Structure-activity relationships of 4-hydroxy-4-biaryl-proline acylsulfonamide tripeptides: A series of potent NS3 protease inhibitors for the treatment of hepatitis C virus

The design and synthesis of a series of tripeptide acylsulfonamides as potent inhibitors of the HCV NS3/4A serine protease is described. These analogues house a C4 aryl, C4 hydroxy-proline at the S2 position of the tripeptide scaffold. Information relating to structure-activity relationships as well as the pharmacokinetic and cardiovascular profiles of these analogues is provided.     

The Transition of Closely Opposed Lesions to Double-Strand Breaks during Long-Patch Base Excision Repair Is Prevented by the Coordinated Action of DNA Polymerase δ and Rad27/Fen1

DNA double-strand breaks can result from closely opposed breaks induced directly in complementary strands. Alternatively, double-strand breaks could be generated during repair of clustered damage, where the repair of closely opposed lesions has to be well coordinated. Using single and multiple mutants of Saccharomyces cerevisiae (budding yeast) that impede the interaction of DNA polymerase δ and the 5′-flap endonuclease Rad27/Fen1 with the PCNA sliding clamp, we show that the lack of coordination between these components during long-patch base excision repair of alkylation damage can result in many double-strand breaks within the chromosomes of nondividing haploid cells. This contrasts with the efficient repair of nonclustered methyl methanesulfonate-induced lesions, as measured by quantitative PCR and S1 nuclease cleavage of single-strand break sites. We conclude that closely opposed single-strand lesions are a unique threat to the genome and that repair of closely opposed strand damage requires greater spatial and temporal coordination between the participating proteins than does widely spaced damage in order to prevent the development of double-strand breaks.Endogenous metabolism or environmental factors such as oxidizing and alkylating agents can produce a wide variety of lesions in DNA. The genomes of mammalian cells experience from 10,000 to as many as 200,000 modifications per day (37, 44). Most lesions are repaired by a complex network of proteins that are part of an elaborate, multistep base excision repair (BER) system that generates single-strand break (SSB) intermediates. Importantly, defects in BER can lead to malignancies and can be associated with age-associated disease, especially neurodegeneration (60).BER is initiated by specific DNA N-glycosylases that remove damaged bases, yielding apurinic/apyrimidinic (AP) sites. Subsequent incision by AP endonucleases results in SSBs, and excision results in a single base gap as a repair intermediate (33, 53). SSBs are expected to be frequent in the genome due to the abundance of base damage as well as intermediates of repair, recombination, replication, and other DNA transactions (15, 16). Because they are generally repaired efficiently by BER and SSB repair enzymes (16, 57), SSBs per se may not be a major source of genome instability. However, if lesions are clustered, the formation of two closely spaced SSBs on opposing strands (or a single SSB and a modified nucleotide or AP site) might pose a special risk in terms of the potential to generate mutations or the possibility of conversion to double-strand breaks (DSBs), which are potent genotoxic lesions. Clustered lesions can arise within cells by chance association of random DNA lesions in a small region or the induction of multiple events in a narrow region, as found for ionizing radiation and various chemicals, such as those used in cancer treatments (47, 58, 59). While efficient BER is important for genome integrity, the repair must be well coordinated to avoid the generation of closely opposed SSB intermediates at closely spaced lesions that could result in the secondary generation of DSBs, especially since cells have limited DSB repair capacity (<50 DSBs/cell in the case of Saccharomyces cerevisiae) (48). While the impact of clustered lesions on repair of DNA has been examined in vitro by use of purified enzymes or cell extracts (13, 14, 27, 39, 56), there has been little opportunity to address specifically the repair of clustered lesions, except for those arising from UV damage (49).Whether formed directly from sugar damage or as BER intermediates, SSBs formed during the repair of base damage often possess 5′-deoxyribose phosphate (5′-dRP) ends that are not suitable for rejoining by DNA ligases (9, 15). In humans, removal and repair of 5′-dRP are accomplished by different combinations of proteins (3, 15) that result in short-patch repair, involving replacement of a single nucleotide (nt), or long-patch repair, involving 2 to 10 nt. The budding yeast Saccharomyces cerevisiae lacks a DNA polymerase β that provides AP lyase activity required for short-patch repair in mammalian cells. Instead, removal and repair of a 5′-dRP rely on the long-patch pathway, involving the successive actions of DNA polymerase δ (Pol δ) for strand displacement, the Rad27/Fen1 endonuclease to remove 5′ flaps, and DNA ligase (Cdc9) to rejoin the resulting nicks (9). The sliding clamp protein PCNA, which interacts with all three players, has been proposed to play a central role in coordinating these processes (18, 19, 34). The coupling between the strand displacement reaction by Pol δ and the flap cutting reaction by Fen1 is highly efficient, with over 90% of the products released by Fen1 being mononucleotides (17).Although the coordination of Pol δ, PCNA, and Rad27/Fen1 provides efficient processing of individual lesions in DNA, closely opposed SSBs that arise during repair of base damage could manifest as DSBs, either directly or as a result of SSB processing. A DNA damaging agent that has been used frequently to characterize long- and short-patch BER is methyl methanesulfonate (MMS). Recently, we described the detection of closely opposed MMS-induced lesions in yeast (42). Since the closely opposed lesions might represent a special challenge to BER, we considered the possibility that they might specifically impact long-patch repair through Pol δ and/or coordination of events with Rad27/Fen1. Pol δ of S. cerevisiae is a heterotrimeric enzyme consisting of Pol3, Pol31, and Pol32 (23). The nonessential Pol32 subunit is involved in translesion DNA synthesis (TLS) (24, 30) and also break-induced replication (41). However, its role in other types of DNA repair remains unclear. Using our in vivo assay for specifically detecting closely spaced methylated DNA lesions (42) and SSBs, we examined the role of Pol32 as well as the cooperation between Pol δ, Rad27/Fen1, and PCNA in the repair of clustered DNA lesions induced by MMS in G₁ stationary-phase haploid yeast. We found that Pol32 plays an important role in ensuring that clustered lesions are efficiently repaired and do not transition to DSBs.     

