General Research Interest:
Research
interest lies at the interface of biology and the physical sciences. The
general thrust
of my research program is aimed at developing and applying
computational methodologies to
understand structural characteristics, kinetics and
thermodynamics of peptides, proteins and
carbohydrates in the context of aqueous and lipid
environments.
In our
computational approaches, we incorporate molecular dynamics simulations with a
variety
of
techniques such as polymer theory, coarse-grained models, network theory,
sequence analysis,
machine
learning and electronic structure calculations.
Technical areas of interest:
Molecular Dynamics
Simulations
Quantum Chemical
Calculations
Enhanced Sampling Methods
Rule-based &
mechanistic kinetic models
Molecular Modeling
& Force fields
Network/Graph Theory
Coarse-graining Approaches
Free Energy and
Binding Calculations
Machine Learning
Research Projects:
Our basic science
research program is aligned towards supporting emerging national security
missions. We apply our expertise in computational structural biology
capabilities towards both
health and energy securities.
Current Research:
National Institutes of Health, NIAID
Center for HIV/AIDS Vaccine
Immunology and Discovery (CHAVI-ID)
The major
goals of this project are to provide project oversight, vaccine design, and
statistical analysis of vaccine response data. Genetic sequence statistical
analysis, and phylogenetically corrected signature
analysis of immunological/sequence data to define critical mutational patterns
associated with antibody resistance and susceptibility.
National Institutes of Health, NIAID
Optimization
Of Efflux Avoidance and Inhibition for Antibiotic Development
Failures of
antibiotic therapy occur with increasing frequency in clinics due to the spread
of multidrug resistant bacterial pathogens. The goal of the project is to develop a new technology for
optimization of efflux avoidance and inhibition in clinical and investigational
antibacterial agents that will be effective against Gram-negative bacteria by
simultaneously targeting the multidrug efflux mechanism and the outer membrane
barrier.
National Institutes of Health, NIGMS
New Mexico
Spatiotemporal Modeling Center
The major goals of this project are to
understand cell membrane spatial organization and dynamics and to determine how
the spatial proximity, dynamics, interactions and biochemical modifications of
membrane receptors and signaling proteins together determine the outcome of
complex, interacting cell signaling networks important in immune system
diseases and cancer.
NCI-DOE Joint Program
Joint Design of Advanced Computing Solutions for
Cancer
The
major goal of this project to establish DOE-NCI partnership to advance exascale development through cancer research designed to
synergize investments by the NCI and the DOE. Our efforts are focused
specifically on Pilot #2 - producing an unprecedented scale of adaptive
simulations for the RAS oncogene to facilitate new drug discovery and development.
Office of the Director of National Intelligence, IARPA
Functional Genomic and
Computational Assessment of Threats (Fun GCAT)
Explore
the chemical diversity of conopeptides from a
structural perspective while establishing relationship to sequence and function.
Evaluate how the chemical diversity of conopeptides
enables exquisite specificity and potency for specific receptors.
DOE/LANL – LDRD Directed Research
Tensor Networks: Robust Unsupervised
Machine Learning for Big-Data Analytics
Development of machine learning (ML) techniques for
efficient and robust data analyses. The objective of this project is to address
this need by development a novel ML methodology and a unique high-performance
computing toolbox to perform data analyses extracting meaningful and
interpretable features from high-dimensional extra-large datasets.
DOE/LANL – LDRD Exploratory Research
Understanding Glycan Dynamics and
Heterogeneity for Effective Human Immunodeficiency Virus (HIV) Vaccine
Development
Glycans
are ubiquitous biomolecules that play important roles in many biological fields, however, their study is complicated by their
dynamics and the distinct heterogeneous forms that can exist at a protein site.
Here, we use novel molecular dynamics simulation strategies to characterize
molecular details of glycan dynamics, and machine learning to predict dominant
type of glycan form at a site given the protein sequence.
