Intrinsically disordered proteins (IDPs) or regions (IDRs) in proteins hold many functions but their biological roles are still not fully understood. Here we describe a new role of such regions. Using the HIV-1 Rev protein, we show that disordered domains have a role in maintaining the correct oligomeric state and the thermodynamic stability of proteins.

We present a new approach for peptide cyclization during solid phase synthesis under highly acidic conditions. Our approach involves simultaneous in situ deprotection, cyclization and trifluoroacetic acid (TFA) cleavage of the peptide, which is achieved by forming an amide bond between a lysine side chain and a succinic acid linker at the peptide N-terminus. The reaction proceeds via a highly active succinimide intermediate, which was isolated and characterized. The structure of a model cyclic peptide was solved by NMR spectroscopy. Theoretical calculations support the proposed mechanism of cyclization. Our new methodology is applicable for the formation of macrocycles in solid-phase synthesis of peptides and organic molecules.

Occurrence of DNA damage in a cell activates the DNA damage response, a survival mechanism that ensures genomics stability. Two key members of the DNA damage response are the tumor suppressor p53, which is the most frequently mutated gene in cancers, and MDC1, which is a central adaptor that recruits many proteins to sites of DNA damage. Here we characterize the in vitro interaction between p53 and MDC1 and demonstrate that p53 and MDC1 directly interact. The p53-MDC1 interaction is mediated by the tandem BRCT domain of MDC1 and the C-terminal domain of p53. We further show that both acetylation of lysine 382 and phosphorylation of serine 392 in p53 enhance the interaction between p53 and MDC1. Additionally, we demonstrate that the p53-MDC1 interaction is augmented upon the induction of DNA damage in human cells. Our data suggests a new role for acetylation of lysine 382 and phosphorylation of serine 392 in p53 in the cellular stress response and offers the first evidence for an interaction involving MDC1 that is modulated by acetylation.

The motor protein nonmuscle myosin II (NMII) must undergo dynamic oligomerization into filaments to perform its cellular functions. A small nonhelical region at the tail of the long coiled-coil region (tailpiece) is a common feature of all dynamically assembling myosin II proteins. This tailpiece is a key regulatory domain affecting NMII filament assembly properties and is subject to phosphorylation in vivo. We previously demonstrated that the positively charged region of the tailpiece binds to assembly-incompetent NMII-C fragments, inducing filament assembly. In the current study, we investigated the molecular mechanisms by which the tailpiece regulates NMII-C self-assembly. Using alanine scan, we found that specific positive and aromatic residues within the positively charged region of the tailpiece are important for inducing NMII-C filament assembly and for filament elongation. Combining peptide arrays with deletion studies allowed us to identify the tailpiece binding sites in the coiled-coil rod. Elucidation of the mechanism by which the tailpiece induces filament assembly permitted us further investigation into the role of tailpiece phosphorylation. Sedimentation and CD spectroscopy identified that phosphorylation of Thr¹⁹⁵⁷ or Thr¹⁹⁶⁰ inhibited the ability of the tailpiece to bind the coiled-coil rod and to induce NMII-C filament formation. This study provides molecular insight into the role of specific residues within the NMII-C tailpiece that are responsible for shifting the oligomeric equilibrium of NMII-C toward filament assembly and determining its morphology.

Integration of the HIV cDNA into the host chromosome is a key event in the viral replication cycle. It is mediated by the viral integrase (IN) enzyme, which is an attractive anti-HIV drug target. Here we present the first AFM imaging of IN-mediated DNA integration products in a two-LTR system.

ASPP2 is a key protein in regulating apoptosis both in p53-dependent and-independent pathways. The C-terminal part of ASPP2 contains four ankyrin repeats and an SH3 domain (Ank-SH3) that mediate the interactions of ASPP2 with apoptosis related proteins such as p53, Bcl-2 and the p65 subunit of NFκB. p53 core domain (p53CD) binds the n-src loop and the RT loop of ASPP2 SH3. ASPP2 contains a disordered proline rich domain (ASPP2 Pro) that forms an intramolecular autoinhibitory interaction with the Ank-SH3 domains. Here we show how this intramolecular interaction affects the intermolecular interactions of ASPP2 with p53, Bcl-2 and NFkB. We used biophysical methods to obtain better understanding of the relationship between ASPP2 and its partners for getting a comprehensive view on ASPP2 pathways. Fluorescence anisotropy competition experiments revealed that both ASPP2 Pro and p53CD competed for binding the n-src loop of the ASPP2 SH3, indicating regulation of p53CD binding to this loop by ASPP2 Pro. Peptides derived from the ASPP2-binding interface of Bcl-2 did not compete with p53CD or NFkB peptides for binding the ASPP2 n-src loop. However, p53CD displaced the NFκB peptide (residues 303–332) from its complex with ASPP2 Ank-SH3, indicating that NFκB 303–332 and p53CD bind a partly overlapping site in ASPP2 SH3, mostly in the RT loop. These results are in agreement with previous docking studies, which showed that ASPP2 Ank-SH3 binds Bcl-2 and NFκB mostly via distinct sites from p53. However they show some overlap between the binding sites of p53CD and NFkB in ASPP2 Ank-SH3. Our results provide experimental evidence that the intramolecular interaction in ASPP2 regulates its binding to p53CD and that ASPP2 Ank-SH3 binds Bcl-2 and NFκB via distinct sites.

