Design and Characterization of HIV-1 ENV Derived Immunogens

Purwar, Mansi

January 2016

The Human Immunodeficiency Virus (HIV) is a member of the retroviridae family from lentivirus genus which primarily infects CD4+ T cells and also to lesser degree monocytes, macrophages, and dendritic cells causing progressive failure of the immune system, ultimately leading to development of acquired immunodeficiency syndrome (AIDS). Currently ~ 37 million people are infected with HIV-1 with approximately 2 million new infections occurring every year (UNAIDS, 2016). Developing safe, effective, and affordable vaccines to prevent HIV infection is the best hope for controlling the HIV/AIDS pandemic. Envelope glycoprotein (Env) on the HIV-1 virion surface is synthesized as a single precursor protein gp160 which is cleaved by furin to form the gp120 and gp41 subunits. gp41 is inserted into the membrane, while gp120 remains non-covalently associated with the ectodomain of gp41 to form a trimer of heterodimers. gp120 binds to the CD4 receptor on CD4+ T cells, which triggers a series of conformational changes leading to the exposure of co-receptor binding sites on gp120. Subsequent binding to the co-receptor (CXCR4 or CCR5) on T-cells initiates fusion of cellular and viral membranes via gp41 subunit. The envelope glycoprotein gp120, on the virion surface is the most accessible component of HIV-1 to the host immune system, and the target of most of the neutralization response. However, the virus has evolved many efficient ways to escape this immune surveillance. Extensive glycosylation of gp120 is one way by which it masks critical neutralization epitopes and the presence of immunodominant long variable loops focuses the immune response away from conserved regions. Certain conserved epitopes are cryptic and get exposed only after gp120 binds to its receptor. Also gp120 and gp41 are highly flexible molecules, attached in a non-covalent fashion to form a trimer of heterodimers, leading to inherent metastability of the Env. This results in exposure of a large number of non-native conformations to the immune system and thus minimizes elicitation of neutralizing antibodies. Despite these defense mechanisms, about 20-30% of HIV-1 patients do generate a broad neutralization response. Although these bNAbs and their epitopes have been identified, eliciting similar bNAbs through immunization is challenging. Monomeric gp120 when used as an immunogen elicits non neutralizing antibodies. This indicates that the epitopes of bNAbs are not present in the right conformation on this molecule. A rational design approach which focuses the immune response towards specific epitopes targeted by bNAbs is required, with the aim to maximize the exposure of conserved neutralization epitopes and to simultaneously ensure minimal exposure of variable non neutralizing epitopes. This can likely be achieved either by (a) stabilization of native Env trimers, or/and by (b) protein fragment design. Chapter 1 gives a brief description of HIV-1 virus. Structural features of the Env protein are described along with epitopes targeted by various bNAbs. Various strategies employed towards structure based vaccine design are discussed. One of the strategies towards rational vaccine design is using protein fragment based approaches. Grafting epitopes onto heterologous scaffolds is a promising approach which can provide more structural stability to the epitope, helps focus immune response on the epitope of interest and can be employed in a prime boost strategy for immunization studies. In a scaffold based approach we used crystal structure information of gp120 in complex with bNAb b12 to define the epitope of this antibody. In Chapter 2 we use this epitope information to graft the epitope on an unrelated scaffold protein to design unique epitope scaffolds. We report a computational strategy to graft the discontinuous epitope of b12 antibody onto different scaffold proteins. Our strategy focuses on identifying the best match of the target scaffold to the query protein so as to cause the least structural disturbance in the scaffold protein. The best hits were screened for binding to b12 using Yeast Surface Display (YSD). Random mutant libraries were also generated to screen for better b12 binders using YSD. We further characterized a few of these epitope scaffolds after purifying them from bacterial systems. One of the epitope scaffolds 1mkh_E2 bound to b12 with a KD value of 7.5µM. 2bodx_03, an unoptimized epitope scaffold reported previously (Azoitei et al, 2011) binds b12 with a KD value of 300μM. Thus our epitope scaffold 1mkh_E2 shows reasonable binding to b12 without any optimization. We are currently purifying other b12 epitope scaffolds and will be characterizing them for binding to b12. We have previously used a protein minimization strategy to design fragments of gp120, called b122a and b121a comprising a compact beta barrel on the lower part of the outer domain in order to focus the immune response towards the b12 epitope. (Bhattacharyya et al, 2013). These were bacterially expressed, found to be partially folded, however, could bind the broadly neutralizing antibody b12 with micromolar affinity. In rabbit immunization studies sera obtained following four primes with the b122a fragment protein and two boosts with full-length gp120 showed broad neutralization of a panel of multiple viruses across different clades (Bhattacharyya et al, 2013). In the present work, These designs were further stabilised by introducing various disulphides. One of the disulphide mutants b122a1-b showed better binding to b12 compared to b122a and increased protection to protease digestion. However these are partially structured as assessed by CD. In Chapter 3 we attempted to evolve stabilized versions of b122a1-b by using a genetic selection based on antibiotic resistance described previously (Foit et al, 2009). We were successfully able to show an in-vivo stability difference between b122a and b122a1-b. From the library generated in the background of b122a1-b using random mutagenesis, a few apparently stabilized mutants were isolated. Most of these