Past Research:
* Systems
level understanding of efflux pump mediated drug resistance (funded by DOE/LANL
LDRD-DR)
*
Constraints in biomass productivity – Improving non-photochemical
quenching pathways (LDRD-ER)
* Influence
of glycosylation on protein folding and stability (funded by NIH/NIAID
(Rutgers))
* Rational
enzyme design & Deactivation of nerve agents (DTRA)
* Energy
landscape of intrinsically disordered proteins & Nuclear
pore complex (LDRD-ER)
*
Biochemical and thermochemical conversion of lignocellulosic
biomass (DOE and LDRD-ER)
*
Multivalent binding and allostery in signaling
molecules (NIH)
* Interfacing
all-atom simulations with spectral measurements (LDRD-ER)
*
Perturbation of local solvent and protein structures by metals (LDRD-DR)
* Role of
glycolipids and sugars in host-pathogen interactions (LDRD-DR)
Current Research Group
Animesh Agarwal (Research Postdoctoral
Fellow)
Jeevapani Hettige (Research Postdoctoral
Fellow)
Srirupa Chakraborty (CNLS Postdoctoral
Fellow)
Rachael Mansbach (Directors Postdoctoral Fellow)
** Postdoc positions
available ** see LANL jobs site for details
Former Postdocs
Tongye Shen (CNLS Postdoctoral
Fellow) – Faculty at University
of Tennessee & Oakridge National Lab
Parthasarthi Ramakrishnan (Directors Postdoctoral Fellow) – Scientist
at CSIR
Giovanni Bellesia (CNLS Postdoctoral Fellow) – Scientist at Roche
Pharmaceuticals
Anurag Sethi (CNLS Postdoctoral Fellow)
– Senior Scientist at Calico/Google
Jianhui Tian (Research Postdoctoral Fellow) –
Data Scientist
Joshua Phillips (LANL
Metropolis Fellow) – Faculty at MTSU
Cesar Lopez (CNLS
Postdoctoral Fellow) – Staff Scientist at LANL
Tim Travers (Research Postdoctoral Fellow) –
Scientist at Pebble Labs
Tyler Reddy
(Directors Postdoctoral Fellow) - Staff Scientist at LANL
Patents
Acute
transmitted hiv envelope
signatures (2008)
Genetic
signatures in envelope glycoprotein of hiv-1 (2010)
Mosaic
hiv envelope immunogenic
polypeptides (2015)
Selected Publications:
Just over
100 publications with more than 5000 citations (h-index: 38) covered at least
six diverse scientific topics. Five key publications are given under each
scientific topic.
1. Dynamics of surface proteins of HIV,
Allosteric effects, Glycosylation and Vaccine design
a. Hansen SG, Wu HL, Burwitz BJ,
Hughes CM, Hammond KB, Ventura AB, Reed JS, Gilbride
RM, Inslie EA, Morrow DW, Ford JC, Selseth AN, Pathak R, Malouli D, Legasse AW, Axthelm MK, Nelson JA, Gillespie GM, Walters LC,
Brackenridge S, Sharpe HR, L用ez CA, Fr殄 K, Korber BT, McMichael AJ, Gnanakaran S, Sacha JB, Picker
LJ. Broadly targeted CD8+ T cell
responses restricted by major histocompatibility complex E. Science. 2016. Feb. 12, 351, pp
714-20. PMCID: PMC4769032.
b. Gnanakaran S, Bhattacharya T, Daniels M, Keele BF, Hraber PT, Lapedes AS, Shen T, Gaschen B,
Krishnamoorthy M, Li H, Decker JM, Salazar-Gonzalez JF,
Wang S, Jiang C, Gao F, Swanstrom
R, Anderson JA, Ping LH, Cohen MS, Markowitz M, Goepfert
PA, Saag MS, Eron JJ, Hicks
CB, Blattner WA, Tomaras
GD, Asmal M, Letvin NL,
Gilbert PB, Decamp AC, Magaret CA, Schief WR, Ban YE, Zhang M, Soderberg
KA, Sodroski JG, Haynes BF, Shaw GM, Hahn BH and Korber B. Recurrent
signature patterns in HIV-1 B clade envelope glycoproteins associated with
either early or chronic infections. PLoS Pathog. 2011.
Sep;7(9):e1002209. PMCID: PMC3182927
c. Gnanakaran S, Daniels M, Bhattacharya T, Lapedes AS, Sethi A, Li M, Tang
H. Greene K, Gao H,
Haynes B,
Cohen MS, Shaw GM, Seaman M, Kumar A, Gao F, Montefiori D and Korber B. Genetic signatures in the envelope
glycoproteins of HIV-1 that are associated with broadly neutralizing
antibodies. PLoS Computational Biology. 2010. 6(10), e1000955. PMCID:
PMC2951345
d. Sethi
A, Tian J, Derdeyn C, Korber B and Gnanakaran S. A mechanistic understanding of allosteric
immune escape pathways in the HIV-1 envelope protein. PLoS
Comp. Biology. 2013. 9:e1003046.
e. Tian J, L用ez CA, Derdeyn CA, Jones MS,
Pinter A, Korber BT, and Gnanakaran
S. Effect of glycosylation on an immunodominant region in the V1V2 variable domain of the
HIV-1 envelope gp120 protein. 2016.
PLoS Comput Biol 12(10): e1005094. PMCID: PMC5055340
2. Antibiotic resistance mechanisms and Permeation barrier
of Gram-negative bacterial envelope
a. Zgurskaya HI, L用ez CA, and Gnanakaran S. Permeability
barrier of gram-negative cell
envelopes
and approaches to bypass it. ACS Infect. Dis. 2015. 1 (11), pp 512–522
b. Phillips JL and Gnanakaran
S. A data-driven approach to modeling the
tripartite structure of multidrug resistance efflux pumps. Proteins. 2015. 83, 46-65. PMID: 24957790
c. Travers T, Wang KJ, Lopez CA, and Gnanakaran
S. Sequence-and structure-based
computational analyses of Gram-negative tripartite efflux pumps in the context
of bacterial membranes. Research in Microbiology. 2018 (in press) https://doi.org/10.1016/j.resmic.2018.01.002
d. Mueller RT,
Travers T, Cha H, Phillips JL, Gnanakaran S, and Pos KM. Switch loop flexibility affects substrate transport
of the AcrB efflux pump. Journal of molecular
biology. 2018. 429(24), 3863-3874.
e. L用ez CA, Travers T, Pos KM, Zgurskaya HI, and Gnanakaran S. Dynamics of intact MexAB-OprM
efflux pump: focusing on the MexA-OprM interface.