The STIL protein participates in mitosis and malignant transformation by regulating centrosomal duplication. Using biophysical methods we studied the structure and interactions of STIL. We revealed that its central domain is intrinsically disordered and mediates protein–protein interactions of STIL. The intrinsic disorder may provide STIL with the conformational flexibility required for its multitude binding.

Peptide arrays are a powerful tool for characterizing protein interactions and for identifying and optimizing peptide ligands. Here we demonstrate the use of peptide arrays for performing detailed SAR studies of lead peptide inhibitors of the interaction between the HIV integrase and Rev proteins. The integration of viral DNA into the genome of the host cell, mediated by the viral integrase (IN) enzyme, is a crucial step in the HIV-1 replication cycle. We have recently found that IN activity is regulated by interactions with the HIV-1 Rev protein and identified three lead peptides derived from the Rev-binding interface in IN. Due to their ability to promote dissociation of the Rev–IN complex in HIV infected cells, these peptides caused IN activation leading to multi-integration, genomic instability and specific eradication of such infected cells. Here we explored the mechanism of action of these three IN-derived peptides as the basis for developing improved anti HIV-1 leads. Using peptide array screening, we found that the IN derived peptides bound IN and Rev in a similar pattern. The Rev-binding sites in IN also mediate IN oligomerization while the IN-binding sites in Rev are also involved in Rev oligomerization. A structural homology was found between the oligomerization domains of Rev and IN residues 171–188 and 211–220. We performed SAR studies of the lead inhibitory peptides using a peptide array containing truncated peptides, alanine scan, D-amino acid scan and N-methylated amino acid scan. We screened IN and Rev for binding this array of modified IN-derived peptides. The screening results showed that C-terminal positively charged residues were essential for the interaction of the IN 118–128 and IN 174–188 peptides with both Rev and IN. The peptides could be shortened and modified without loss of binding to IN and Rev. This provides a basis for the future development of shorter peptides with better pharmacological properties that inhibit the Rev–IN interaction. We conclude that peptide arrays are excellent tools to perform detailed SAR binding studies in one short efficient experiment. The SAR study by the peptide array method is a powerful tool for developing improved inhibitors based on a lead peptide sequence.

CagA is a virulence factor that Helicobacter pylori inject into gastric epithelial cells through a type IV secretion system where it can cause gastric adenocarcinoma. Translocation is dependent on the presence of secretion signals found in both the N- and C-terminal domains of CagA and an interaction with the accessory protein CagF. However, the molecular basis of this essential protein-protein interaction is not fully understood. Herein we report, using isothermal titration calorimetry, that CagA forms a 1:1 complex with a monomer of CagF with nm affinity. Peptide arrays and isothermal titration calorimetry both show that CagF binds to all five domains of CagA, each with μm affinity. More specifically, a coiled coil domain and a C-terminal helix within CagF contacts domains II-III and domain IV of CagA, respectively. In vivo complementation assays of H. pylori with a double mutant, L36A/I39A, in the coiled coil region of CagF showed a severe weakening of the CagA-CagF interaction to such an extent that it was nearly undetectable. However, it had no apparent effect on CagA translocation. Deletion of the C-terminal helix of CagF also weakened the interaction with CagA but likewise had no effect on translocation. These results indicate that the CagA-CagF interface is distributed broadly across the molecular surfaces of these two proteins to provide maximal protection of the highly labile effector protein CagA.