mutations were hydrophobic to polar substitutions at exposed positions while a few of the mutations were substitutions with similar side chain chemistry as in wildtype. In future studies we will measure mutant stabilities and binding affinity to b12. A set of similar fragment immunogens were also designed based on subtype C CAP210 gp120 sequences. In Chapter 4 we describe various immunization studies comprising of different sets of b12 epitope based fragment immunogens. In one study we displayed some of these immunogens on Qβ VLPs. In another study, we tested subtype C based fragment immunogens. The humoral immune response was probed in terms of generation of antibodies against the immunogens using ELISA. Neutralization activity of the sera was measured in a standard TZM-bl assay. Sera raised against these particles in rabbit immunization studies could neutralize Tier1 viruses across different subtypes. The group primed with particles displaying b122a1-b and the group primed with b122a conjugated to particle in the presence of adjuvant contained significantly higher amounts of antibodies directed towards the CD4bs than sera from the group primed with empty particles and boosted with gp120. This study demonstrates the overall utility of the particle based display approach. In immunization studies with subtype C derived fragment immunogens as primes, no significant neutralization was seen even for Tier 1 viruses. In this study, the group primed and boosted with full length gp120 performed better than other groups suggesting that antibodies elicited against regions present in these subtype C priming immunogens are non-neutralizing. One of the rational vaccine design strategies is by stabilization of native Env trimers. In previous studies, a disulfide bond was engineered between gp120 and gp41 of Env to stabilize the interactions (SOS gp140). An I559P mutation was also introduced to stabilize the native gp41 conformation in the context of disulfide engineered Env (SOSIP gp140). The purified, soluble SOSIP gp140 immunogens were trimeric and cleaved properly and are believed to be one of the closest mimics of native Env trimers. However, these immunogens have so far failed to elicit broad neutralizing responses. In Chapter 5, we use structural information derived from high resolution atomic structure of native like cleaved gp140 BG505-SOSIP, to provide an alternate strategy to form uncleaved trimeric gp140s by cyclic permutation to design molecules that mimic cleaved trimers. The structure reveals that the gp41 C-terminus is in very close proximity (~8Å) to the N-terminus of gp120 from an adjacent subunit. We have designed a cyclic permutant of gp140 from JRFL strain where the gp41 C terminus is now connected to the gp120 N-terminus with a short linker. This novel connectivity results in preservation of the native gp41 N-terminus along with a much shorter linker length than in conventional gp140. This might promote trimer folding and stabilization because of the resulting decreased magnitude of conformational entropy change during folding. The structure also reveals that the gp120 C-terminus is close to the trimer axis, and due to cyclic permutation, this becomes the new C-terminus of gp140. To further stabilize the trimeric form, we have attached a foldon trimerization domain at the C terminus. The protein has been expressed and purified from mammalian cells. The protein exists primarily as a trimer in solution as assessed by SEC-MALS. It shows better binding to broadly neutralizing antibody b12 when compared to b6, a non-neutralizing antibody. Further biophysical characterization of the protein is in progress. We have previously described design of a bacterially expressed outer domain derivative of gp120 (ODEC) that had V1/V2 and V3 loops deleted and bound CD4 (Bhattacharyya et al, 2010). To improve the initial ODEC design, three different rational design strategies were used. In the first approach, residue frequency based methods were used to design a construct named ODECConsensus. In another approach, a cyclic permutant of ODEC (CycV4OD) was designed with new N and C termini in the flexible V4 loop. In the third approach the bridging sheet (BS) region was deleted from ODEC to form ODECΔBS. In Chapter 6 we have used hydrogen deuterium exchange-mass spectrometric analysis (HDX-MS) to study conformational flexibility of these fragment immunogens. These studies revealed that all the three immunogens show reduced conformational flexibility compared to ODEC. 5-7 protons remain protected up to 2 hours whereas for ODEC, exchange completes at 20 minutes. This reduced flexibility correlates with 6-20 fold tighter VRC01 binding relative to ODEC. In rabbit immunizations, all three constructs elicit significant gp120 titers as early as week 6 in the absence of any gp120 boost whereas ODEC shows significant gp120 titers only after two gp120 boosts. Week 24 sera elicited after immunization with ODECΔBS, ODECConsensus and CycV4OD boosted with gp120 show neutralization of multiple Tier 1 viruses from subtype B and C, whereas corresponding ODEC immunized animals failed to show a neutralizing response. This study demonstrates that reduced conformational flexibility correlates with better antigenicity and an improved immunogenicity profile for these fragment immunogens. Also we have used HDX-MS studies to one of the stem based HA fragment immunogen pH1HA10-foldon described previously (Mallajosyula et al, 2014) to do peptide finger printing and find regions of protein showing increased protection to hydrogen deuterium exchange and thus derive some structural insights about this trimeric fragment immunogen. Peptide mapping experiments show that the HA stem fragment peptides are exchanging rapidly with more than 90% exchange completing by 30 s for most of the peptides. The well folded foldon trimerization domain peptide shows a very slow exchange profile. A few of the HA peptides exchange slowly with 1-2 protons exchanging after 30 s. Fast exchange seen for this fragment immunogen may be due to truncation of the stem region leading to greater solvent accessibility of the trimer interface.

