Molecular basis of TASL recruitment by the peptide/histidine transporter 1, PHT1.

PHT1 is a histidine /oligopeptide transporter with an essential role in Toll-like receptor innate immune responses. It can act as a receptor by recruiting the adaptor protein TASL which leads to type I interferon production via IRF5. Persistent stimulation of this signalling pathway is known to be involved in the pathogenesis of systemic lupus erythematosus (SLE). Understanding how PHT1 recruits TASL at the molecular level, is therefore clinically important for the development of therapeutics against SLE and other autoimmune diseases. Here we present the Cryo-EM structure of PHT1 stabilized in the outward-open conformation. By combining biochemical and structural modeling techniques we propose a model of the PHT1-TASL complex, in which the first 16 N-terminal TASL residues fold into a helical structure that bind in the central cavity of the inward-open conformation of PHT1. This work provides critical insights into the molecular basis of PHT1/TASL mediated type I interferon production.

Identification and Optimization of EphA2-Selective Bicycles for the Delivery of Cytotoxic Payloads.

Bicycles are constrained bicyclic peptides that represent a promising binding modality for use in targeted drug conjugates. A phage display screen against EphA2, a receptor tyrosine kinase highly expressed in a number of solid tumors, identified a number of Bicycle families with low nanomolar affinity. A Bicycle toxin conjugate (BTC) was generated by derivatization of one of these Bicycles with the potent cytotoxin DM1 via a cleavable linker. This BTC demonstrated potent antitumor activity in vivo but was poorly tolerated, which was hypothesized to be the result of undesired liver uptake caused by poor physicochemical properties. Chemical optimization of a second Bicycle, guided by structural biology, provided a high affinity, metabolically stable Bicycle with improved physicochemical properties. A BTC incorporating this Bicycle also demonstrated potent antitumor activity and was very well tolerated when compared to the initial BTC. Phage display selection followed by chemical optimization of Bicycles can deliver potent drug conjugates with favorable pharmaceutical properties.

Bicyclic Peptides as a New Modality for Imaging and Targeting of Proteins Overexpressed by Tumors.

Molecular imaging of cancers using probes specific for tumor-associated target proteins offers a powerful solution for providing information regarding selection of targeted therapy, patient stratification, and response to therapy. Here we demonstrate the power of bicyclic peptides as targeting probes, exemplified with the tumor-overexpressed matrix metalloproteinase MT1-MMP as a target. A bicyclic peptide with subnanomolar affinity towards MT1-MMP was identified, and its radioconjugate showed selective tumor uptake in an HT1080 xenograft mouse model. Proteolytic stabilization of the peptide by chemical modification significantly enhanced the in vivo tumor signal [from 2.5%ID/g to 12%ID/g at 1 hour post injection (p.i.)]. Studies using mouse xenograft models with different cell lines show a robust correlation between tumor signals and in vivo MT1-MMP expression levels. Fatty acid modification of the bicyclic peptide extended its circulating half-life, resulting in increased tumor signals (36%ID/g at 6 hours p.i.). Comparative work with an equipotent radiolabeled MT1-MMP targeting antibody demonstrated starkly differential biodistribution and tumor accumulation properties, with the tumor signal slowly increasing to 6.2%ID/g within 48 hours. The rapid tumor penetration characteristics of bicyclic peptides, coupled with high potency and chemical versatility, thus offer high-contrast imaging probes for clinical diagnostics with compelling additional potential in targeted therapy.Significance: This work demonstrates the potential of bicyclic peptides as a platform for the development of high-contrast imaging probes for potential use in clinical cancer diagnostics and molecularly targeted therapeutics.

Stable and Long-Lasting, Novel Bicyclic Peptide Plasma Kallikrein Inhibitors for the Treatment of Diabetic Macular Edema.