Human apolipoprotein-B mRNA-editing catalytic polypeptide-like 3G (A3G) is a cytidine deaminase that restricts retroviruses, endogenous retro-elements and DNA viruses. A3G plays a key role in the anti-HIV-1 innate cellular immunity. The HIV-1 Vif protein counteracts A3G mainly by leading A3G towards the proteosomal machinery and by direct inhibition of its enzymatic activity. Both activities involve direct interaction between Vif and A3G. Disrupting the interaction between A3G and Vif may rescue A3G antiviral activity and inhibit HIV-1 propagation. Here, mapping the interaction sites between A3G and Vif by peptide array screening revealed distinct regions in Vif important for A3G binding, including the N-terminal domain (NTD), C-terminal domain (CTD) and residues 83–99. The Vif-binding sites in A3G included 12 different peptides that showed strong binding to either full-length Vif, Vif CTD or both. Sequence similarity was found between Vif-binding peptides from the A3G CTD and NTD. A3G peptides were synthesized and tested for their ability to counteract Vif action. A3G 211–225 inhibited HIV-1 replication in cell culture and impaired Vif dependent A3G degradation. In vivo co-localization of full-length Vif with A3G 211–225 was demonstrated by use of FRET. This peptide has the potential to serve as an anti-HIV-1 lead compound. Our results suggest a complex interaction between Vif and A3G that is mediated by discontinuous binding regions with different affinities.

Peptide cyclization is an important tool for overcoming the limitations of linear peptides as drugs. Backbone cyclization (BC) has advantages over side chain (SC) cyclization because it combines N-alkylation for extra peptide stability. However, the appropriate building blocks for BC are not yet commercially available. This problem can be overcome by preparing SC cyclic peptide analogs of the most active BC peptide using commercially available building blocks. We have recently developed BC peptides that inhibit the HIV-1 integrase enzyme (IN) activity and HIV-1 replication in infected cells. Here we used this system as a model for systematically comparing the BC and SC cyclization modes using biophysical, biochemical and structural methods. The most potent SC cyclic peptide was active almost as the BC peptide and inhibited IN activity in vitro and blocked IN activity in cells even after 6 days. We conclude that both cyclization types have their respective advantages: The BC peptide is more active and stable, probably due to the N-alkylation, while SC cyclic peptides are easier to synthesize. Due to the high costs and efforts involved in preparing BC peptides, SC may be a more approachable method in many cases. We suggest that both methods are interchangeable.

The molecular basis of the interaction between mitochondrial carrier homologue 2 (MTCH2) and truncated BID (tBID) was characterized. These proteins participate in the apoptotic pathway, and the interaction between them may serve as a target for anticancer lead compounds. In response to apoptotic signals, MTCH2 recruits tBID to the mitochondria, where it activates apoptosis. A combination of peptide arrays screening with biochemical and biophysical techniques was used to characterize the mechanism of the interaction between tBID and MTCH2 at the structural and molecular levels. The regions that mediate the interaction between the proteins were identified. The two specific binding sites between the proteins were determined to be tBID residues 59–73 that bind MTCH2 residues 140–161, and tBID residues 111–125 that bind MTCH2 residues 240–290. Peptides derived from tBID residues 111–125 and 59–73 induced cell death in osteosarcoma cells. These peptides may serve as lead compounds for anticancer drugs that act by targeting the tBID-MTCH2 interaction.

Purpose: XIAP [X-linked inhibitor of apoptosis (IAP) protein] is the best characterized mammalian caspase inhibitor. XIAP is frequently overexpressed in a variety of human tumors, and genetic inactivation of XIAP in mice protects against lymphoma. Therefore, XIAP is an attractive target for anticancer therapy. IAP antagonists based on a conserved IAP-binding motif (IBM), often referred to as “Smac-mimetics,” are currently being evaluated for cancer therapy in the clinic. ARTS (Sept4_i2) is a mitochondrial proapoptotic protein which promotes apoptosis by directly binding and inhibiting XIAP via a mechanism that is distinct from all other known IAP antagonists. Here, we investigated the ability of peptides derived from ARTS to antagonize XIAP and promote apoptosis in cancer cell lines.

Experimental Design: The ability of synthetic peptides, derived from the C-terminus of ARTS, to bind to XIAP, stimulate XIAP degradation, and induce apoptosis was examined. We compared the response of several cancer cell lines to different ARTS-derived peptides. Pull-down assays were used to examine binding to XIAP, and apoptosis was evaluated using terminal deoxynucleotidyl transferase–mediated dUTP nick end labeling, caspase activation, and Western blot analyses of caspase substrates.

