Amino acid requirement for the high affinity binding of a selected arginine-rich peptide with the HIV Rev-response element RNA.

The arginine-rich motif is a class of short arginine-rich peptides that bind to specific RNA structures that has been found to be a versatile framework for the design and selection of RNA-binding peptides. We previously identified novel peptides that bind to the Rev-response element (RRE) RNA of the HIV from an arginine-rich polypeptide library (ARPL) consisting of a polyarginine (15 mer) randomized at the N-terminal 10 positions. The selected peptides bound more strongly to the RRE than the natural binding partner, Rev, and contained glutamine residues that were assumed to be important for recognition of the G-A base pair. In addition, the peptides were predicted to bind to the RRE in an alpha-helical conformation. In this study, in order to understand the mechanism of the interaction between the RRE and the putative alpha-helical glutamine-containing peptides, the amino acid requirements for high affinity binding were analyzed by a combinatorial approach using a bacterial system for detecting RNA-peptide interactions. A consensus peptide, the DLA peptide, was elucidated, which consists of a single glutamine residue within a polyarginine context with the glutamine residue flanked at specific positions by three nonarginine residues, two of which appear to be important for alpha-helix stabilization. In addition, the DLA peptide was found to bind extremely tightly to the RRE with an affinity 50-fold higher than that of the Rev peptide as determined by a gel shift assay. A working model for the interaction of the DLA peptide to the RRE is proposed, which should aid in the development of peptide-based drugs that inhibit HIV replication, as well as in our understanding of polypeptide-RNA interactions. Copyright (c) 2008 European Peptide Society and John Wiley & Sons, Ltd.     

Sequence and structure space of RNA-binding peptides

Studies of RNA-binding peptides, and recent combinatorial library experiments in particular, have demonstrated that diverse peptide sequences and structures can be used to recognize specific RNA sites. The identification of large numbers of sequences capable of binding to a particular site has provided extensive phylogenetic information used to deduce basic principles of recognition. The high frequency at which RNA-binding peptides are found in large sequence libraries suggests plausible routes to evolve sequence-specific binders, facilitating the design of new binding molecules and perhaps reflecting characteristics of natural evolution.     

HIV Rev peptides conjugated with peptide nucleic acids and their efficient binding to RRE RNA

HIV Rev peptides conjugated with peptide nucleic acids (PNAs) were designed and synthesized to develop a designing approach for a novel RNA-binding molecule. The binding affinities of PNA-peptides with the Rev responsive element (RRE) RNA were determined by the competition assay using a rhodamine-labeled Rev. The peptide conjugated with an antisense PNA (TGCGC) bound RRE RNA more efficiently than the molecule without the PNA or the peptide sequence.     

Selection of TAR RNA-binding chameleon peptides by using a retroviral replication system

The interaction between the arginine-rich motif (ARM) of the human immunodeficiency virus (HIV) Tat protein and TAR RNA is essential for Tat activation and viral replication. Two related lentiviruses, bovine immunodeficiency virus (BIV) and Jembrana disease virus (JDV), also require Tat ARM-TAR interactions to mediate activation, but the viruses have evolved different RNA-binding strategies. Interestingly, the JDV ARM can act as a "chameleon," adopting both the HIV and BIV TAR binding modes. To examine how RNA-protein interactions may evolve in a viral context and possibly to identify peptides that recognize HIV TAR in novel ways, we devised a retroviral system based on HIV replication to amplify and select for RNA binders. We constructed a combinatorial peptide library based on the BIV Tat ARM and identified peptides that, like the JDV Tat ARM, also function through HIV TAR, revealing unexpected sequence characteristics of an RNA-binding chameleon. The results suggest that a retroviral screening approach may help identify high-affinity TAR binders and may provide new insights into the evolution of RNA-protein interactions.     

