Computational Design of Selective Peptides to Discriminate between Similar PDZ Domains in an Oncogenic Pathway

Zheng, Fan; Jewell, Heather; Fitzpatrick, Jeremy; Zhang, Jian; Mierke, Dale F.; Grigoryan, Gevorg

doi:10.1016/j.jmb.2014.10.014

Cited by 24 publications

(24 citation statements)

References 73 publications

(106 reference statements)

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“…It involves aspects of both positive design , as the AB interaction must be favored, and negative design (Hecht et al, 1990), as the AC interaction must be disfavored. Multistate design (MSD) (Davey and Chica, 2012), which designs for multiple protein states simultaneously, has proven itself useful in designing a single protein sequence to adopt multiple conformations (Ambroggio and Kuhlman, 2006; Fromer et al, 2009), in understanding what kind of sequences can adopt multiple conformations (Babor et al, 2011; Humphris and Kortemme, 2007; Willis et al, 2013), and in designing specificity such as when designing a protein to bind one target but to avoid another (Ashworth et al, 2010; Grigoryan et al, 2009; Zheng et al, 2014) or when organizing multimeric assemblies (Fallas and Hartgerink, 2012; Havranek and Harbury, 2003; Lewis et al, 2014). …”

Section: Introductionmentioning

confidence: 99%

Computationally Designed Bispecific Antibodies using Negative State Repertoires

et al. 2016

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A challenge in the structure-based design of specificity is modeling the negative states, i.e. the complexes that you do not want to form. This is a difficult problem because mutations predicted to destabilize the negative state might be accommodated by small conformational rearrangements. To overcome this challenge, we employ an iterative strategy that cycles between sequence design and protein docking in order to build up an ensemble of alternative negative state conformations for use in specificity prediction. We have applied our technique to the design of heterodimeric CH3 interfaces in the Fc region of antibodies. Combining computationally- and rationally-designed mutations produced unique designs with heterodimer purities greater than 90%. Asymmetric Fc crystallization was able to resolve the interface mutations; the heterodimer structures confirmed that the interfaces formed as designed. With these CH3 mutations, and those made at the heavy-/light-chain interface, we demonstrate one-step synthesis of four fully IgG bispecific antibodies.

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Section: Introductionmentioning

confidence: 99%

Computationally Designed Bispecific Antibodies using Negative State Repertoires

et al. 2016

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“…Future design studies will help calibrate the methods so that diverse sequences can be obtained with reliably high success rates. Combining dTERMen with a post-analysis procedure that includes all-atom modeling with aggressive conformational search, using peptide redocking [51] or MD simulation [52], could be one way to recognize sequences or mutations that can or cannot be accommodated. Although this would increase the computational costs, such a secondary evaluation could be performed for a modest number of promising candidates designs.…”

Section: Discussionmentioning

confidence: 99%

Tertiary structural motif sequence statistics enable facile prediction and design of peptides that bind anti-apoptotic Bfl-1 and Mcl-1

Frappier

Jenson

Zhou

et al. 2018

Preprint

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Understanding the relationship between protein sequence and structure well enough to rationally design novel proteins or protein complexes is a longstanding goal in protein science. The Protein Data Bank (PDB) is a key resource for defining sequence-structure relationships that has supported the development of critical resources such as rotamer libraries and backbone torsional statistics that quantify the probabilities of protein sequences adopting different structures. Here, we show that well-defined, noncontiguous structural motifs (TERMs) in the PDB can also provide rich information useful for proteinpeptide interaction prediction and design. Specifically, we show that it is possible to rapidly predict the binding energies of peptides to Bcl-2 family proteins as accurately as can be done with widely used structure-based tools, without explicit atomistic modeling. One benefit of a TERM-based approach is that prediction performance is less sensitive to the details of the input structure than are methods that evaluate energies using precise atomic coordinates. We show that protein design using TERM energies (dTERMen) can generate highly novel and diverse peptides to target anti-apoptotic proteins Bfl-1 and Mcl-1. 15 of 17 peptides designed using dTERMen bound tightly to their intended targets, and these peptides have just 15 -38% sequence identity to any known native Bcl-2 family protein ligand. Highresolution structures of four designed peptides bound to their targets provided opportunities to analyze strengths and limitations of this approach. Dramatic success designing peptides using dTERMen, which comprised going from input structure to experimental validation of high-affinity binders in approximately one month, provides strong motivation for further developing TERM-based approaches to design.

