Large-Scale Synthesis of Man9GlcNAc2 High-Mannose Glycan and the Effect of the Glycan Core on Multivalent Recognition by HIV Antibody 2G12.

Access to homogeneous high-mannose glycans in high-mg quantities is necessary for carbohydrate-based HIV vaccine development research. We have used directed evolution to design highly antigenic oligomannose clusters that are recognized in low-nM affinity by HIV antibodies. Herein we report an optimized large-scale synthesis of Man9GlcNAc2 including improved building block synthesis and a fully stereoselective 5 + 6 coupling, yielding 290 mg of glycan. We then use this glycan to study the effect of the GlcNAc2 core on the antigenicity of an evolved 2G12-binding glycopeptide, 10F2.

The Impact of Sustained Immunization Regimens on the Antibody Response to Oligomannose Glycans.

The high mannose patch (HMP) of the HIV envelope protein (Env) is the structure most frequently targeted by broadly neutralizing antibodies; therefore, many researchers have attempted to use mimics of this region as a vaccine immunogen. In our previous efforts, vaccinating rabbits with evolved HMP mimic glycopeptides containing Man9 resulted in an overall antibody response targeting the glycan core and linker rather than the full glycan or Manα1→2Man tips of Man9 glycans. A possible reason could be processing of our immunogen by host serum mannosidases. We sought to test whether more prolonged dosing could increase the antibody response to intact glycans, possibly by increasing the availability of intact Man9 to germinal centers. Here, we describe a study investigating the impact of immunization regimen on antibody response by testing immunogen delivery through bolus, an exponential series of mini doses, or a continuously infusing mini-osmotic pump. Our results indicate that, with our glycopeptide immunogens, standard bolus immunization elicited the strongest HIV Env-binding antibody response, even though higher overall titers to the glycopeptide were elicited by the exponential and pump regimens. Antibody selectivity for intact glycan was, if anything, slightly better in the bolus-immunized animals.

Oligomannose Glycopeptide Conjugates Elicit Antibodies Targeting the Glycan Core Rather than Its Extremities.

Up to ∼20% of HIV-infected individuals eventually develop broadly neutralizing antibodies (bnAbs), and many of these antibodies (∼40%) target a region of dense high-mannose glycosylation on gp120 of the HIV envelope protein, known as the "high-mannose patch" (HMP). Thus, there have been numerous attempts to develop glycoconjugate vaccine immunogens that structurally mimic the HMP and might elicit bnAbs targeting this conserved neutralization epitope. Herein, we report on the immunogenicity of glycopeptides, designed by in vitro selection, that bind tightly to anti-HMP antibody 2G12. By analyzing the fine carbohydrate specificity of rabbit antibodies elicited by these immunogens, we found that they differ from some natural human bnAbs, such as 2G12 and PGT128, in that they bind primarily to the core structures within the glycan, rather than to the Manα1 → 2Man termini (2G12) or to the whole glycan (PGT128). Antibody specificity for the glycan core may result from extensive serum mannosidase trimming of the immunogen in the vaccinated animals. This finding has broad implications for vaccine design aiming to target glycan-dependent HIV neutralizing antibodies.

Directed Evolution of Glycopeptides Using mRNA Display.

Directed evolution is a useful method for the discovery of nucleic acids, peptides, or proteins that have desired binding abilities or functions. Because of the abundance and importance of glycosylation in nature, directed evolution of glycopeptides and glycoproteins is also highly desirable. However, common directed evolution platforms such as phage-, yeast-, or mammalian-cell display are limited for these applications by several factors. Glycan structure at each glycosylation site is not genetically encoded, and yeast and mammalian cells produce a heterogeneous mixture of glycoforms at each site on the protein. Although yeast, mammalian and Escherichia coli cells can be engineered to produce a homogenous glycoform at all glycosylation sites, there are just a few specific glycan structures that can readily be accessed in this manner. Recently, we reported a novel system for the directed evolution of glycopeptide libraries, which could in principle be decorated with any desired glycan. Our method combines in vitro peptide selection by mRNA display with unnatural amino acid incorporation and chemical attachment of synthetic oligosaccharides. Here, we provide an updated and optimized protocol for this method, which is designed to create glycopeptide mRNA display libraries containing ~1013 sequences and select them for target binding. The target described here is the HIV broadly neutralizing monoclonal antibody 2G12; 2G12 binds to cluster of high-mannose oligosaccharides on the HIV envelope glycoprotein gp120; and glycopeptides that mimic this epitope may be useful in HIV vaccine applications. This method is expected to be readily applicable for other types of glycans and targets of interest in glycobiology.

Synthesis of multivalent glycopeptide conjugates that mimic an HIV epitope.

Recently, we reported a directed evolution method which enabled us to discover sequences of glycopeptides that bind with picomolar affinity to HIV antibody 2G12 and are of interest as HIV vaccine candidates. In this manuscript, we describe the syntheses of several of these large (~11-12 kDa) glycopeptides by a combination of fast flow peptide synthesis and click chemistry. We also discuss the optimization of their attachment to carrier protein CRM197, affording antigenic and immunogenic conjugates ready for animal vaccination.

