This is the author accepted manuscript. The final version is available from the publisher via the DOI in this recordWhen solving constrained multi-objective optimization problems, an important issue is how to balance convergence, diversity and feasibility simultaneously. To address this issue, this paper proposes a parameter-free constraint handling technique, a two-archive evolutionary algorithm, for constrained multi-objective optimization. It maintains two collaborative archives simultaneously: one, denoted as the convergence-oriented archive (CA), is the driving force to push the population toward the Pareto front; the other one, denoted as the diversity-oriented archive (DA), mainly tends to maintain the population diversity. In particular, to complement the behavior of the CA and provide as much diversified information as possible, the DA aims at exploring areas under-exploited by the CA including the infeasible regions. To leverage the complementary effects of both archives, we develop a restricted mating selection mechanism that adaptively chooses appropriate mating parents from them according to their evolution status. Comprehensive experiments on a series of benchmark problems and a real-world case study fully demonstrate the competitiveness of our proposed algorithm, in comparison to five state-of-the-art constrained evolutionary multi-objective optimizers.Royal Society (Government)Ministry of Science and Technology of ChinaScience and Technology Innovation Committee Foundation of ShenzhenShenzhen Peacock PlanEngineering and Physical Sciences Research Council (EPSRC

Chen, R

Fu, G

Li, K

Yao, X

arXiv

Mathur, Mohit C.

Kobayashi, Tomoyoshi

Chalovich, Joseph M.

Elsevier - Publisher Connector 

Cardiomyopathy Causing Mutations Stabilize an Intermediate State of Thin Filaments 

When solving constrained multi-objective optimization problems, an important issue is how to balance convergence, diversity and feasibility simultaneously. To address this issue, this paper proposes a parameter-free constraint handling technique, a two-archive evolutionary algorithm, for constrained multi-objective optimization. It maintains two collaborative archives simultaneously: one, denoted as the convergence-oriented archive (CA), is the driving force to push the population toward the Pareto front; the other one, denoted as the diversity-oriented archive (DA), mainly tends to maintain the population diversity. In particular, to complement the behavior of the CA and provide as much diversified information as possible, the DA aims at exploring areas under-exploited by the CA including the infeasible regions. To leverage the complementary effects of both archives, we develop a restricted mating selection mechanism that adaptively chooses appropriate mating parents from them according to their evolution status. Comprehensive experiments on a series of benchmark problems and a real-world case study fully demonstrate the competitiveness of our proposed algorithm, in comparison to five state-of-the-art constrained evolutionary multi-objective optimizers