Plasma kallikrein, a member of the kallikrein-kinin system, catalyzes the release of the bioactive peptide bradykinin, which induces inflammation, vasodilation, vessel permeability, and pain. Preclinical evidence implicates the activity of plasma kallikrein in diabetic retinopathy, which is a leading cause of visual loss in patients suffering from diabetes mellitus. Employing a technology based on phage-display combined with chemical cyclization, we have identified highly selective bicyclic peptide inhibitors with nano- and picomolar potencies toward plasma kallikrein. Stability in biological matrices was either intrinsic to the peptide or engineered via the introduction of non-natural amino acids and nonpeptidic bonds. The peptides prevented bradykinin release in vitro, and in vivo efficacy was demonstrated in both a rat paw edema model and in rodent models of diabetes-induced retinal permeability. With a highly extended half-life of ∼40 h in rabbit eyes following intravitreal administration, the bicyclic peptides are promising novel agents for the treatment of diabetic retinopathy and diabetic macular edema.

Molecular basis for modulation of the p53 target selectivity by KLF4.

The tumour suppressor p53 controls transcription of various genes involved in apoptosis, cell-cycle arrest, DNA repair and metabolism. However, its DNA-recognition specificity is not nearly sufficient to explain binding to specific locations in vivo. Here, we present evidence that KLF4 increases the DNA-binding affinity of p53 through the formation of a loosely arranged ternary complex on DNA. This effect depends on the distance between the response elements of KLF4 and p53. Using nuclear magnetic resonance and fluorescence techniques, we found that the amino-terminal domain of p53 interacts with the KLF4 zinc fingers and mapped the interaction site. The strength of this interaction was increased by phosphorylation of the p53 N-terminus, particularly on residues associated with regulation of cell-cycle arrest genes. Taken together, the cooperative binding of KLF4 and p53 to DNA exemplifies a regulatory mechanism that contributes to p53 target selectivity.

Backbone-driven collapse in unfolded protein chains.

Collapse of unfolded protein chains is an early event in folding. It affects structural properties of intrinsically disordered proteins, which take a considerable fraction of the human proteome. Collapse is generally believed to be driven by hydrophobic forces imposed by the presence of nonpolar amino acid side chains. Contributions from backbone hydrogen bonds to protein folding and stability, however, are controversial. To date, the experimental dissection of side-chain and backbone contributions has not yet been achieved because both types of interactions are integral parts of protein structure. Here, we realized this goal by applying mutagenesis and chemical modification on a set of disordered peptides and proteins. We measured the protein dimensions and kinetics of intra-chain diffusion of modified polypeptides at the level of individual molecules using fluorescence correlation spectroscopy, thereby avoiding artifacts commonly caused by aggregation of unfolded protein material in bulk. We found no contributions from side chains to collapse but, instead, identified backbone interactions as a source sufficient to form globules of native-like dimensions. The presence of backbone hydrogen bonds decreased polypeptide water solubility dramatically and accelerated the nanosecond kinetics of loop closure, in agreement with recent predictions from computer simulation. The presence of side chains, instead, slowed loop closure and modulated the dimensions of intrinsically disordered domains. It appeared that the transient formation of backbone interactions facilitates the diffusive search for productive conformations at the early stage of folding and within intrinsically disordered proteins.

S100 proteins interact with the N-terminal domain of MDM2.

S100 proteins interact with the transactivation domain and the C-terminus of p53. Further, S100B has been shown to interact with MDM2, a central negative regulator of p53. Here, we show that S100B bound directly to the folded N-terminal domain of MDM2 (residues 2-125) by size exclusion chromatography and surface plasmon resonance experiments. This interaction with MDM2 (2-125) is a general feature of S100 proteins; S100A1, S100A2, S100A4 and S100A6 also interact with MDM2 (2-125). These interactions with S100 proteins do not result in a ternary complex with MDM2 (2-125) and p53. Instead, we observe the ability of a subset of S100 proteins to disrupt the extent of MDM2-mediated p53 ubiquitylation in vitro.

Posttranslational modifications affect the interaction of S100 proteins with tumor suppressor p53.