HIV-1 Env

B12 Epitope Scaffolds

β-Lactamasescreeming System

HIV-1 ENV Derived Immunogens

Viral Spike Mimetics

HIV-1 gp120

Molecular Biophysics

gp120 Immunogen Design And Characterization

Chakraborty, Kausik

06 1900

HIV-1 is the causative agent for AIDS and has been a major focus of research for the past two decades. Though there is a combination therapy in place known as the “Highly Active Anti-Retroviral Therapy” (HAART), its usefulness is confounded by the generation of escape mutants, a host of side effects, and its prohibitive cost. The most useful alternative would be the prevention of infection by vaccination. Vaccine research has been focused on the use of recombinant protein sub-units of the virus or combinations thereof to elicit a neutralizing response against the virus. These approaches have mostly resulted in a failure to generate broadly cross reactive neutralizing response against primary strains of the virus. The work reported herein is aimed at designing a rigidified version of gp120/gp120 derivatives and understanding the scope of the various antigenic regions in gp120 in generating a neutralization response. Chapter one discusses some general features of the virus and the immune system. The general nature of AIDS, its spread and its immunological characteristics are also described in this chapter. Chapter two discusses the design and NMR structural analysis of gp120 bridging sheet peptide mimics in methanol and water. The structure of gp120 can be loosely divided into two domains (the outer domain and the inner domain) that are linked together by a discontinuous four stranded antiparallel beta sheet known as the bridging sheet. The bridging sheet is known to overlap with the coreceptor binding site of gp120 and hence is a suitable target for designing virus-entry inhibitors. 17b, a neutralizing antibody isolated from an infected individual, is known to bind to this region of gp120. Our aim in this part of the work was to design a four stranded antiparallel beta sheet, based on the sequence of the bridging sheet, that would contain most of the residues involved in 17b binding. NMR and CD studies confirmed that the peptide was well structured in methanol but the structure was largely lost on addition of aqueous solvent. A small population of the peptide was found to be well-folded in aqueous solution. Chapter three discusses the design and characterization of a gp120-CD4D12 single chain. It is well known that the conformation of gp120 changes upon binding CD4 to expose cryptic epitopes, known as CD4i epitopes. In this work we report the generation of a single chain gp120-CD4 construct that has the cryptic epitopes exposed. The construct bound to 17b, a conformation specific antibody against the bridging sheet of gp120, a cryptic epitope, as well as a non-covalent complex of gp120:CD4D12. There was also very insignificant secondary structural change in gp120 upon complex formation with CD4D12 as observed by CD spectroscopy. Immunological studies with DNA and protein vaccination in guinea-pigs indicated that though 17b like antibodies are generated after immunization, they did not contribute towards the neutralization of primary isolates of the virus. It was also observed that it was the anti-CD4D12 antibodies that were responsible for the neutralization by the sera. These studies indicated towards the inability of the bridging sheet to generate effective neutralization response in case of vaccination with gp120/CD4 complexes. Chapter four discusses the design of a mimic of the gp120/CD4 complex. Since it was seen from our previous work that gp120/CD4 complexes generate a large fraction of antiCD4 antibodies and hence are unsuitable for vaccination purposes, we generated a construct with the minimal binding region of CD4. The small fragment of CD4 spanning from 21st residue to 64th residue was inserted in the V1/V2 loop of gp120. The insertion site was designed based on the region of gp120 closest to this fragment and capable of tolerating insertions. This protein did not bind to 17b as well as gp120/CD4 complex but showed a higher binding compared to full length gp120. Further immunological characterization with this protein revealed that it was not capable of generating neutralizing antibodies against the virus. Chapter five discusses the design and execution of a SPR based solution phase competition experiment to find the solution phase binding constant of CD4 and CD4 analogs to gp120. A major problem during the analysis of binding data obtained by SPR is the accurate determination of Rmax, a parameter needed to obtain an accurate equilibrium dissociation constant. In this chapter we have developed a binary as well as a ternary solution phase SPR based assay to accurately determine a solution phase equilibrium binding constant. The binding constants were determined for gp120 binding to CD4D12 and other CD4 analogs. To confirm the validity of the assay, a control antigen:antibody interaction whose equilibrium dissociation constant has been determined by other methods has been used as a test case. Chapter six discusses the design and characterization of V3 peptides inserted in the loop regions of E. coli Thioredoxin (Trx). Trx has earlier been used to display random peptide libraries between the 33rd and the 34th residue. We have constructed three constructs where the peptide has been inserted between the 33rd and 34th residue, between the 74th and 75th residue and between the 84th and 85th residue. The insertion between 74th and 75th position (74V3Trx) was found to be superior to the other two and would be a suitable alternative for display of a random peptide library. The binding of these constructs to 447-52D, a V3 peptide specific antibody was characterized. These were also characterized immunologically, and 74V3Trx was found to generate weakly neutralizing activity against the MN strain of HIV-1. Competition experiments with 447-52D with these sera indicated that there were antibodies generated that could compete out 447-52D binding to gp120 but not in sufficient concentration to provide broad neutralization. Appendix 1 discusses the rational design of disulfides to stabilize proteins based on the analysis of naturally occurring disulfides. In our attempts to design a rigidified version of gp120 we had designed disulfides in gp120 based on its crystal structure. Many of these were disulfides that would span antiparallel adjacent strands. In order to improve the design principles, we analyzed naturally occurring disulfides that span antiparallel adjacent strands and characterized them in terms of their positional preference in a beta sheet. It was found that these disulfides mostly occur on edge strands and are found exclusively between non-hydrogen bonded registered pairs of adjacent antiparallel strands. Mutagenesis on Thioredoxin was performed to verify our results. It was found that disulfides designed between the non-hydrogen bonded pairs of antiparallel strands could significantly stabilize the protein whereas the ones between hydrogen bonded pairs destabilized the protein.

