Project description:HIV-1 infection begins with binding of the viral envelope glycoprotein Env to the host receptor CD4, triggering a series of conformational changes that lead to fusion of the virus and cell membranes. Env, a trimer of gp120 and gp41 subunits, occupies a ‘closed’ conformation with contacts between gp120 subunits at the apex, and transitions through an ‘open’ conformation with the gp120 subunits spread apart following CD4 binding. Using deep mutational scanning, sequence-fitness landscapes were mapped for full-length Env from the clade B BaL strain interacting with CD4, and broadly neutralizing antibodies VRC01 and PG16, which preferentially bind closed Env. Contacting residues are conserved for CD4 binding, and glycosylation at N262 is critical for accessing the high-affinity CD4-bound state. By comparison, VRC01 binding is resistant to most single amino acid substitutions, an ideal quality in a broadly neutralizing antibody. Also in contrast to CD4 interaction, Env interfacial residues are under tight selection for PG16 binding to maintain a closed conformation. Screening for mutations that enhanced PG16 binding, we identified several important sites, in particular neutralization of the electropositive apical cavity that we hypothesize promotes trimer opening by electrostatic repulsion. Mutations were combined to generate Quaternary Epitope Stabilized (QES) mutants with enhanced presentation of the PG16 epitope, and the mutations were partially transferable to other HIV-1 strains. These mutational analyses offer insight into Env conformational stabilization that may assist immunogen design.

Project description:We report deep mutational scanning data for the Env protein's LLP-2 domain in the NL4-3 strain HIV-1 Env. Processed Data repersents counts for each amino acid pre and post spread

Project description:Buffering of deleterious mutations by molecular chaperones and degradation of aberrant proteins by quality control systems are both major factors that can impact the mutational landscape available to a client protein. The impacts of the proteostasis network on protein evolution are not limited to just endogenous clients, but can also shape the mutational landscapes accessible to rapidly evolving viral proteins. Here, we test the hypothesis that the composition of the host cell’s endoplasmic reticulum (ER) proteostasis network shapes the evolution of RNA viruses by focusing on human immunodeficiency virus-1 envelope (Env), a membrane glycoprotein that folds and matures in the host cell’s secretory pathway. We apply chemical genetic methods to activate the IRE1-XBP1s and/or the ATF6 transcriptional arms of the unfolded protein response in a stress-independent manner. We then quantitatively assess the impact of the resulting altered host cell ER proteostasis environments on the relative enrichment of all Env single amino acid substitutions using deep mutational scanning. We find that upregulation of host ER proteostasis factors globally reduces the mutational tolerance of HIV-1 Env, particularly upon induction of the IRE1-XBP1s transcriptional arm of the UPR. The effects of ATF6 activation are less global, but still significant at particular Env sites. The impact of the XBP1s-induced ER proteostasis environment is disparate for diverse structural elements of Env. Conserved, functionally important regions generally exhibit the largest decreases in mutational tolerance upon XBP1s activation. In contrast, specific regions of Env, including regions targeted by broadly neutralizing antibodies, display greatly enhanced mutational tolerance when XBP1s is activated. Altogether, these data reveal a new set of host factors that specifically shape the mutational space accessible to HIV Env and, more generally, provide compelling evidence that UPR-regulated proteostasis mechanisms play critical roles in membrane protein evolution.

Project description:The HIV-1 surface glycoprotein Env binds target receptors to mediate fusion of the viral and host cell membranes during infection. Env is incorporated with very low density into virions, and in some cell types, regions within the long cytosolic C-terminal tail may mediate direct or indirect associations with Gag during virus assembly and budding. Here, the mutational landscape is determined across the transmembrane and proximal cytosolic domains of Env (001428 isolate from clade C) interacting with the MA domain of Gag at cellular membranes. No evidence is found in a derivative line of HEK293 cells for specific motifs that mediate Env/MA associations.