Proteins of the S100 family bind to the intrinsically disordered transactivation domain (TAD; residues 1-57) and C-terminus (residues 293-393) of the tumor suppressor p53. Both regions provide sites that are subject to posttranslational modifications, such as phosphorylation and acetylation, that can alter the affinity for interacting proteins such as p300 and MDM2. Here, we found that S100A1, S100A2, S100A4, S100A6, and S100B bound to two subdomains of the TAD (TAD1 and TAD2). Both subdomains were mandatory for high-affinity binding to S100 proteins. Phosphorylation of Ser and Thr residues increased the affinity for the p53 TAD. Conversely, acetylation and phosphorylation of the C-terminus of p53 decreased the affinity for S100A2 and S100B. In contrast, we found that nitrosylation of S100B caused a minor increase in binding to the p53 C-terminus, whereas binding to the TAD remained unaffected. As activation of p53 is usually accompanied by phosphorylation and acetylation at several sites, our results suggest that a shift in binding from the C-terminus in favor of the N-terminus occurs upon the modification of p53. We propose that binding to the p53 TAD might be involved in the stimulation of p53 activity by S100 proteins.

Interaction between the transactivation domain of p53 and PC4 exemplifies acidic activation domains as single-stranded DNA mimics.

The tumor suppressor p53 regulates cell cycle arrest and apoptosis by transactivating several genes that are critical for these processes. The transcriptional activity of p53 is often regulated by post-translational modifications and its interactions with various transcriptional coactivators. Here we report a physical interaction between the N-terminal transactivation domain (TAD) of p53 and the C-terminal DNA-binding domain of positive cofactor 4 (PC4(CTD)). Using NMR spectroscopy, we showed that residues 35-57 (TAD2) interact with PC4. (15)N,(1)H HSQC and fluorescence competition experiments indicated that TAD binds to the DNA-binding site of PC4. Hepta-phosphorylation of the TAD peptide increased its binding affinity. Computer modeling of the p53N-PC4 complex revealed several important interactions that are reminiscent of those in the single-stranded DNA-PC4 complex. The ubiquitous nature of the acidic transactivation domain of p53 in mediating interactions with several transcription cofactors is also manifested as a DNA mimetic.

Molecular basis of the interactions between the p73 N terminus and p300: effects on transactivation and modulation by phosphorylation.

The transcription factor p73 belongs to the p53 family of proteins and can transactivate a number of target genes in common with p53. Here, we characterized the interaction of the p73 N terminus with four domains of the transcriptional coactivator p300 and with the negative regulator Mdm2 by using biophysical and cellular measurements. We found that, like p53, the N terminus of p73 contained two distinct transactivation subdomains, comprising residues 10-30 and residues 46-67. The p73 N terminus bound weakly to the Taz1, Kix, and IBiD domains of p300 but with submicromolar affinity for Taz2, in contrast to previous reports. We found weaker binding of the p73 N terminus to the p300 domains in vitro correlated with a significant decrease in transactivation activity in a cell line for the QS and T14A mutants, and tighter binding of the phosphomimetic T14D in vitro correlated with an increase in vivo. Further, we found that phosphorylation of T14 increased the affinity of the p73 N terminus for Taz2 10-fold. The phosphomimetic p73alpha T14D caused increased levels of transactivation.

Downhill versus barrier-limited folding of BBL 2: mechanistic insights from kinetics of folding monitored by independent tryptophan probes.