Human Immunodeficiency Virus (HIV)

Immunogenetics

HIV-1 gp120

HIV (Viruses)

gp120-CD4D12

gp120-M9

HIV Vaccine Design

gp120

Molecular Biology

Targeting The CD4 Biniding Site In HIV-1 Immunogen Design

Bhattacharyya, Sanchari

07 1900

Over three decades have passed since the discovery of HIV-1, yet an AIDS vaccine remains elusive. The envelope glycoprotein of HIV-1 gp120, is the most exposed protein on the viral surface and thus serves as an important target for vaccine design. However, various factors like high mutability of gp120, extensive glycosylation and very high conformational flexibility of gp120 have confounded all efforts to design a suitable immunogen that elicits broad and potent neutralizing antibodies against HIV-1. In Chapter 1, a brief description of the structural organization of HIV-1 along with the progress made and the difficulties encountered in the development of a vaccine are presented. In Chapter 2, the design and characterization of an outer domain immunogen of HIV-1 gp120 is discussed. The outer domain (OD) of the envelope glycoprotein gp120 is an important target for vaccine design since it contains a number of conserved epitopes, including a large fraction of the CD4 binding site. Attempts to design OD based immunogens in the past have met with little success. In this work, we designed an OD immunogen based on the sequence of the HXBc2 strain, expressed and purified it from E. coli (ODEC). The ODEC molecule lacks the variable loops V1V2 and V3 and incorporates 11 designed mutations at the interface of the inner and the outer domains of gp120 to increase solubility. Biophysical studies showed that ODEC is folded and protease resistant while ODEC lacking the designed mutations is highly aggregation prone. In contrast to previously characterized OD constructs, ODEC bound CD4 and the broadly neutralizing antibody b12 with micromolar affinities, but not the non-neutralizing antibodies b6 and F105. Further improvement in the refolding protocol yielded a better structured molecule that bound CD4, b12 and VRC01 with sub-micromolar affinities. In rabbit immunization studies with animals primed with ODEC and boosted with gp120, the sera are able to neutralize Tier I viruses and some Tier II viruses like JRFL and RHPA with measurable IC50s. This is one of the first examples of a gp120 fragment based immunogen which was able to elicit sera that showed modest neutralization of some Tier II viruses. Subsequently amide hydrogen-deuterium exchange studies of ODEC showed that though the molecule is well-folded, it is labile to exchange. This might indicate why ODEC does not elicit high amounts of neutralizing antibodies. In Chapter 3, we report the design and characterization of two smaller fragments of gp120 (b121a and b122a) to target the epitope of the broadly neutralizing antibody b12. The region chosen comprised of a compact beta barrel in the lower part of the outer domain of gp120. Unlike ODEC, the fragments corresponding to these constructs were not contiguous stretches in gp120. Thus we used linkers to connect them. Further, nine designed mutations were introduced at exposed hydrophobic regions of the fragment to increase its solubility. The designed protein fragments were expressed in E. coli in order to prevent glycosylation and consequent epitope masking that might occur if expressed in an eukaryotic expression system. Biophysical studies showed that b121a/b122a are partially folded. Disulfide mapping studies showed that the expected disulfide bridges were formed. The designed immunogens could bind b12, but not the non-neutralizing antibody b6. Sera from rabbits primed with b121a/b122a protein fragments and boosted with full-length gp120 showed broad neutralizing activity against a 20 virus panel including Tier2 and 3 viruses such as PVO4, CAAN, CAP45 and ZM233. Sera from animals that received only gp120 showed substantially decreased breadth and potency. Serum depletion studies confirmed that neutralization was gp120 directed and that a substantial fraction of it was mediated by CD4 binding site (CD4bs) antibodies. The data demonstrate that it is possible to elicit broadly neutralizing sera against HIV-1 in small animals, despite the restricted germline VH gene usage observed so far in broadly neutralizing CD4bs directed antibodies in humans. In Chapter 3, we also discuss design of a new construct b122d, which includes regions corresponding to b121a, but with linker connectivities similar to b122a. It was found to bind b12 with sub-micromolar affinity and also showed proteolytic resistance comparable to b121a. This indicated that though b121a showed better proteolytic resistance than b122a, it bound b12 poorly because one of the linkers might sterically occlude the b12 binding site. As the b12 binding site constructs based on the subtype B HXBc2 sequence elicited neutralizing antibodies, we chose to design similar constructs based on a subtype C sequence. The proteins (Cb122a and Cb122d) were purified from E. coli, characterized and found to bind b12 with micromolar affinity. The new constructs (b122d, Cb122a, Cb122d) will shortly be tested in animal immunizations. Disulfides are known to stabilize proteins by reducing the entropy of the unfolded state. In Chapter 4, we attempted to stabilize b122a by engineering disulfides. The disulfides are expected to rigidify the molecule and possibly improve its ability to elicit neutralizing antibodies. Some of the disulfides tested in b122a were predicted based on stereo-chemical criteria by the program MODIP (Modeling Disulfide Bridges in Proteins), while others were chosen at non-hydrogen bonded positions (NHB) on anti-parallel beta strands, based