Rev-derived peptides inhibit HIV-1 replication by antagonism of Rev and a co-receptor,CXCR4

Rev, a viral regulatory protein of HIV-1, binds through its arginine-rich domain to the Rev-responsive element (RRE), a secondary structure in transcribed HIV-1 RNA. Binding of Rev to RRE mediates export of singly spliced or unspliced mRNAs from the nucleus to the cytoplasm. It has been previously shown that a certain arginine-rich peptide exhibits not only RRE-binding ability but also cell permeability and antagonism of CXCR4, one of the major coreceptors of HIV-1. Here we designed and synthesized arginine-rich peptides derived from the RNA-binding domain of Rev (Rev_34-50) and evaluated their anti-HIV-1 activities. Rev_34-50-A₄C, comprising Rev_34-50 with AAAAC at the C-terminus to increase the α-helicity, inhibited HIV-1 entry by CXCR4 antagonism and virus production in persistently HIV-1-infected PM1-CCR5 cells. Interestingly, similar motif of human lymphotropic virus type I Rex (Rex_1-21) also exerted moderate anti-HIV-1 activity. These results indicate that arginine-rich peptide, Rev_34-50-A₄C exerts dual antagonism against CXCR4 and Rev.     

Water, Shape Recognition, Salt Bridges, and Cation-Pi Interactions Differentiate Peptide Recognition of the HIV Rev-Responsive Element

Recognition of the human immunodeficiency virus Rev-responsive element (RRE) RNA by the Rev protein is an essential step in the viral life cycle. Formation of the Rev-RRE complex signals nucleocytoplasmic export of unspliced and partially spliced viral RNA. Essential components of the complex have been localized to a minimal arginine-rich Rev peptide and stem IIB of RRE. In vitro selection studies have identified a synthetic peptide known as RSG 1.2 that binds with better specificity and affinity to RRE than the Rev peptide. NMR structures of both peptide-RNA complexes of Rev and RSG 1.2 bound to RRE stem IIB have been solved and reveal gross structural differences between the two bound complexes. Molecular dynamics simulations of the Rev and RSG 1.2 peptides in complex with RRE stem IIB have been simulated to better understand on an atomic level how two arginine-rich peptides of similar length recognize the same sequence of RNA with such different structural motifs. While the Rev peptide employs some base-specific hydrogen bonding for recognition of RRE, shape recognition, through contact with the sugar-phosphate backbone, and cation-pi interactions are also important. Molecular dynamics simulations suggest that RSG 1.2 binds more tightly to the RRE sequence than Rev by forming more base-specific contacts, using water to mediate peptide-RNA contacts, and is held in place by a strong salt bridge network spanning the major groove of the RNA.     

Membrane permeability commonly shared among arginine-rich peptides

Delivery of proteins and other macromolecules using membrane-permeable carrier peptides is a recently developed novel technology, which enables us to modulate cellular functions for biological studies with therapeutic potential. One of the most often used carrier peptides is the arginine-rich basic peptide derived from HIV-1 Tat protein [HIV-1 Tat (48-60)]. Using this peptide, efficient intracellular delivery of molecules including proteins, oligonucleic acids and liposomes has been achieved. We have demonstrated that these features were commonly shared among many arginine-rich peptides such as HIV-1 Rev (34-50) and octaarginine. Not only the linear peptides but also branched-chain peptides showed efficient internalization with an optimum number of arginines (approximately eight residues). The structural and mechanistic features of the translocation of these membrane-permeable arginine-rich peptides are reviewed.     

Screening in vivo for RNA-binding peptides from combinatorial libraries.

We have modified a previously developed genetic assay system for RNA-polypeptide interactions in a attempt to more readily identify RNA-binding peptides. The first modification involved the design of a "complex" library that would contain a variety of RNA-binding polypeptides. The second modification involved the use of neomycin phosphotransferase (NPT II) as the reporter gene, therefore allowing "selection" of RNA-binding peptides by kanamycin resistance. The improved screening system should allow the identification of peptides that bind to a variety of RNA structures.     