Li, Ke

Chen, Renzhi

Fu, Guangtao

Yao, Xin

University of Birmingham Research Portal

Two-Archive Evolutionary Algorithm for Constrained Multi-Objective Optimization

Open Research Exeter

IEEE Transactions on Evolutionary Computation

English

Two-archive evolutionary algorithm for constrained multi objective optimization

Tuesday, March 3, 2009 377aC98S) in a cardiac TnI core structure (McTnI-ND29-Cys) did not affect the
COOH-terminal conformation of TnI and preserved binding to TnT and TnC.
McTnI-ND29-Cys purified from bacterial culture was fluorescently labeled
with the Alexa Fluor 532 dye and used to reconstitute troponin complex. After
verifying the ratio of fluorophore to protein conjugation by spectrophotometer
and SDS-PAGE, Ca2þ-titrations were performed for fluorescence intensity
and polarization changes. The results demonstrated Ca2þ regulated conforma-
tional/environmental changes as well as flexibility change in the COOH termi-
nus of TnI. Further experiments are performed to measure the Ca2þ-induced
structural changes in reconstituted myofilaments to understand the function of
TnI COOH terminal domain in calcium-regulation of muscle contraction.
1936-Plat
Cardiomyopathy Causing Mutations Stabilize an Intermediate State of
Thin Filaments
Mohit C. Mathur1, Tomoyoshi Kobayashi2, Joseph M. Chalovich1.
1Brody School of Medicine, East Carolina University, Greenville, NC, USA,
2University of Illinois at Chicago, Chicago, IL, USA.
Congenital cardiomyopathies are initiated by changes in ATP hydrolysis and re-
sult in hypertrophy, fibrosis, andmyofibrillar disarray.We studied themechanism
by which mutations in troponin and tropomyosin change ATPase rates and have
linked several mutants to inappropriate switching between the inactive and active
states of the actin thin filament. We have shown that troponin I mutants mimick-
ing protein kinase C phosphorylation stabilize the inactive state of actin filaments
whereas theD14 TnTmutant stabilizes the active state.We have now shown that
two mutations on troponin I, R146G and R146W, which cause cardiomyopathy
produce complex effects on ATPase activity. These TnI mutations produced in-
creased ATPase rates in the absence of calcium and decreased rates in the pres-
ence of calcium compared to wild type. These differences were maintained at
high actin concentrations. Saturating concentrations of the activator NEM-S1
equalized the rates of both the mutants and wild type. The NEM-S1 data rule
out alterations in rate constants of transitions (i.e. product release) along theactive
pathway. The results from the R146G and R146Wmutants have implications for
the function of the 3 structural states of regulated actin that have been observed.
That is, the results can be explainedmost readily if the mutants stabilize an inter-
mediate state in both calcium and EGTA with an activity between that of the in-
active and active states. In the past we have assumed that the intermediate state
had properties identical to the inactive state. Our current data show that while
the intermediate more closely resembles the inactive state it has unique proper-
ties. Our present results, as well as previous results, indicate that inappropriate
stabilization of any state of regulated actin can result in cardiac dysfunction.
Platform AI: Protein Dynamics I
1937-Plat
Probing Conformational Motion of Serpin by Time-Resolved and Single
Molecule Fluorescence
Chin Wing Ko1, Wenhua Zhou1, Richard J. Marsh2, Daven A. Armoogum2,
Nick Nicolaou2, Angus J. Bain2, Zhenquan Wei3, Aiwu Zhou3,
Liming Ying1.
1Imperial College London, London, United Kingdom, 2University College
London, London, United Kingdom, 3University of Cambridge and
Cambridge Institute for Medical Research, Cambridge, United Kingdom.
Serpin (serine protease inhibitor) is a structural prototype for the study of the
molecular mechanism of many diseases due to the conformational instability
which leads to protein aggregation. The inhibitory function of serpin relys on
a flexible loop undertaking a striking conformational transition, but this prop-
erty also leaves serpin at risk of polymerization. We have investigated the con-
formational dynamics of the reaction center loop (RCL) of the plasminogen
activator inhibitor-1 (PAI-1) by time resolved fluorescence spectroscopy. The
RCL becomes more solvent exposed and exhibits faster rotation when PAI-1
interacts with an octapeptide which blocks the loop insertion pathway, indicat-
ing that the RCL is well displaced from the protein surface. A heterogeneous
population model with three rotational correlation times has been developed
to account for the ‘‘dip and rise’’ observed in fluorescence anisotropy decays.
We have also employed single molecule FRET to probe the conformational
change of serpin under different environment and the early stage of its ployme-
rization process. Preliminary results will be presented.
1938-Plat
Evolution of enzyme fold: Linking protein dynamics and catalysis
Pratul K. Agarwal.
Oak Ridge National Laboratory, Oak RIdge, TN, USA.
Enzymes are dynamic molecules. In the past, enzymes have been viewed as
static entities and their high catalytic power has been explained on the basisof direct structural interactions between the enzyme and the substrate. Recent