Results: The C-terminus of ARTS contains a unique sequence, termed ARTS-IBM (AIBM), which is important for binding to XIAP and cell killing. AIBM peptides can bind to XIAP-BIR3, penetrate cancer cells, reduce XIAP levels, and promote apoptosis.

Conclusions: Short synthetic peptides derived from the C-terminus of ARTS are sufficient for binding to XIAP and can induce apoptosis in cancer cells. These results provide proof-of-concept for the feasibility of developing ARTS-based anticancer therapeutics.

HIV-1 integrase (IN) is one of the key enzymes in the viral replication cycle. It mediates the integration of viral cDNA into the host cell genome. IN activity requires interactions with several viral and cellular proteins, as well as IN oligomerization. Inhibition of IN is an important target for the development of anti-HIV therapies, but there is currently only one anti-HIV drug used in the clinic that targets IN. Several other small-molecule anti-IN drug leads are either undergoing clinical trials or in earlier stages of development. These molecules specifically inhibit one of the IN-mediated reactions necessary for successful integration. However, small-molecule inhibitors of protein–protein interactions are difficult to develop. In this review, we focus on peptides that inhibit IN. Peptides have advantages over small-molecule inhibitors of protein–protein interactions: they can mimic the structures of the binding domains within proteins, and are large enough to competitively inhibit protein–protein interactions. The development of peptides that bind IN and inhibit its protein–protein interactions will increase our understanding of the IN mode of action, and lead to the development of new drug leads, such as small molecules derived from these peptides, for better anti-HIV therapy.

pH and Na(+) homeostasis in all cells requires Na(+)/H(+) antiporters. In most cases, their activity is tightly pH-regulated. NhaA, the main antiporter of Escherichia coli, has homologues in all biological kingdoms. The crystal structure of NhaA provided insights into the mechanism of action and pH regulation of an antiporter. However, the active site of NhaA remained elusive because neither Na(+) nor Li(+), the NhaA ligands, were observed in the structure. Using isothermal titration calorimetry, we show that purified NhaA binds Li(+) in detergent micelles. This interaction is driven by an increase in enthalpy (ΔH of -8000 ± 300 cal/mol and ΔS of -15.2 cal/mol/degree at 283 K), involves a single binding site per NhaA molecule, and is highly specific and drastically dependent on pH; Li(+) binding was observed only at pH 8.5. Combining mutational analysis with the isothermal titration calorimetry measurements revealed that Asp-163, Asp-164, Thr-132, and Asp-133 form the Li(+) binding site, whereas Lys-300 plays an important role in pH regulation of the antiporter.

Oligomerization plays a major role in regulating the activity of many proteins, and in modulating their interactions. p53 is a homotetrameric transcription factor that has a pivotal role in tumor suppression. Its tetramerization domain is contained within its C-terminal domain, which is a site for numerous protein-protein interactions. Those can either depend on or regulate p53 oligomerization. Here we screened an array of peptides derived from proteins known to bind the tetrameric p53 C-terminal domain (p53CTD) and identified ten binding peptides. We quantitatively characterized their binding to p53CTD using fluorescence anisotropy. The peptides bound tetrameric p53CTD with micromolar affinities. Despite the high charge of the binding peptides, electrostatics contributed only mildly to the interactions. NMR studies indicated that the peptides bound p53CTD at defined sites. The most significant chemical shift deviations were observed for the peptides WS100B(81–92), which bound directly to the p53 tetramerization domain, and PKCα(281–295), which stabilized p53CTD in circular dichroism thermal denaturation studies. Using analytical ultracentrifugation, we found that several of the peptides bound preferentially to p53 tetramers. Our results indicate that the protein-protein interactions of p53 are dependent on the oligomerization state of p53. We conclude that peptides may be used to regulate the oligomerization of p53.

The HIV-1 Rev protein is responsible for shuttling partially spliced and unspliced viral mRNA out of the nucleus. This is a crucial step in the HIV-1 lifecycle, thus making Rev an attractive target for the design of anti-HIV drugs. Despite its importance, there is a lack of structural, biophysical, and quantitative information about Rev. This is mainly because of its tendency to undergo self-assembly and aggregation; this makes it very difficult to express and handle. To address this knowledge gap, we have developed two new highly efficient and reproducible methods to prepare Rev in large quantities for biochemical and structural studies: 1) Chemical synthesis by using native chemical ligation coupled with desulfurization. Notably, we have optimized our synthesis to allow for a one-pot approach for the ligation and desulfurization steps; this reduced the number of purification steps and enabled the obtaining of desired protein in excellent yield. Several challenges emerged during the design of this Rev synthesis, such as racemization, reduced solubility, formylation during thioester synthesis, and the necessity for using orthogonal protection during desulfurization; solutions to these problems were found. 2) A new method for expression and purification by using a vector that contained an HLT tag, followed by purification with a Ni column, a cation exchange column, and gel filtration. Both methods yielded highly pure and folded Rev. The CD spectra of the synthetic and recombinant Rev proteins were identical, and consistent with a predominantly helical structure. These advances should facilitate future studies that aim at a better understanding of the structure and function of the protein.