Facile detection of specific RNA-polypeptide interactions by MALDI-TOF mass spectrometry.

A simple method for the detection of specific RNA-polypeptide interactions using MALDI-TOF mass spectroscopy is described. Instead of direct observation of the RNA-polypeptide complex, we attempted the indirect observation of the binding event by focusing on the disappearance of the free polypeptide signal upon interaction with RNA. As a result, specific binding of the Rev-response element (RRE) RNA of the HIV with two RRE-binding peptide aptamers, DLA and RLA peptides, as well as the bacteriophage lambda boxB RNA with the lambda N peptide was observed. We also show that specific RNA-binding peptides can be identified from a mixture of peptides with varying RNA-binding affinity, showing that the method could be applied to high-throughput screening from simple peptide libraries. The method described in this study provides a quick and simple method for detecting specific RNA-polypeptide interactions that avoids difficulties associated with direct observation of RNA and RNA-polypeptide complexes, which may find various applications in the analysis of RNA-polypeptide interactions and in the identification of novel RNA-binding polypeptides. Copyright (c) 2008 European Peptide Society and John Wiley & Sons, Ltd.     

Construction of peptides with nucleobase amino acids: design and synthesis of the nucleobase-conjugated peptides derived from HIV-1 Rev and their binding properties to HIV-1 RRE RNA

In order to develop a novel molecule that recognizes a specific structure of RNA, we have attempted to design peptides having L-alpha-amino acids with a nucleobase at the side chain (nucleobase amino acid (NBA)), expecting that the function of a nucleobase which can specifically recognize a base in RNA is regulated in a peptide conformation. In this study, to demonstrate the applicability of the NBA units in the peptide to RNA recognition, we designed and synthesized a variety of NBA-conjugated peptides, derived from HIV-1 Rev. Circular dichroism study revealed that the conjugation of the Rev peptide with an NBA unit did not disturb the peptide conformation. RNA-binding affinities of the designed peptides with RRE IIB RNA were dependent on the structure of the nucleobase moieties in the peptides. The peptide having the cytosine NBA at the position of the Asn40 site in the Rev showed a higher binding ability for RRE IIB RNA, despite the diminishing the Asn40 function. Furthermore, the peptide having the guanine NBA at the position of the Arg44 site, which is the most important residue for the RNA binding in the Rev, bound to RRE IIB RNA in an ability similar to Rev34-50 with native sequence. These results demonstrate that an appropriate NBA unit in the peptide plays an important role in the RNA binding with a specific contact such as hydrogen bonding, and the interaction between the nucleobase in the peptide and the base in the RNA can enhance the RNA-binding affinity and specificity.     

Specific regulation of mRNA splicing in vitro by a peptide from HIV-1 Rev

The Rev protein of HIV-1 regulates the synthesis of partially spliced forms of cytoplasmic viral mRNA by binding to a cis-acting RNA sequence, the Rev response element (RRE). We have investigated the regulation of splicing in vitro and have shown that Rev specifically inhibits splicing of pre-mRNAs containing an RRE by 3- to 4-fold. A synthetic peptide of 17 amino acids containing the RNA-binding domain of Rev is highly functional and specifically inhibits splicing by up to 30-fold. Other peptides that bind to the RRE with high affinity, but with low specificity, do not specifically inhibit splicing. Six repeated monomeric binding sites for the peptide can substitute for the RRE, indicating that regulation by Rev requires interactions with multiple sites. The peptide acts at a step in the assembly of splicing complexes, suggesting that one of the functions of the basic region of Rev is to prevent formation of a functional spliceosome.     