Barrier-free downhill folding has been proposed for the peripheral subunit-binding domain BBL. To date, ultrafast kinetic experiments on BBL, which are crucial for a mechanistic understanding of folding, have been hampered by the lack of good intrinsic spectroscopic probes. Here, we present a detailed kinetic characterization of three single-point tryptophan mutants of BBL that have suitable fluorescence properties for following microsecond and nanosecond folding kinetics using temperature jump fluorescence spectroscopy. Experiments were performed at pH 7, which is optimal for stability and minimizes complications that arise from the presence of an alternative native-state conformation of BBL at lower pH. We examined the dependence of rate and equilibrium constants on concentration of denaturant and found that they follow well-established laws allowing kinetic transients to be related to events in folding and compared with equilibrium data. Logarithms of rate constants versus denaturant concentration yielded plots (chevrons) that are characteristic of barrier-limited folding for all mutants investigated, including a truncated sequence that was previously used in the proposal of downhill folding. The thermodynamic quantities calculated from the rate constants were in excellent agreement with those directly determined from equilibrium denaturation based on empirical two-state equations. We found that sequence truncation of BBL as used in studies proposing downhill folding leads to a large loss in helical content and protein stability, which were exacerbated at the low pH used in those studies. The kinetics and equilibria of folding of BBL fit to conventional barrier-limited kinetics.

Four domains of p300 each bind tightly to a sequence spanning both transactivation subdomains of p53.

The transcriptional coactivator p300 binds to and mediates the transcriptional functions of the tetrameric tumor suppressor p53. Both proteins consist of independently folded domains linked by intrinsically disordered sequences. A well studied short sequence of the p53 transactivation domain, p53(15-29), binds weakly to four folded domains of p300 [Taz1/cysteine-histidine-rich region 1 (CH1), Kix, Taz2/CH3, IBiD], with dissociation constants (K(D)) in the 100 muM region. However, we found that a longer N-terminal transactivation domain construct p53(1-57) bound tightly to each p300 domain. Taz2/CH3 had the greatest affinity (K(D) = 27 nM) and competes with the N-terminal domain of Mdm2 for the p53 N terminus. p300 thus can protect the N terminus of p53 against the binding of other proteins. Mutations of p53 that abrogate transactivation (L22Q/W23S, W53Q/F54S) greatly weakened binding to each p300 domain, linking phenotypic defects to weakened coactivator binding. We propose a complex between tetrameric p53 and p300 in which four domains of p300 wrap around the four transactivation domains of p53.

Mutational analysis of the complex of human RNase inhibitor and human eosinophil-derived neurotoxin (RNase 2).

RNase inhibitor (RI) binds diverse proteins in the pancreatic RNase superfamily with extremely high avidity. Previous studies showed that tight binding of RNase A and angiogenin (Ang) is achieved primarily through interactions of hot spot residues in the 434-460 C-terminal segment of RI with the enzymatic active site; Asp435 of RI forms key hydrogen bonds with the catalytic lysine in both complexes, whereas the other contacts are largely distinctive. Here we have investigated the structural basis for recognition of a third ligand, eosinophil-derived neurotoxin (EDN), by single-site and multisite mutagenesis. Surprisingly, Ala replacement of Asp435 decreases affinity for EDN only by 14-fold, as compared to the several hundred-fold decreases with RNase A and Ang, and individual mutations of three other hot spot residues-Tyr434, Tyr437, and Ser460-have essentially no effect. Ala substitutions of nine additional residues, selected by examining a computational model of the RI.EDN complex, also have no marked impact. Overall, the losses in affinity for the single-residue variants examined account for only approximately 25% of the free energy of binding for the complex. However, multisite mutagenesis of RI reveals strong superadditivity of mutational effects, indicating that part of this shortfall reflects negative cooperativity. Replacement of Tyr434 together with Asp435 or Tyr437 increases K(i) by 540- and 290-fold, respectively. Thus, the C-terminal region of RI again plays an important role in ligand recognition, although probably smaller than for binding RNase A and Ang. Simultaneous substitutions of three neighboring tryptophans (261, 263, and 318) on RI attenuate affinity even more dramatically (by 4900-fold), indicating that the interactions of this RI region also contribute a considerable amount of the binding energy for the EDN complex. These findings highlight the potential importance of cooperativity in protein-protein interactions and the consequent limitations of single-site mutagenesis for assessing interface energetics.