Recent strategies targeting HIV glycans in vaccine design.

Although efforts to develop a vaccine against HIV have so far met with little success, recent studies of HIV-positive patients with strongly neutralizing sera have shown that the human immune system is capable of producing potent and broadly neutralizing antibodies (bnAbs), some of which neutralize up to 90% of HIV strains. These antibodies bind conserved vulnerable sites on the viral envelope glycoprotein gp120, and identification of these sites has provided exciting clues about the design of potentially effective vaccines. Carbohydrates have a key role in this field, as a large fraction of bnAbs bind carbohydrates or combinations of carbohydrate and peptide elements on gp120. Additionally, carbohydrates partially mask some peptide surfaces recognized by bnAbs. The use of engineered glycoproteins and other glycostructures as vaccines to elicit antibodies with broad neutralizing activity is therefore a key area of interest in HIV vaccine design.

Directed evolution of multivalent glycopeptides tightly recognized by HIV antibody 2G12.

Herein, we report a method for in vitro selection of multivalent glycopeptides, combining mRNA display with incorporation of unnatural amino acids and "click" chemistry. We have demonstrated the use of this method to design potential glycopeptide vaccines against HIV. From libraries of ~10(13) glycopeptides containing multiple Man9 glycan(s), we selected variants that bind to HIV broadly neutralizing antibody 2G12 with picomolar to low nanomolar affinity. This is comparable to the strength of the natural 2G12-gp120 interaction, and is the strongest affinity achieved to date with constructs containing 3-5 glycans. These glycopeptides are therefore of great interest in HIV vaccine design.

Identification of antisense RNA stem-loops that inhibit RNA-protein interactions using a bacterial reporter system.

Many well-characterized examples of antisense RNAs from prokaryotic systems involve hybridization of the looped regions of stem-loop RNAs, presumably due to the high thermodynamic stability of the resulting loop-loop and loop-linear interactions. In this study, the identification of RNA stem-loops that inhibit U1A protein binding to the hpII RNA through RNA-RNA interactions was attempted using a bacterial reporter system based on phage lambda N-mediated antitermination. As a result, loop sequences possessing 7-8 base complementarity to the 5' region of the boxA element important for functional antitermination complex formation, but not the U1 hpII loop, were identified. In vitro and in vivo mutational analysis strongly suggested that the selected loop sequences were binding to the boxA region, and that the structure of the antisense stem-loop was important for optimal inhibitory activity. Next, in an attempt to demonstrate the ability to inhibit the interaction between the U1A protein and the hpII RNA, the rational design of an RNA stem-loop that inhibits U1A-binding to a modified hpII was carried out. Moderate inhibitory activity was observed, showing that it is possible to design and select antisense RNA stem-loops that disrupt various types of RNA-protein interactions.

Analysis of the spacial requirements for RNA-protein interactions within the N antitermination complex of bacteriophage lambda.

In bacteriophage lambda, formation of a transcriptional antitermination complex consisting of the lambda N protein, nut RNA transcript (boxA-boxB), host factors, and RNA polymerase is mediated by the interaction of the boxB RNA with the RNA-binding domain of N. In order to understand the spacial requirements of this boxB/N interaction within the complex, the effects of changes in the length of the nut site linker, the boxB stem, and the peptide spacer connecting the RNA-binding domain and activation domain of N were examined using a bacterial reporter system. As a result, we found that the requirements for the boxB stem length and N peptide linker length were optimized and strict. In contrast, when the boxB/N interaction was replaced by heterologous RNA/peptide interactions, the strict requirement for the length of the peptide linker and the RNA stem was relaxed, presumably due to the absence of the interaction between boxB/N and the host factor NusA in the wild-type complex. It was also shown that the decrease in activity upon stem lengthening could be partially suppressed by simultaneous lengthening of the RNA spacer, suggesting that a further understanding of the organization of the antitermination complex may provide insights into the engineering of functional ribonucleoprotein complexes.

Replacement of the lambda boxB RNA-N peptide with heterologous RNA-peptide interactions relaxes the strict spatial requirements for the formation of a transcription anti-termination complex.

In bacteriophage lambda, formation of a transcriptional anti-termination complex involving the elongating RNA polymerase is mediated by the interaction of boxB RNA with the RNA-binding domain of the N protein (N peptide). In an attempt to understand the spatial requirements for boxB/N peptide interaction within the anti-termination complex, the effects of changes in the distance between boxA and boxB RNA, the length of the boxB stem, and the distance between the N peptide and remainder of the N protein were examined using a bacterial reporter system. It was found that the requirements for boxB stem length and the distance between N peptide and the remainder of N were optimized and strict. In contrast, replacement of the boxB/N interaction by heterologous RNA-peptide interactions appeared to relax the strict requirement for RNA stem length and the orientation of the RNA-binding peptide, presumably due to the absence of the cooperative interaction between boxB/N and the host factor NusA. In addition, the decrease in activity upon stem lengthening could be partially suppressed by simultaneous lengthening of the RNA spacer. A further understanding of the structural organization of the anti-termination complex may provide insights into how functional ribonucleoprotein complexes may be engineered.