on earlier studies in the lab. Some of the disulfide mutants showed better binding to b12 and increased protection to enzymatic digestion. These disulfides were subsequently engineered into other b12 binding site constructs, namely b122d, Cb122a and Cb122d and these were biophysically characterized. Amongst the various disulfides that were tested in b122a, the one at 293-448 (according to HxBc2 numbering) was found to improve the binding to b12 by about ~16-fold. Not only did this disulfide improve the binding of b122a to b12, it also showed similar improvement in case of b122d and both the subtype C constructs tested. Moreover, since the position 293-448 is an exposed NHB position of an anti-parallel beta strand, spontaneous formation of the disulfide and the improved binding to b12 for all the proteins tested reinforces the fact that cysteines engineered at such positions leads to formation of a stabilizing disulfide. All the proteins containing the 293-448 disulfide will be used in future for rabbit immunization studies to examine if they elicit better neutralizing antibodies than the parent b122a molecule. As discussed in Chapter 2, ODEC showed a very fast rate of hydrogen exchange, indicating that it is flexible. As the 293-448 disulfide improved the binding of b12 binding site constructs, in Chapter 5, disulfides at exposed NHB positions were introduced in the context of ODEC. Previously engineered inter-domain disulfides have been shown to reduce the conformational flexibility of gp120. The disulfides in the lower beta barrel of the outer domain which harbors the CD4 binding site were found to be monomeric, oxidized and could bind neutralizing CD4bs antibodies better than the WT protein. On the other hand, the disulfides in the upper barrel of the outer domain were aggregated and bound antibodies poorly compared to the WT protein, indicating that this part of the molecule may not be well structured in the fragment. However, there was no significant change in the hydrogen exchange kinetics for these mutants. Mutations in the Phe-43 cavity of gp120 (S375W/T257S) which constrain gp120 in the CD4 bound conformation were also tested in ODEC (ODEC-CF). This protein was found to bind CD4 and VRC01 about 8 and 2 times better respectively than WT ODEC. These improved immunogens will be used shortly in rabbit immunization studies. In an attempt to improve the immunogenicity of the gp120 fragment proteins, b121a, b122a and ODEC were displayed on/conjugated to the surface of Qβ virus like particles in Chapter 6. Exposed single cysteine mutants of these proteins were purified, characterized biophysically and found to have the single cysteine free for conjugation. These were subsequently conjugated to the Qβ virus like particles through click chemistry (carried out in Prof. MG Finn’s lab at TSRI), purified and used for rabbit immunization studies. The gp120 ELISA titers of the elicited sera showed that conjugation may be a better option to display foreign antigens on the surface than genetic fusion. There was no difference in the ELISA titers with and without adjuvant, indicating that the particles are sufficiently immunogenic in themselves. Sera from these studies will be tested in neutralization assays. The overall utility of the particle based display approach will be assessed by comparing neutralization data from particle based immunizations to identical immunizations with unconjugated immunogens. Most HIV-1 broadly neutralizing antibodies are directed against the gp120 subunit of the Env surface protein. Native Env consists of a trimer of gp120:gp41 heterodimers, and in contrast to monomeric gp120, preferentially binds CD4 binding site (CD4bs) directed neutralizing antibodies over non-neutralizing ones. Some cryo-electron tomography studies have suggested that the V1V2 loop regions of gp120 are located close to the trimer interface. To understand this further, in Chapter 7, we have designed cyclically permuted variants of gp120 with and without the h-CMP and SUMO2a trimerization domains inserted into the V1/V2 loop. h-CMP-V1cyc is one such variant where 153 and 142 are the N and C terminal residues of cyclically permuted gp120 and h-CMP is fused to the N-terminus. This molecule forms a trimer under native conditions and binds CD4 and the neutralizing CD4bs antibodies b12 with significantly higher affinity relative to wtgp120. It binds the non-neutralizing CD4bs antibody F105 with lower affinity than gp120. A similar derivative, h-CMP-V1cyc1 bound the V1V2 directed broadly neutralizing antibodies PG9/PG16 with ~20 fold higher affinity compared to wild type JRCSF gp120. These cyclic permutants of gp120 are properly folded and are potential immunogens. The data also support Env models in which the V1V2 loops are proximal to the trimer interface. In Appendix A1, peptide analogs of selected secondary structural elements of gp120 were designed. Some of them were grafted on known scaffold proteins. The synthesized peptides were characterized biophysically. Most of the peptides did not have a well-defined secondary structure, indicating that they are not stable in isolation. Hence they were not pursued for further studies. One helical peptide adopted a significant amount of structure in aqueous buffer and will be shortly conjugated to carrier proteins and used in immunization studies. In Appendix A2, we created error-prone PCR libraries and loop-randomization libraries of b12 binding site constructs and attempted to screen these for better b12 binding using phage-display. However the screening was unsuccessful as the phages showed non-specific binding to b12 antibody. These libraries will be screened in future using yeast display.