Analysis of secondary structure and self‐assembly of amelogenin by variable temperature circular dichroism and isothermal titration calorimetry

Amelogenin is a proline‐rich enamel matrix protein known to play an important role in the oriented growth of enamel crystals. Amelogenin self‐assembles to form nanospheres and higher order structures mediated by hydrophobic interactions. This study aims to obtain a better insight into the relationship between primary–secondary structure and self‐assembly of amelogenin by applying computational and biophysical methods. Variable temperature circular dichroism studies indicated that under physiological pH recombinant full‐length porcine amelogenin contains unordered structures in equilibrium with polyproline type II (PPII) structure, the latter being more populated at lower temperatures. Increasing the concentration of rP172 resulted in the promotion of folding to an ordered β‐structured assembly. Isothermal titration calorimetry dilution studies revealed that at all temperatures, self‐assembly is entropically driven due to the hydrophobic effect and the molar heat of assembly (ΔH_A) decreases with temperature. Using a computational approach, a profile of domains in the amino acid sequence that have a high propensity to assemble and to have PPII structures has been identified. We conclude that the assembly properties of amelogenin are due to complementarity between the hydrophobic and PPII helix prone regions. Proteins 2009. © 2009 Wiley‐Liss, Inc.     

Cell Proliferation and Epidermal Growth Factor Signaling in Non-small Cell Lung Adenocarcinoma Cell Lines Are Dependent on Rin1

