification of cleavage sites in the HIV-1 TAR RNA by 10-23 and 8-17 catalytic motif containing DNA enzymes.

A quick identification of a cleavage site in the target RNA molecule to obtain sequence-specific cleavage by either catalytic RNA (ribozymes) or DNA (DNA enzymes) is very important for achieving gene-specific suppression. These molecules could also provide important information on the secondary and tertiary structure of the target RNA molecule. We have exploited the use of two kinds of DNA enzymes, namely, the 10-23 and 8-17 catalytic motif containing DNA enzymes, to achieve these objectives. We identified several DNA enzyme cleavage sites in the human immunodeficiency virus type 1 (HIV-1) transactivation response element (TAR) RNA-a structural feature present at the 5' end of all HIV-1 transcripts. Most of the DNA enzymes that cleaved the TAR RNA were targeted to the regions that were single-stranded in the predicted structure. Regions that were predicted to be base-paired (stem) failed to show any detectable cleavage. The DNA enzyme possessing the 8-17 catalytic motif was extremely efficient in cleaving full length, as well as short, HIV-1 specific transcripts. The efficiency of cleavage of the same target RNA by DNA enzymes that possessed the 10-23 catalytic motif was significantly less in comparison, and they failed to cleave the short transcripts. These molecules, in principle, have the potential to down regulate expression of all HIV-1 transcripts from a wide range of isolates because this region is functionally very well conserved.