HIV-1 Immunogens

HIV (Human Immuno Deficiency Virus)

Retrovirus

HIV-1 Immunogens - Design

Disulfide Mutants

B12 Binding Site Immunogen

HIV-1 Vaccine Design

HIV-1 gp120 Immunogens

gp120 Proteins

HIV-1 Immunogen Design

Biochemistry

Protein Engineering of HIV-1 Env and Human CD4

Saha, Piyali

January 2013

Since, its discovery over three decades ago, HIV has wrecked havoc worldwide. According to the UNAIDS report 2011, at present 34 million people is living with HIV and AIDS vaccine with broadly neutralizing activity still remains elusive. The envelope glycoproteins on the virion surface, is the most accessible component to the host immune system and therefore is targeted for vaccine design. However, the virus has employed various strategies to avoid the host immune response. The extremely high rate of mutations, extensive glycosylation of the envelope glycoprotein, conformational flexibility of the envelope, has made all the efforts aimed to design a broadly neutralizing immunogen futile. In Chapter1, we briefly discuss about the structural and genomic organization of the HIV-1 along with various strategies the virus has employed to evade the immune system. We also present the progress and failures encountered in the past three decades, on the way to design protective HIV vaccine and inhibitors. On the host cell surface, HIV-1 glycoprotein gp120 binds to the cell surface receptor CD4 and leads to the fusion of viral and host cellular membranes. CD4 is present on the surface of T-lymphocytes. It consists of a cytoplasmic tail, one transmembrane region, and four extracellular domains, D1−D4. sCD4 has been used as an entry inhibitor against HIV-1. However, this molecule could not neutralize primary isolates of the virus. Previously, from our lab, we had reported the design and characterization of a construct consisting of the first two domains of CD4 (CD4D12), that binds gp120 with similar affinity as soluble 4-domain CD4 (sCD4). However, the first domain alone (CD4D1) was previously shown to be largely unfolded and had 3-fold weaker affinity for gp120 when compared to sCD4 [Sharma, D.; et al. (2005) Biochemistry 44, 16192−16202]. In Chapter 2, we describe the design and characterization of three single-site mutants of CD4D12 (G6A, L51I, and V86L) and one multisite mutant of CD4D1 (G6A/L51I/L5K/F98T). G6A, L51I, and V86L are cavity-filling mutations while L5K and F98T are surface mutations which were introduced to minimize the aggregation of CD4D1 upon removal of the second domain. All the mutations in CD4D12 increased the stability and yield of the protein relative to the wild-type protein. The mutant CD4D1 (CD4D1a) with the 4 mutations was folded and more stable compared to the original CD4D1, but both bound gp120 with comparable affinity. In in vitro neutralization assays, both CD4D1a and G6A-CD4D12 were able to neutralize diverse HIV-1 viruses with similar IC50s as 4-domain CD4. These stabilized derivatives of human CD4 are useful starting points for the design of other more complex viral entry inhibitors. Most HIV-1 broadly neutralizing antibodies are directed against the gp120 subunit of the env surface protein. Native env consists of a trimer of gp120−gp41 heterodimers, and in contrast to monomeric gp120, preferentially binds CD4 binding site (CD4bs)-directed neutralizing antibodies over non-neutralizing ones. One group of cryo-electron tomography studies have suggested that the V1V2 loop regions of gp120 are located close to the trimer interface and the other group claimed that the V1V2 loop region is far from the apex of the trimer. To further investigate the position of the V1V2 region, in the native envelope trimer, in Chapter 3, we describe the design and characterization of cyclically permuted variants of gp120 with and without the h-CMP and SUMO2a trimerization domains inserted into the V1V2 loop. h-CMP-V1cyc is one such variant in which residues 153 and 142 are the N- and C-terminal residues, respectively, of cyclically permuted gp120 and h-CMP is fused to the N-terminus. This molecule forms a trimer under native conditions and binds CD4 and the neutralizing CD4bs antibodies b12 with significantly higher affinity than wild-type gp120. It binds non-neutralizing CD4bs antibody F105 with lower affinity than gp120. A similar derivative, h-CMP-V1cyc1, bound the V1V2 loop-directed broadly neutralizing antibodies PG9 and PG16 with ~15-fold higher affinity than wild-type JRCSF gp120. These cyclic permutants of gp120 are properly folded and are potential immunogens. The data also support env models in which the V1V2 loops are proximal to the trimer interface. HIV-1 envelope (env) protein gp120 has approximately 25 glycosylation sites of which ~4 are located in the inner domain, ~7-8 in the V1/V2 and V3 variable loops and the rest in the outer domain (OD) of gp120. These glycans shield env from recognition by the host immune system and are believed to be indispensable for proper folding of gp120 and viral infectivity. However, there is no detailed study that describes whether a particular potential n-linked glycan is indispensable for folding of gp120.Therefore, in Chapter 4, using rationally designed mutations and yeast surface display (YSD), we show that glycosylation is not essential for the correct in vivo folding of OD alone or OD in the context of core gp120. Following randomization of the remaining four glycosylation sites, we isolated a core gp120 mutant, which contained a single inner domain glycan and retained yeast surface expression and broadly neutralizing antibody (bNAb) binding. Thus demonstrates that most gp120 glycans are dispensable for folding in the absence of gp41. However in the context of gp160, we show that all core gp120 glycans are dispensable for folding, recognition of bNAbs and for viral infectivity. We also show that deglycosylated molecules can serve as a starting point to re-introduce epitopes for specific glycan dependent bNAbs. Several of these constructs will also be useful for epitope mapping and env structural characterization. Glycosylation of env is known to inhibit binding to germline precursors of known bNAbs. Hence the present results inform immunogen design, clarify the role of glycosylation in gp120 folding and illustrate general methodology for design of glycan free, folded protein derivatives. On the virion surface env glycoproteins gp120 and gp41 interact via non-covalent interactions and form trimers of heterodimers. Upon binding cell surface receptor CD4 and co-receptor CCR5/CXCR4, gp120 and gp41 undergo a lot of conformational changes, which ultimately lead to the fusion of viral and cellular membranes by formation of six-helix bundle in gp41. High resolution structural information is available for core gp120 and post-fusion six-helix bundle conformation of gp41. However, the structural information about the native gp120:gp41 interface in the native trimer is lacking. In Chapter 5, we describe the design and characterization of various single chain derivatives of gp120 inner doamin and gp41. Among the designed constructs, gp41-id2b is folded but is a mixture of dimer and monomer under native conditions. To facilitate, trimer formation, two trimerization domains (h-CMP and Foldon) were individually fused to the N-terminus of gp41-id2b to generate h-CMP-gp41-id2b and Foldon-gp41-id2b. Although, these molecules were proteolytically more stable than gp41-id2b, they did not form trimer under native conditions. All the single chain derivatives were designed based on the crystal structure of gp120, which was devoid of C1 and C5 domains (PDBID 1G9M). A new set of constructs to mimic the native gp120:gp41 interface will be designed and characterized based on the recently solved crystal structure of gp120 with the C1 and C5 domains (PDBID 3JWD and 3JWO). Helix-helix interactions are fundamental to many biological signals and systems, found in homo- or hetero-multimerization of signaling molecules as well as in the process of virus entry into the host. In HIV, virus-host membrane fusion during infection is mediated by the formation of six helix bundle (6HB) from homotrimers of gp41, from which a number of synthetic peptides have been derived as antagonists of virus entry. Yeast surface two-hybrid (YS2H) system is a platform, which is designed to detect protein-protein interactions occurring through a secretory pathway. In Chapter 6, we describe the use of aYS2H system, to reconstitute 6HB complex on the yeast surface and delineate the residues influencing homo-oligomeric and hetero-oligomeric coiled-coil interactions. Hence, we present YS2H as a platform for facile characterization of hetero-oligomeric interactions and design of antagonistic peptides for inhibition of HIV and many other enveloped viruses relying on membrane fusion for infection, as well as cellular signaling events triggered by hetero-oligomeric coiled coils. However, using this YS2H platform, the native hetero-oligomeric complex of gp120 and gp41 could not be captured. In Appendix 1, we report cloning, expression and purification of PΔGgp120 and ΔGgp120 from methylotrophic yeast Pichia pastoris. PΔGgp120 was purified as a secreted protein. However, in electrophoretic analyses the molecule ran as a heterogeneous smear. Further optimization of the purification protocol and biophysical characterizations of this molecule will be performed in future. In Appendix 2, gp41 variants were expressed on the yeast cell surface as a C-terminally fused protein and its interaction with externally added gp120 was monitored by FACS. The surface expression of the gp41 constructs was poor and they did not show any interaction with gp120.

