Abstract

The predictable engineering of well-behaved transcriptional circuits is a central goal of synthetic biology. The artificial attachment of promoters to transcription factor genes usually results in noisy or chaotic behaviors, and such systems are unlikely to be useful in practical applications. Natural transcriptional regulation relies extensively on protein-protein interactions to insure tightly controlled behavior, but such tight control has been elusive in engineered systems. To help engineer protein-protein interactions, we have developed a molecular dynamics simulation framework that simplifies features of proteins moving by constrained Brownian motion, with the goal of performing long simulations. The behavior of a simulated protein system is determined by summation of forces that include a Brownian force, a drag force, excluded volume constraints, relative position constraints, and binding constraints that relate to experimentally determined on-rates and off-rates for chosen protein elements in a system. Proteins are abstracted as spheres. Binding surfaces are defined radially within a protein. Peptide linkers are abstracted as small protein-like spheres with rigid connections. To address whether our framework could generate useful predictions, we simulated the behavior of an engineered fusion protein consisting of two 20,000 Da proteins attached by flexible glycine/serine-type linkers. The two protein elements remained closely associated, as if constrained by a random walk in three dimensions of the peptide linker, as opposed to showing a distribution of distances expected if movement were dominated by Brownian motion of the protein domains only. We also simulated the behavior of fluorescent proteins tethered by a linker of varying length, compared the predicted Förster resonance energy transfer with previous experimental observations, and obtained a good correspondence. Finally, we simulated the binding behavior of a fusion of two ligands that could simultaneously bind to distinct cell-surface receptors, and explored the landscape of linker lengths and stiffnesses that could enhance receptor binding of one ligand when the other ligand has already bound to its receptor, thus, addressing potential mechanisms for improving targeted signal transduction proteins. These specific results have implications for the design of targeted fusion proteins and artificial transcription factors involving fusion of natural domains. More broadly, the simulation framework described here could be extended to include more detailed system features such as non-spherical protein shapes and electrostatics, without requiring detailed, computationally expensive specifications. This framework should be useful in predicting behavior of engineered protein systems including binding and dissociation reactions.

Highlights

  • Predictable manipulation of transcriptional networks is a central goal of synthetic biology

  • To help engineer proteinprotein interactions, we have developed a molecular dynamics simulation framework that simplifies features of proteins moving by constrained Brownian motion, with the goal of performing long simulations

  • The simulation tools we propose here could be used for designing novel DNA-binding complexes, or artificial proteins acting at any other step in signal transduction

Read more

Summary

Introduction

Predictable manipulation of transcriptional networks is a central goal of synthetic biology. Transcriptional regulation that plays a key role in the physiology of the organism often involves elaborate protein-protein interactions that are spatially and quantitatively tuned to give a desired result. Lambda repressor binds to its operators in a highly cooperative manner that involves three distinct protein-protein interactions so that an octameric complex can form in the fully repressed state.. Lambda repressor binds to its operators in a highly cooperative manner that involves three distinct protein-protein interactions so that an octameric complex can form in the fully repressed state.1,2 Another striking example is the Kai clock found in photosynthetic bacteria.. Another striking example is the Kai clock found in photosynthetic bacteria.3 In this system, the KaiC protein goes through 24-h cycles of autophosphorylation and dephosphorylation, modulated by the KaiA and KaiB proteins. In higher eukaryotes, the key events in determining transcriptional patterns often take place at the cell surface and in the cytoplasm, and are essentially decided by the time a transcription factor enters the nucleus

Objectives
Results
Conclusion

Talk to us

Join us for a 30 min session where you can share your feedback and ask us any queries you have

Schedule a call

Disclaimer: All third-party content on this website/platform is and will remain the property of their respective owners and is provided on "as is" basis without any warranties, express or implied. Use of third-party content does not indicate any affiliation, sponsorship with or endorsement by them. Any references to third-party content is to identify the corresponding services and shall be considered fair use under The CopyrightLaw.