Analysis of the interaction between selected RNA-binding peptides and a target RNA containing a bulge and a GNRA-type tetraloop.

We have characterized the interaction between selected novel RNA-binding peptides and their target RNA. The RNA is comprised of two elements, a GCAA tetraloop, a member of the thermodynamically stable GNRA-type (where N is A or G, U, C; R is G or A) tetraloops, and a tri-purine bulge found in the frameshift stimutating structure on the human immunodeficiency virus type 1 (HIV-1) gag-pol mRNA. Peptides that bind specifically to the target RNA were selected from a combinatorial library based on arginine-rich motif (ARM) by a bacterial reporter system. We performed mutational studies using the reporter system and gel shift assays and found that the binding affinity and specificity of the RNA were mainly dependent on the GNRA-type tetraloop, and a modest contribution was also attributed to the bulge structure. Our finding reveals a novel mode of interaction by an RNA-peptide complex and expands our knowledge on the diversity of molecular recognition.

An efficient thermally induced RNA conformational switch as a framework for the functionalization of RNA nanostructures.

RNA offers a variety of interactions and dynamic conformational switches not available with DNA that may be exploited for the construction of nanomolecular structures. Here, we show how the RNA loop-loop, or "kissing", interaction can be used to construct specific circular RNA arrangements that are capable of thermal isomerization to alternative structures. We also show how this thermally induced structural rearrangement can be used to unmask a functional RNA structure, in this case, a peptide-binding RNA structure, the Rev-response element (RRE) of HIV, thereby acting as a functional peptide-binding switch. The relative ease with which the RRE could be engineered into the RNA substrates suggested that a variety of functional RNA structures may be introduced. In addition, the structural rearrangement was extremely efficient, showing that the "kissing" complexes described in this study may provide a useful framework for the construction of functional RNA-based nanostructures, as well as aid in our understanding of the way RNA functions in biological systems.

RNA LEGO: magnesium-dependent formation of specific RNA assemblies through kissing interactions.

The high affinity and specificity of nucleic acid base complementarity has been proven to be a powerful method for constructing specific molecular assemblies. On the other hand, recent structural studies of RNA have revealed the wide range of tertiary interactions utilized in RNA folding, which may potentially be used as tools for the design of specific macromolecular assemblies. Here, RNA building blocks containing two hairpin loops, based on the dimerization initiation site (DIS) of HIV RNA, connected by a short linker were used to construct large RNA assemblies through hairpin loop-loop ("kissing") interactions. We show that specific linear and circular assemblies can be constructed in a magnesium-dependent manner using several non-self-complementary loop-loop interactions designed in this study. These results show that the use of RNA tertiary interactions may broaden the repertoire of nucleic acid-based nanostructures.

Selection of RRE RNA binding peptides using a kanamycin antitermination assay.

The arginine-rich domains of several RNA-binding proteins have been shown to bind their cognate RNAs with high affinities and specificities as isolated peptides, adopting different conformations within different complexes. The sequence simplicity and structural diversity of the arginine-rich motif has made it a good framework for constructing combinatorial libraries and identifying novel RNA-binding peptides, including those targeted to the HIV Rev response element (RRE). Here we describe a modified transcription antitermination reporter assay engineered with kanamycin resistance that enables larger in vivo screens (approximately 10(9) sequences) than previously possible. We show that the assay detects only specific RNA-protein complexes, and that binders are enriched at least 300-fold per round of selection. We screened a large peptide library in which amino acids with charged, polar, and small side chains were randomly distributed within a polyarginine framework and identified a set of high affinity RRE-binding peptides. Most contain glutamine at one particular peptide position, and the best peptides display significantly higher antitermination activities than Rev or other previously described high-affinity RRE-binding peptides. The kanamycin antitermination (KAN) assay should be useful for screening relatively large libraries and thereby facilitate identification of novel RNA binders.

RNA LEGO: magnesium-dependent assembly of RNA building blocks through loop-loop interactions.

We describe the construction of nano-molecular assemblies using RNA building blocks the human immunodeficiency virus type 1 (HIV-1) dimerization initiation site (DIS) RNA, that forms stable base pairing through a magnesium-dependent loop-loop interaction ("kissing"). RNA building blocks containing two DIS or DIS-like hairpins connected by a two nucleotide linker self-assembled to form specific structures as observed by non-denaturing polyacrylamide gel electrophoresis (PAGE). Furthermore, observation of "real time" formation of the molecular assemblies by circular dichroism (CD) spectroscopy was attempted.