Protein Engineering

HIV-1 Protease

Human CD4

HIV-1 GP120

HIV-1 Virus - Structure

HIV-1 Virus - Genomic Organization

HIV-1 Envelope Glycoprotein

HIV-1 - Host-Immune Response

HIV Vaccines

HIV Inhibitors

Human Immunodeficiency Virus (HIV)-1

HIV Immunogen Design

Human CD4D12

Human CD4D1

Molecular Biology

Protein Engineering and Stabilization of HIV-1 Envelope Glycoprotein

Kesavardana, Sannula

January 2014

A number of viral diseases such as Hepatitis B, small pox, measles, rubella and polio have effective vaccines to control or eradicate them. HIV-1 is a lentivirus which infects human immune cells and leads to the disease called AIDS (Acquired Immuno Deficiency Syndrome). Despite much effort since the three decades of its discovery, there is no effective vaccine against HIV-1. The envelope glycoprotein of HIV-1 is the most accessible protein on the virion surface and is essential for HIV-1 infection. Thus, this protein is the primary target for HIV-1 vaccine design. However, HIV-1 has acquired numerous immune evasive mechanisms to escape from the human immune system. Various factors such as high variability of the envelope sequence, presence of immune dominant variable loop regions, extensive glycosylation which masks conserved epitopes on the envelope, weak non-covalent interactions between gp120 and gp41 subunits of the envelope and the metastable nature of the envelope hinder the development of an effective vaccine against HIV-1. Various approaches have been carried out to design immunogens based on the envelope glycoprotein but so far none of these have succeeded in elicitation of a broad neutralizing antibody response. In chapter 1, brief descriptions of the HIV-1 epidemic, structural and genomic organization of HIV-1 along with the difficulties faced and progress in the development of an HIV-1 vaccine are described. HIV-1 envelope glycoprotein (Env) is a trimer of gp120-gp41 heterodimers. The gp41 subunit in the native, pre-fusion trimeric Env exists in a metastable conformation and attains a stable post-fusion six helix bundle (6HB) conformation comprised of a trimer of N-heptad repeat (NHR) and C-heptad repeat (CHR) heterodimers, that drives fusion of viral and cellular membranes. The metastable nature of gp41 drives the equilibrium towards the post-fusion conformation which favours shedding of gp120 and formation of the gp41 six helix bundle remnants from the Env trimer. These dissociated products display non-neutralizing epitopes to the immune system to drive non-neutralizing antibody responses. Design and purification of Env glycoprotein in its native trimeric form is challenging due to the instability of the functional HIV-1 native Env trimer. In chapter 2, we describe our attempts to stabilize native Env trimers by incorporation of mutations at the NHR:CHR interface that disrupt the post-fusion 6HB of gp41. The mutations V570D and I573D stabilize native JRFL Env and occlude non-neutralizing epitopes to a greater extent than the previously identified I559P mutation that it is at the interface of the NHR trimers in the 6HB. The mutations prevent sCD4 induced gp120 shedding and 6HB formation. The data suggest that positions 570 and 573 are surface proximal in the native Env. Aspartic acid substitutions at these positions stabilize native trimers through destabilization of the post fusion 6HB conformation. These mutations should enhance the exposure of native Env forms to the immune system and therefore can be used to stabilize Env in a DNA vaccine format. In previous studies, a disulfide bond was engineered between gp120 and gp41 of Env to stabilize the interactions between them (SOS gp140). An I559P mutation was also introduced to stabilize the native gp41 conformation in the context of disulfide engineered Env (SOSIP gp140). The purified, soluble SOSIP gp140 immunogens were trimeric and cleaved properly. However, these immunogens failed to elicit broad neutralizing responses. The SOSIP gp140 immunogens appear to be good conformational mimics of the native trimeric Env. Thus, it is important to understand the details of the conformation and antigenic nature of SOSIP Env to further assist the design of Env immunogens in a native-like conformation. In chapter 3, we expressed JRFL-SOSIP Env on the cell surface and probed with various gp120 and gp41 specific antibodies to investigate whether this Env protein mimics the native like Env conformation. We show that introduction of a disulfide bond between gp120 and gp41 perturbs the native Env conformation, though this effect is partially alleviated by furin expression. The introduction of the V570D mutation instead of the I559P mutation partially restored the native like conformation of disulfide engineered Env. Proper cleavage of the Env to gp120 and gp41 is essential for the formation of native Env conformation. Uncleaved Env attains non-native forms and binds to non-neutralizing antibodies. To overcome inefficient cleavage problems, we co-expressed gp120 and gp41 genes on separate plasmids in mammalian cells and monitored the formation of native like Env complexes on the cell surface. We observed a fraction of native-like Env complexes on the cell surface when gp120 and gp41 with the V570D mutation are co¬expressed. We also describe the expression of Env with a self-cleavable 2A peptide between gp120 and gp41-V570D. We conclude that co-expression of gp120 and gp41 to form native like Env complexes is possible. HIV-1 Env trimeric immunogens are believed to be better immunogens than monomeric gp120. The trimeric Env immunogens designed so far, elicited marginally better