Rin1 is a Rab5 guanine nucleotide exchange factor that plays an important role in Ras-activated endocytosis and growth factor receptor trafficking in fibroblasts. In this study, we show that Rin1 is expressed at high levels in a large number of non-small cell lung adenocarcinoma cell lines, including Hop62, H650, HCC4006, HCC827, EKVX, HCC2935, and A549. Rin1 depletion from A549 cells resulted in a decrease in cell proliferation that was correlated to a decrease in epidermal growth factor receptor (EGFR) signaling. Expression of wild type Rin1 but not the Rab5 guanine nucleotide exchange factor-deficient Rin1 (Rin1Δ) complemented the Rin1 depletion effects, and overexpression of Rin1Δ had a dominant negative effect on cell proliferation. Rin1 depletion stabilized the cell surface levels of EGFR, suggesting that internalization was necessary for robust signaling in A549 cells. In support of this conclusion, introduction of either dominant negative Rab5 or dominant negative dynamin decreased A549 proliferation and EGFR signaling. These data demonstrate that proper internalization and endocytic trafficking are critical for EGFR-mediated signaling in A549 cells and suggest that up-regulation of Rin1 in A549 cell lines may contribute to their proliferative nature.Internalization of epidermal growth factor receptors (EGFR)² and their subsequent delivery to lysosomes play key roles in attenuating EGF-mediated signaling cascades (1, 2). The proper delivery of EGFR into lysosomes for degradation requires a series of highly regulated targeting and delivery events. Following ligand binding, EGFR is internalized via endocytic vesicles that are subsequently targeted to early endosomes. This targeting event is mediated by the small GTPase, Rab5 (3, 4). Once delivered to the early endosome, receptors that are destined for degradation are incorporated into vesicles that bud into the lumen of the endosome, forming the multivesicular body (reviewed in Refs. 5, 6). Sequestration of the activated cytoplasmic domain of EGFR into the intralumenal vesicles of the multivesicular body effectively terminates receptor signaling (7). Subsequent fusion of the multivesicular body with lysosomes delivers the intralumenal vesicles and their contents into the lumen of the lysosome where they are degraded (reviewed in Refs. 8–10). Inactivating mutations in Rab5 disrupt the delivery of cell surface receptors, such as EGFR, to early endosomes, thereby inhibiting receptor trafficking to the lysosome and receptor degradation (11, 12). Therefore, activation of Rab5 is a key point of regulation for EGFR signaling.Rab5 cycles between an inactive GDP-bound state and an active GTP-bound state, and Rab5 activation requires the exchange of GDP to GTP. This exchange is catalyzed by guanine nucleotide exchange factors (GEFs) that are specific to the Rab5 family of proteins (reviewed in Ref. 13). Rab5 family GEFs all contain a catalytic vacuolar protein sorting 9 (Vps9) domain that facilitates the GDP to GTP exchange (14–17). Many Rab5 GEFs contain other functional domains that are involved in cell signaling events (13). Rin1 is a good example of a multidomain Rab5 GEF. In addition to the Vps9 domain, Rin1 also contains an Src homology 2 domain, a proline-rich domain, and a Ras association domain. Rin1 was originally identified through its ability to interact with active Ras (18), and a role for Rin1 in a number of cell signaling systems has been established, including EGF-mediated signaling (19–21). Rin1 directly interacts with the activated EGFR through its Src homology 2 domain (22). Furthermore, Ras occupation of the Rin1 Ras association domain positively impacts the Rab5 GEF activity of Rin1, which promotes EGFR internalization and attenuation in fibroblasts (23). However, Rin1 expression is up-regulated in several types of cancers, including squamous cell carcinoma (24), colorectal cancer (25), and cervical cancer (26), through duplications or rearrangements of the RIN1 locus. These studies suggest that Rin1 may also play a role in enhancing cell proliferation.It is well established that a large percentage of non-small cell lung adenocarcinomas exhibit up-regulation of EGFR and aberrant signaling through the Ras/MAPK pathway (reviewed in Ref. 27). In addition, a recent study examining 188 human lung adenocarcinomas identified that 132 of 188 tumor samples exhibited mutations relating to the Ras/MAPK signaling pathway (28). Accordingly, the role of Rin1 in non-small cell lung adenocarcinoma was addressed. Examination of a panel of non-small cell lung adenocarcinoma lines (including A549) revealed enhanced Rin1 expression relative to a nontransformed lung epithelial cell line (BEAS-2B). Depletion of Rin1 from A549 cells resulted in decreased proliferation. This decrease correlated with a reduction in EGF-activated ERK phosphorylation and the stabilization of cell surface EGFR. These defects were complemented by wild type Rin1 expression but not by mutant Rin1 lacking a functional Vps9 domain, suggesting that the GEF activity of Rin1 is necessary for proper EGFR signaling in A549 cells. In addition, overexpression of Rin1Δ, dominant negative Rab5, and dynamin resulted in similar defects in cell proliferation and EGFR signaling as Rin1 depletion. These data indicate that proper EGFR internalization and trafficking are critical for robust EGFR-mediated signaling and cell proliferation in A549 cells and offer evidence that Rin1 positively regulates cell proliferation in non-small cell lung adenocarcinoma.     