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“…Multistate design is particularly challenging when designing positively for some criteria but negatively against others (33), requiring that the goals be treated separately instead of simply combined into a single goal. A variety of algorithmic approaches, based on explicit structural modeling (34-37), sequence potentials derived from the evolutionary record (15), and sequence potentials derived from structural modeling (38), have driven applications such as modifying protein interaction specificity (39)(40)(41), designing peptide inhibitors (42)(43)(44), altering substrate specificity (45)(46)(47), characterizing resistance mechanisms (48), and enabling a single protein to adopt multiple folds (49). We have focused on a Pareto optimization framework (50) as the basis for elucidating and explicitly optimizing trade-offs between criteria and thereby providing the recently well-discussed advantages of provable optimality guarantees, such as enabling more direct interpretation of experimental data according to the driving models without concern for algorithmic bias or sampling failure (17).…”

Section: Discussionmentioning

confidence: 99%

Computationally optimized deimmunization libraries yield highly mutated enzymes with low immunogenicity and enhanced activity

Salvat

Verma

Parker

et al. 2017

Proc. Natl. Acad. Sci. U.S.A.

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Therapeutic proteins of wide-ranging function hold great promise for treating disease, but immune surveillance of these macromolecules can drive an antidrug immune response that compromises efficacy and even undermines safety. To eliminate widespread T-cell epitopes in any biotherapeutic and thereby mitigate this key source of detrimental immune recognition, we developed a Pareto optimal deimmunization library design algorithm that optimizes protein libraries to account for the simultaneous effects of combinations of mutations on both molecular function and epitope content. Active variants identified by high-throughput screening are thus inherently likely to be deimmunized. Functional screening of an optimized 10-site library (1,536 variants) of P99 β-lactamase (P99βL), a component of ADEPT cancer therapies, revealed that the population possessed high overall fitness, and comprehensive analysis of peptide-MHC II immunoreactivity showed the population possessed lower average immunogenic potential than the wild-type enzyme. Although similar functional screening of an optimized 30-site library (2.15 × 10 9 variants) revealed reduced population-wide fitness, numerous individual variants were found to have activity and stability better than the wild type despite bearing 13 or more deimmunizing mutations per enzyme. The immunogenic potential of one highly active and stable 14-mutation variant was assessed further using ex vivo cellular immunoassays, and the variant was found to silence T-cell activation in seven of the eight blood donors who responded strongly to wild-type P99βL. In summary, our multiobjective library-design process readily identified large and mutually compatible sets of epitope-deleting mutations and produced highly active but aggressively deimmunized constructs in only one round of library screening.deimmunization | computational protein design | immunogenicity | T-cell epitope | combinatorial library P rotein engineering techniques have enabled targeted modification of biotherapeutics to mitigate the T-cell-mediated immune response that otherwise can undermine clinical applications (1). These approaches mutate specific amino acids in a therapeutic candidate so as to disrupt MHC II binding of constituent peptides processed from the protein following uptake by antigen-presenting cells (APCs). The amino acid substitutions prevent APCs from displaying peptide epitopes to cognate CD4 +

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Computational Design of Selective Peptides to Discriminate between Similar PDZ Domains in an Oncogenic Pathway

Cited by 24 publications

References 73 publications

Computationally Designed Bispecific Antibodies using Negative State Repertoires

Computationally Designed Bispecific Antibodies using Negative State Repertoires

Tertiary structural motif sequence statistics enable facile prediction and design of peptides that bind anti-apoptotic Bfl-1 and Mcl-1

Computationally optimized deimmunization libraries yield highly mutated enzymes with low immunogenicity and enhanced activity

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