neutralizing antibody response than monomeric gp120. However, these immunogens failed to elicit antibodies which could neutralize multiple primary HIV-1 isolates. Thus, it is possible that these immunogens have failed to mimic the native Env conformation. Cryo-EM and crystal structures of Env suggested that three gp120 monomers are held together at the apex of the Env trimer and the V1V2 regions of each gp120 monomer contribute to this trimeric interface. It was also shown that two broadly neutralizing antibodies (PG9 and PG16) bind to quaternary epitopes formed by V1V2 regions. Based on these observations, we hypothesized that insertion of heterologous trimerization domains into V1V2 loops might help in the formation of native like gp120 trimers. In chapter 4, two different trimerization domains (6-helix bundle and foldon trimerization domains) were inserted at the V1 loop of gp120 and C1 and C5 regions of gp120 were deleted to reduce the conformational flexibility of gp120. The resulting constructs were not trimeric and lost binding to trimer specific antibodies, PG9 and PG16. Due to their large distances between N and C-termini, these trimerization domains might have altered the local conformation of V1V2 regions and destabilized gp120 trimer formation. Interestingly, introduction of a trimerization domain (hCMP) at the C-terminus of C1 and C5 deleted gp120 (gp120-hCMP-21), led to the formation of native-like trimers which bound to both PG9 and PG16 antibodies. These results suggest that it may be difficult to trimerize gp120 by insertion of heterologous trimerization domains into the V1V2 loop and that conformational integrity of the V1V2 region is essential for the formation of trimeric gp120 interface. V1V2 regions of gp120 form quaternary epitopes on the Env trimer and are target for several broadly neutralizing antibodies. Moreover, these regions are important for the formation of the gp120 trimeric interface in the Env. In chapter 4, we show that insertion of heterologous trimerization domains at the V1 loop failed to form native like gp120 trimers. To further investigate this issue, in chapter 5, we made cyclic permutants of the gp120 molecule to create new N and C-termini at the V1 or V2 loop regions. This allowed the insertion of heterologous trimerization domains at these loop regions without affecting the folding and stability of gp120. The hCMP trimerization domain was introduced at the N-terminus of cyclically permuted gp120 (V1cyc and V2cyc). The resulting cyclic permutants were trimeric and retained binding to several broadly neutralizing antibodies. These cyclic permutants showed 10-20 fold increased binding to quaternary epitope specific neutralizing antibodies PG9 and PGT 145. CD4 binding site directed broadly neutralizing antibodies b12 and VRC01 also showed increased affinities to these cyclic permutants. Immunization of guinea pigs with cyclic permutants elicited broad neutralizing antibody response to Tier-1 and Tier-2 HIV-1 isolates with substantially higher titers than the corresponding monomeric gp120 immunogens. The data demonstrate that cyclic permutation of gp120 did not affect the structural and functional properties of gp120. It is possible to elicit broadly neutralizing sera against HIV-1 using cyclically permuted gp120 trimers in small animals. Among several proposed cryo-EM tomography structures of trimeric Env, some suggested that the V1V2 loop regions of gp120 are located close to the trimer interface while some other structures suggested that the V1V2 loop regions of gp120 are located far from the trimer axis. The present study supports Env models in which the V1V2 loops are proximal to the trimer interface. This has recently been confirmed in high resolution cryo-EM and crystal structures of HIV-1 gp140 derivatives. HIV-1 Env subunit gp120 has 50% of its molecular mass comprised of glycans which shield Env from immune recognition. Env has approximately 25 glycosylation sites of which ~4 are located in the inner domain, ~7-8 in the V1/V2 and V3 loops and the rest in the outer domain (OD). Earlier reports suggested that the glycans are indispensable for proper folding of Env and a certain level of glycan coverage is essential for maintaining infectivity of the virion. In chapter 6, we investigated the effect of removal of glycans from core gp120 on the infectivity of the HIV-1 and on the recognition of Env by various broadly neutralizing antibodies (bNAbs). We mutated the glycosylation sites in core gp120 to the second most frequent amino acids based on multiple sequence alignment. Pseudoviral infectivity assays and mammalian cell surface display experiments show that in the context of gp160, all core gp120 glycans are dispensable for viral infectivity and for recognition of bNAbs. We also show that deglycosylated molecules can serve as a starting point to re-introduce epitopes for specific glycan dependent bNAbs. Several of the constructs will also be useful for epitope mapping and Env structural characterization. Glycosylation of Env is known to inhibit binding to germline precursors of known bNAbs. In this study we show that recognition of VRC01 germline-bNAb increases substantially with the progressive loss of glycans from JRFL pseudoviruses. This work has so far resulted in the following publications (mentioned in next page).

Protein Engineering

Human Immnodeficiency Virus (HIV)

Protein Stability

HIV-1 Envelop Glycoproteins

HIV-1 Env

HIV-1

HIV-1 Envelop Trimeric Immunogens

Envelop Glycoproteins

HIV-1 Envelop Glycoprotein Trimers

HIV-1 JRFL Env

gp120:gp41 Complexes

HIV-1 gp120

Molecular Biophysics