Project description:Generation of Tier 2 HIV neutralizing antibody (nAb) responses by immunization remains a challenging problem, and the immunological barriers to induction of such responses by Env immunogens remain unclear. We explored these barriers by combining a suite of innovative techniques, including longitudinal lymph node fine needle aspirates, germinal center (GC) B cell lineage tracking, and a new method for detecting and quantifying GC T follicular helper (GC Tfh) cells, in non-human primates immunized with a native-like HIV-1 Env trimer protein (BG505 SOSIP.v5.2). A majority of immunized animals (9/12) developed Tier 2 neutralizing antibodies (nAb). Tier 2 nAb development best correlated with GC B cell magnitude in response to later booster immunizations and the quality of the Tfh help. Notably, these immunological factors distinguished between qualitatively successful and unsuccessful vaccine Ab responses, as they correlated with nAb development but did not correlate with simple Env Ab binding titers. Therefore, direct probing of germinal centers in future vaccine trials is key, as this suite of technically robust approaches provides quantitation of the proximal immune correlates of neutralizing antibody development and could allow redesign of optimal multi-stage vaccination schedules.

Project description:CD4 T follicular helper cells (Tfh) are essential for establishing serological memory and have distinct helper attributes that impact both the quantity and quality of the antibody response. Therefore, gaining insights into Tfh subsets promoting antibody persistence and functional capacity is crucial for vaccine design. We investigated the potential of inducing a mixed Tfh1/17 response to enhance HIV-1 Envelope (Env) antibodies to a DNA-prime/protein boost platform, utilizing rhesus macaques as our experimental model. Following immunization with Clade C gp140 protein formulated with cationic liposome-based formulation (CAF01), we successfully generated germinal center (GC) Tfh1/17 cells, in contrast to the predominance of GC Tfh1 cells induced with gp140 formulated in monophosphoryl lipid A+QS-21 (MPLA). Analysis of lymph nodes, employing proteomic and transcriptional approaches, demonstrated robust induction of GC responses across vaccine platforms with distinct qualitative and quantitative effects elicited by MPLA versus CAF01. While the induction of GC Tfh1 cells with MPLA and GC Tfh1/17 cells with CAF01 resulted in comparable peak HIV-Env antibody levels, there was a notable difference in antibody persistence. The MPLA group demonstrated significantly greater antibody persistence at week 8 and up to 30 weeks after final immunization compared to CAF01. Inducing GC Tfh1 cells with MPLA furthermore enhanced tier 1 neutralization titers, antibody functions, and Env-specific IgG in the rectal mucosa. Notably, IFNγ+ Env-specific Tfh responses, both in blood and lymph nodes, were higher with MPLA and correlated with Env antibody persistence. These findings suggest that vaccine platforms maximizing GC Tfh1 induction may confer protective immunity against HIV.

Project description:Deep mutational scanning of Env from the HIV-1 strain DU422 for binding to CD4 and PG16

Project description:Mutational scanning of EcFbFP

Project description:The translation pre-initiation complex (PIC) scans the mRNA for an AUG codon in favorable context, and AUG recognition stabilizes a closed PIC conformation. The unstructured N-terminal tail (NTT) of yeast eIF1A deploys five basic residues to contact tRNAi, mRNA, or 18S rRNA exclusively in the closed state. Interestingly, EIF1AX mutations altering the human eIF1A NTT are associated with uveal melanoma (UM). We found that substituting all five basic residues, and seven UM-associated substitutions, in yeast eIF1A suppresses initiation at near-cognate UUG codons and AUGs in poor context. Ribosome profiling of NTT substitution R13P reveals heightened discrimination against unfavorable AUG context genome-wide. Both R13P and K16D substitutions destabilize the closed complex at UUG codons in reconstituted PICs. Thus, electrostatic interactions involving the eIF1A NTT stabilize the closed conformation and promote utilization of suboptimal start codons. We predict UM-associated mutations alter human gene expression by increasing discrimination against poor initiation sites.

Project description:We investigate how a protein-protein interaction between two ancient transcriptional regulators (a homeodomain and MADS box protein) was gained approximately 200 million years ago in a clade of ascomycete yeasts that includes Saccharomyces cerevisiae. We combine deep mutational scanning of Matα2 with a functional selection for cooperative gene expression and tested millions of possible alternative evolutionary solutions to this interaction interface. Pooled Matα2 mutants were deeply sequenced before and after selection for functional Matα2-Mcm1 interaction. The changes in frequency of each variant allowed us to determine their relative fitness.