A hallmark of Alzheimer’s disease is production of amyloid β peptides resulting from aberrant cleavage of the amyloid precursor protein. Amyloid β assembles into fibrils under physiological conditions, through formation of neurotoxic intermediate oligomers. Tachykinin peptides are known to affect amyloid β neurotoxicity in cells. To understand the mechanism of this effect, we studied how tachykinins affect Aβ(1–40) aggregation in vitro. Fibrils grown in the presence of tachykinins exhibited reduced thioflavin T (ThT) fluorescence, while their morphology, observed in transmission electron microscopy (TEM), did not alter. Cross linking studies revealed that the distribution of low molecular weight species was not affected by tachykinins. Our results suggest that there may be a specific interaction between tachykinins and Aβ(1–40) that allows them to co-assemble. This effect may explain the reduction of Aβ(1–40) neurotoxicity in cells treated with tachykinins.

ARTS (Sept4_i2) is a mitochondrial pro-apoptotic protein that functions as a tumor suppressor. Its expression is significantly reduced in leukemia and lymphoma patients. ARTS binds and inhibits XIAP (X-linked Inhibitor of Apoptosis protein) by interacting with its Bir3 domain. ARTS promotes degradation of XIAP through the proteasome pathway. By doing so, ARTS removes XIAP inhibition of caspases and enables apoptosis to proceed. ARTS contains 27 unique residues in its C-terminal domain (CTD, residues 248–274) which are important for XIAP binding. Here we characterized the molecular details of this interaction. Biophysical and computational methods were used to show that the ARTS CTD is intrinsically disordered under physiological conditions. Direct binding of ARTS CTD to Bir3 was demonstrated using NMR and fluorescence spectroscopy. The Bir3 interacting region in ARTS CTD was mapped to ARTS residues 266–274, which are the nine C-terminal residues in the protein. Alanine scan of ARTS 266–274 showed the importance of several residues for Bir3 binding, with His268 and Cys273 contributing the most. Adding a reducing agent prevented binding to Bir3. A dimer of ARTS 266–274 formed by oxidation of the Cys residues into a disulfide bond bound with similar affinity and was probably required for the interaction with Bir3. The detailed analysis of the ARTS – Bir3 interaction provides the basis for setting it as a target for anti cancer drug design: It will enable the development of compounds that mimic ARTS CTD, remove IAPs inhibition of caspases, and thereby induce apoptosis.

The ASPP proteins are apoptosis regulators: ASPP1 and ASPP2 promote, while iASPP inhibits, apoptosis. The mechanism by which these different outcomes are achieved is still unknown. The C-terminal ankyrin repeats and SH3 domain (ANK-SH3) mediate the interactions of the ASPP proteins with major apoptosis regulators such as p53, Bcl-2, and NFκB. The structure of the complex between ASPP2(ANK-SH3) and the core domain of p53 (p53CD) was previously determined. We have recently characterized the individual interactions of ASPP2(ANK-SH3) with Bcl-2 and NFκB, as well as a regulatory intramolecular interaction with the proline rich domain of ASPP2. Here we compared the ASPP interactions at two levels: ASPP2(ANK-SH3) with different proteins, and different ASPP family members with each protein partner. We found that the binding sites of ASPP2 to p53CD, Bcl-2, and NFκB are different, yet lie on the same face of ASPP2(ANK-SH3) . The intramolecular binding site to the proline rich domain overlaps the three intermolecular binding sites. To reveal the basis of functional diversity in the ASPP family, we compared their protein-binding domains. A subset of surface-exposed residues differentiates ASPP1 and ASPP2 from iASPP: ASPP1/2 are more negatively charged in specific residues that contact positively charged residues of p53CD, Bcl-2, and NFκB. We also found a gain of positive charge at the non-protein binding face of ASPP1/2, suggesting a role in electrostatic direction towards the negatively charged protein binding face. The electrostatic differences in binding interfaces between the ASPP proteins may be one of the causes for their different function.