Interaction of chromium(III) complex of chiral binaphthyl tetradentate ligand with DNA

Since conformation of the molecule plays a vital role in the activity of drug, we have investigated the DNA interaction of a chromium(III) complex with ligands in two conformations. Chromium(III) complexes derived from chiral binaphthyl Schiff base ligands, viz. R- and S-2,2'-bis(salicylideneamino) 1,1'-binaphthyl, have been synthesized and characterized by mass, IR, and electronic spectra. The interaction of these R- and S-binaphthyl Schiff base chromium(III) complexes with CT-DNA was investigated with the goal of examining whether the chirality has an influence on the chromium(III)-DNA binding properties. The difference in chirality of the ligand did not show any striking difference in binding properties. The binding constants for R and S conformers were estimated to be 18 (+/-0.4) x 10(3) and 9.4 (+/-0.3) x 10(3) M(-1), respectively, through spectroscopic titrations. All the experimental results are suggestive that both the isomers are DNA groove binders. The results of steady-state as well as time-resolved fluorescence experiments, however, suggest that the R conformer has restricted mobility when bound to DNA because it is more deeply buried in the groove of DNA compared to the S isomer.     

Catalytic site modifications of TAP1 and TAP2 and their functional consequences

The transporter associated with antigen processing (TAP), a member of the ATP binding cassette (ABC) family of transmembrane transporters, transports peptides across the endoplasmic reticulum membrane for assembly of major histocompatibility complex class I molecules. Two subunits, TAP1 and TAP2, are required for peptide transport, and ATP hydrolysis by TAP1.TAP2 complexes is important for transport activity. Two nucleotide binding sites are present in TAP1.TAP2 complexes. Compared with other ABC transporters, the first nucleotide binding site contains non-consensus catalytic site residues, including Asp(668) in the Walker B region of TAP1 (in place of a highly conserved glutamic acid), and Gln(701) in the switch region of TAP1 (in place of a highly conserved histidine). At the second nucleotide binding site, a glutamic acid (TAP2 Glu(632)) follows the Walker B motif, and the switch region contains a histidine (TAP2 His(661)). We found that alterations at Glu(632) and His(661) of TAP2 significantly reduced peptide translocation and/or TAP-induced major histocompatibility complex class I surface expression. Alterations of TAP1 Asp(668) alone or in combination with TAP1 Gln(701) had only small effects on TAP activity. Thus, the naturally occurring Asp(668) and Gln(701) alterations of TAP1 are likely to contribute to attenuated catalytic activity at the first nucleotide binding site (the TAP1 site) of TAP complexes. Due to its enhanced catalytic activity, the second nucleotide binding site (the TAP2 site) appears to be the main site driving peptide transport. A mechanistic model involving one main active site is likely to apply to other ABC transporters that have an asymmetric distribution of catalytic site residues within the two nucleotide binding sites.     

Polyphosphate kinase from M. tuberculosis: an interconnect between the genetic and biochemical role

The enzyme Polyphosphate Kinase (PPK) catalyses the reversible transfer of the terminal γ-Pi of ATP to form a long chain Polyphosphate (PolyP). Using an IPTG inducible mycobacterial vector, the vulnerability of this gene has been evaluated by antisense knockdown experiments in M. tuberculosis. Expression profiling studies point to the fact that down regulation of PPK caused cidality during the late phase in contrast to its bacteriostatic mode immediately following antisense expression. PPK thus seems to be a suitable anti-tubercular drug target. The enzyme which is a tetramer has been cloned in E. coli and purified to homogeneity. An enzyme assay suitable for High Throughput Screening was optimized by using the statistical Taguchi protocol and the kinetic parameters determined. The enzyme displayed a strong product inhibition by ADP. In order to accurately estimate the product inhibition, progress curve analysis of the enzyme reaction was monitored. The kinetic equation describing the progress curve was suitably modified by taking into account the product inhibition. The reversible nature of the enzyme indicated a possibility of a two way ATP↔ADP switch operating in the bacteria as a response to its growth requirement.