Characterization of functional domains of equine infectious anemia virus Rev suggests a bipartite RNA-binding domain

Equine infectious anemia virus (EIAV) Rev is an essential regulatory protein that facilitates expression of viral mRNAs encoding structural proteins and genomic RNA and regulates alternative splicing of the bicistronic tat/rev mRNA. EIAV Rev is characterized by a high rate of genetic variation in vivo, and changes in Rev genotype and phenotype have been shown to coincide with changes in clinical disease. To better understand how genetic variation alters Rev phenotype, we undertook deletion and mutational analyses to map functional domains and to identify specific motifs that are essential for EIAV Rev activity. All functional domains are contained within the second exon of EIAV Rev. The overall organization of domains within Rev exon 2 includes a nuclear export signal, a large central region required for RNA binding, a nonessential region, and a C-terminal region required for both nuclear localization and RNA binding. Subcellular localization of green fluorescent protein-Rev mutants indicated that basic residues within the KRRRK motif in the C-terminal region of Rev are necessary for targeting of Rev to the nucleus. Two separate regions of Rev were necessary for RNA binding: a central region encompassing residues 57 to 130 and a C-terminal region spanning residues 144 to 165. Within these regions were two distinct, short arginine-rich motifs essential for RNA binding, including an RRDRW motif in the central region and the KRRRK motif near the C terminus. These findings suggest that EIAV Rev utilizes a bipartite RNA-binding domain.     

In vitro selection of ribozymes dependent on peptides for activity

A peptide-dependent ribozyme ligase (aptazyme ligase) has been selected from a random sequence population based on the small L1 ligase. The aptazyme ligase is activated > 18,000-fold by its cognate peptide effector, the HIV-1 Rev arginine-rich motif (ARM), and specifically recognizes the Rev ARM relative to other peptides containing arginine-rich motifs. Moreover, the aptazyme ligase can preferentially recognize the Rev ARM in the context of the full-length HIV-1 Rev protein. The only cross-reactivity exhibited by the aptazyme is toward the Tat ARM. Reselection of peptide- and protein-dependent aptazymes from a partially randomized population yielded aptazymes that could readily discriminate against the Tat ARM. These results have important implications for the development of aptazymes that can be used in arrays for the detection and quantitation of multiple cellular proteins (proteome arrays).     

Constrained peptides mimic a viral suppressor of RNA silencing

The design of high-affinity, RNA-binding ligands has proven very challenging. This is due to the unique structural properties of RNA, often characterized by polar surfaces and high flexibility. In addition, the frequent lack of well-defined binding pockets complicates the development of small molecule binders. This has triggered the search for alternative scaffolds of intermediate size. Among these, peptide-derived molecules represent appealing entities as they can mimic structural features also present in RNA-binding proteins. However, the application of peptidic RNA-targeting ligands is hampered by a lack of design principles and their inherently low bio-stability. Here, the structure-based design of constrained α-helical peptides derived from the viral suppressor of RNA silencing, TAV2b, is described. We observe that the introduction of two inter-side chain crosslinks provides peptides with increased α-helicity and protease stability. One of these modified peptides (B3) shows high affinity for double-stranded RNA structures including a palindromic siRNA as well as microRNA-21 and its precursor pre-miR-21. Notably, B3 binding to pre-miR-21 inhibits Dicer processing in a biochemical assay. As a further characteristic this peptide also exhibits cellular entry. Our findings show that constrained peptides can efficiently mimic RNA-binding proteins rendering them potentially useful for the design of bioactive RNA-targeting ligands.     

Automated screening procedure for high-throughput generation of antibody fragments

In the emerging field of proteomics, there is an urgent need for catcher molecules such as antibodies for detecting the proteome or parts of the proteome in a microarray format. A suitable source for providing a large diversity of binders is obtained by combinatorial libraries, such as phage display libraries of single chain antibody fragments (scFv) or Fab fragments. To find novel binders from the n-CoDeR libraries with a high throughput, we have automated the screening process with robotics. The automated system is configured to screen tens of thousands of clones per day to target antigens in various formats, including peptides and soluble proteins, as well as cell-bound targets; thus, it is well designed to meet demands from the proteomics area.