evidence has linked protein dynamics to catalytic efficiency of enzymes.
Further, motions in hydration-shell/bulk solvent have been shown to impact
protein motions, therefore, function.
Theoretical and computational studies of protein dynamics linked to enzyme
catalysis will be discussed. Investigations of cyclophilin A and dihydrofolate
reductase have lead to the discovery of networks of protein vibrations promot-
ing catalysis. Results indicate that the reaction promoting dynamics in these
enzymes is conserved across several species. Moreover, we have characterized
the protein dynamics of a diverse super-family of dinucleotide binding en-
zymes. These enzymes share very low sequence similarity and have different
structural features. The results show that the reaction promoting dynamics is
remarkably similar in this enzyme super-family.
1939-Plat
Function And Activity Of Von Willebrand Factor Is Regulated By
A Hierarchy Of Mechanical Forces
Carsten Baldauf1, Tobias Obser2, Antje Pieconka3, Sonja Schneppenheim3,
Ulrich Budde3, Reinhard Schneppenheim2, Frauke Graeter1.
1CAS-MPG PICB, Shanghai, China, 2University Medical Center Hamburg-
Eppendorf, Hamburg, Germany, 3AescuLabor Hamburg, Coagulation Lab,
Hamburg, Germany.
The von Willebrand factor (VWF) is a shear-flow sensitive multimeric protein.
Under normal flow conditions VWF is in a globular state, it unfolds at high shear
rates and is activated for adhesion at the blood vessel wall [Schneider et al. 2007
PNAS p7899]. The elongation of multimeric VWF results in a force pulling
along the VWF length axis. Based on a model of the VWF A domain organiza-
tion, we performed force probe molecular dynamics simulations. We reveal the
basis of two force-sensing VWF functions, and test the results by experiments.
Our results indicate a competition between VWF A2 domain and glycoprotein
Ib (GPIb) for the same binding site of the VWF A1 domain. When the stretch-
ing force along VWF reaches a critical point, the A1 A2 interaction is lost. The
domains remain connected by a linker that gives space for GPIb to bind to the
A1 domain. We thus suggest a force-dependent platelet binding to VWF as me-
diated by GPIb, which is experimentally testable and represents an alternative
mechanism to recently published studies [Chen et al. 2008 Biophys J p1303;
Lou et al. 2008 PNAS p13847].
We show how proteolysis of the VWF is activated under shear conditions. The
specific proteolytic site is buried in the VWFA2 domain [Sutherland et al. 2004
J Mol Model p259]. At extreme forces as present in high molecular weight
VWF multimers, the A2 domain C terminus unfolds until the ADAMTS13
cleavage site is uncovered. Introducing a disulfide bond by mutagensis prevents
VWF cleavage. This explains the size regulation of VWF by ADAMTS13:
larger multimers involve higher pulling forces and therefore higher unfolding
rates under shear flow. Larger VWF is cleaved faster, preventing blood clots
and thrombosis [in preparation].
1940-Plat
Experimental Confirmation of an NtrC Transition Pathway Predicted
by Targeted MD
Janice Velos, Ming Lei, Ce Feng Liu, Phillip Steindel, Dorothee Kern.
Brandeis University, Waltham, MA, USA.
The infinitely short lifetime of transition states makes characterization
extremely difficult. We have used a combination of molecular dynamics and
experimental approaches to determine two important rate-limiting interactions
involved in the allosteric transition of a signaling protein. Targeted MD simula-
tions of the receiver domain of NtrC (Nitrogen Regulatory Protein C) were used
to predict interactions that are important in stabilizing the transition state be-
tween the known inactive and active structures of the protein. Mutations were
made to test these predictions and the rate of exchange between the two sub-
states were measured by 15N-CPMG relaxation dispersion experiments. The re-
sults verify the importance of these key interactions in the transition pathway of
NtrC. This work shows that targeted molecular dynamics together with experi-
mental validation can be an invaluable tool at elucidating the structure and
rate-limiting interactions of conformational transitions.
1941-Plat
Real-time 3D Tracking of Structural Transitions in Adenylate Kinase by
Thermal Noise Imaging
Yunhsiang Hsu, Vijay Rana, Arnd Pralle.
SUNY Buffalo, Amherst, NY, USA.
Proteins have to be flexible enough to support turn-over rates up to hundreds
per second, yet stable enough to maintain their three-dimensional structure
over hours and days. As result of thermal excitation they fluctuate between
structural conformations. We measured thermally excited structural fluctua-
tions in the Adenylate Kinase using a site-specifically attached nanoparticle


Mohit C. Mathur

Tomoyoshi Kobayashi

Joseph M. Chalovich

Crossref

Cardiomyopathy Causing Mutations Stabilize an Intermediate State of Thin Filaments

http://pure-oai.bham.ac.uk/ws/files/58789097/Li_et_al_2018_Two_archive_evolutionary_algorithm_IEEE_Transactions_on_Evolutionary_Computation.pdf

Cardiomyopathy Causing Mutations Stabilize an Intermediate State of Thin Filaments

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