TY - JOUR
T1 - Advances in Understanding Stimulus-Responsive Phase Behavior of Intrinsically Disordered Protein Polymers
AU - Ruff, Kiersten M.
AU - Roberts, Stefan
AU - Chilkoti, Ashutosh
AU - Pappu, Rohit V.
N1 - Funding Information:
We are grateful to current and former members of the Chilkoti and Pappu labs for many helpful discussions. They include Jeong-Mo Choi, Michael Dzuricky, Martin Fossat, Felipe Garcia Quiroz, Tyler Harmon, Alex Holehouse, Ammon Posey, and Joe Simon. We have learned a lot through our interactions with colleagues and collaborators including Simon Alberti, Clifford Brangwynne, Nick Carroll, D. Allan Drummond, Anthony Hyman, Richard Kriwacki, Gabriel Lopez, Erik Martin, Tanja Mittag, Michael Rosen, Michael Rubinstein, and Stefan Zauscher. The US National Science Foundation supports an active collaboration between the Chilkoti and Pappu labs through grant DMR 1729783 .
Publisher Copyright:
© 2018 The Authors
PY - 2018/11/2
Y1 - 2018/11/2
N2 - Proteins and synthetic polymers can undergo phase transitions in response to changes to intensive solution parameters such as temperature, proton chemical potentials (pH), and hydrostatic pressure. For proteins and protein-based polymers, the information required for stimulus-responsive phase transitions is encoded in their amino acid sequence. Here, we review some of the key physical principles that govern the phase transitions of archetypal intrinsically disordered protein polymers (IDPPs). These are disordered proteins with repetitive amino acid sequences. Advances in recombinant technologies have enabled the design and synthesis of protein sequences of a variety of sequence complexities and lengths. We summarize insights that have been gleaned from the design and characterization of IDPPs that undergo thermo-responsive phase transitions and build on these insights to present a general framework for IDPPs with pH and pressure responsive phase behavior. In doing so, we connect the stimulus-responsive phase behavior of IDPPs with repetitive sequences to the coil-to-globule transitions that these sequences undergo at the single-chain level in response to changes in stimuli. The proposed framework and ongoing studies of stimulus-responsive phase behavior of designed IDPPs have direct implications in bioengineering, where designing sequences with bespoke material properties broadens the spectrum of applications, and in biology and medicine for understanding the sequence-specific driving forces for the formation of protein-based membraneless organelles as well as biological matrices that act as scaffolds for cells and mediators of cell-to-cell communication.
AB - Proteins and synthetic polymers can undergo phase transitions in response to changes to intensive solution parameters such as temperature, proton chemical potentials (pH), and hydrostatic pressure. For proteins and protein-based polymers, the information required for stimulus-responsive phase transitions is encoded in their amino acid sequence. Here, we review some of the key physical principles that govern the phase transitions of archetypal intrinsically disordered protein polymers (IDPPs). These are disordered proteins with repetitive amino acid sequences. Advances in recombinant technologies have enabled the design and synthesis of protein sequences of a variety of sequence complexities and lengths. We summarize insights that have been gleaned from the design and characterization of IDPPs that undergo thermo-responsive phase transitions and build on these insights to present a general framework for IDPPs with pH and pressure responsive phase behavior. In doing so, we connect the stimulus-responsive phase behavior of IDPPs with repetitive sequences to the coil-to-globule transitions that these sequences undergo at the single-chain level in response to changes in stimuli. The proposed framework and ongoing studies of stimulus-responsive phase behavior of designed IDPPs have direct implications in bioengineering, where designing sequences with bespoke material properties broadens the spectrum of applications, and in biology and medicine for understanding the sequence-specific driving forces for the formation of protein-based membraneless organelles as well as biological matrices that act as scaffolds for cells and mediators of cell-to-cell communication.
KW - collapse transitions of polymers
KW - intrinsically disordered protein polymers
KW - lower critical solution temperature
KW - stimulus-responsive phase transitions
KW - upper critical solution temperature
UR - http://www.scopus.com/inward/record.url?scp=85049344470&partnerID=8YFLogxK
U2 - 10.1016/j.jmb.2018.06.031
DO - 10.1016/j.jmb.2018.06.031
M3 - Review article
C2 - 29949750
AN - SCOPUS:85049344470
SN - 0022-2836
VL - 430
SP - 4619
EP - 4635
JO - Journal of Molecular Biology
JF - Journal of Molecular Biology
IS - 23
ER -