Scientific reports. 2018. Vol. 7,
16521.
3. Molecular aspects of initiation of cell signaling events at
the membrane in Cancer and Allergy
a. L用ez
CA, Sethi A, Goldstein B, Wilson B, and Gnanakaran S. Membrane-mediated
regulation of
the
intrinsically disordered CD3 ε cytoplasmic tail of the TCR. Biophys.
J. 2015. 108, 2481.
b. Sethi A,
Goldstein B and Gnanakaran S. Quantifying intramolecular binding in
multivalent interactions: a structure-based synergistic study on Grb2:Sos1
complex. PLoS Comput.
Biol. 2011. :e1002192.
c. Carpenter
TS, L用ez CA, Neale C, Montour C, Ing様fsson
HI, Natale FD, Lightstone
FC, and
Gnanakaran S. Capturing Phase Behavior of Ternary
Lipid Mixtures with a Refined Martini Coarse Grained Force Field. Journal of
Chemical Theory and Computation. 2018. (In
press).
d. Travers T, L用ez CA, Van QN, Neale C, Tonelli
M, Stephen AG, and Gnanakaran S. Molecular
recognition of RAS/RAF complex at the
membrane: Role of RAF cysteine-rich domain. Scientific
Reports. 2018. 8, 8461.
e. L用ez
CA, Swift MF, Xu XP, Hanein
D, Volkmann N and Gnanakaran S. Biophysical characterization of
a nanodisc with and without an embedded protein: An
integrative study using molecular dynamics
simulations
and cryo-EM. Structure. 2018.
(In revision).
4. Intrinsically
disordered proteins in signaling and Misfolding
diseases (Alzheimerユs and related dementia)
a. Sethi A, Tian
J, Vu DM, Gnanakaran S. Identification of minimally interacting modules in an intrinsically
disordered protein. Biophys J. 2012. Aug 22;103(4):748-57. PMCID: PMC3443776
b. Gnanakaran S, Hochstrasser
RM, and Garcia AE. Nature of structural inhomogeneities on folding a helix and their influence on
spectral measurements. Proc. Natl.
Acad. Sci. USA. 2004.
9229-9234. PMCID: PMC438958
c. Gnanakaran S, Nymeyer
H, Portman J, Sanbonmatsu K, and Garcia AE. Peptide folding
simulations. Curr. Opin. Struct. Biol. 2003. 13:168-174. PMID: 12727509
d. Sethi A, Anunciado D, Tian J, Vu DM, and Gnanakaran S. Deducing conformational variability of
intrinsically disordered proteins from infrared spectroscopy with Bayesian
statistics. Chem. Phys. 2013.
422:143. PMCID: PMC3810979
e. Tian J, Sethi A, Anunciado D, Vu DM, and Gnanakaran S. Characterization
of a disordered protein during micellation:
interactions of α-synuclein with sodium dodecyl
sulfate. Journal of Physical Chemistry B. 2012. 116(15),
4417-4424.
5. Toxins, Virulence factors and Host-Pathogen Interactions
a. L用ez CA, Unkefer CJ, Swanson BI, Swanson JMJ, and Gnanakaran S. Membrane
perturbing properties of toxin mycolactone from
Mycobacterium ulcerans. PLoS
Comp. biology. 2018. 14(2),
e1005972.
b. Tian J, Sethi
A, Swanson B, Goldstein B, and Gnanakaran S. Taste of sugar at the
membrane: thermodynamics and kinetics of the interaction of a
disaccharide with lipid bilayers. Biophys. J. 2013. 104: 622-32. PMCID: PMC3566452
c. Parthasarathi R, Tian J, Redondo
A, and Gnanakaran S. A quantum chemical study of
carbohydrate-phospholipid interactions. J. Phys. Chem
A. 2011. 115, 12826-40.
d. Vuyisich M, Gnanakaran
S, Lovchik JA, Lyons R, and Gupta G. A dual-purpose protein ligand for
effective therapy and sensitive
diagnosis of anthrax. Protein J. 2008. 27, 292-302. PMID: 18649128
e. Mukundan
H, Price DN, Goertz M, Parthasarathi
R, Monta撲 GA, Kumar S, Scholfield
MR, Anderson
AS,
Gnanakaran S, Iyer S,
Schmidt J, and Swanson BI. Understanding
the interaction of lipoarabinomannan with membrane
mimetic architectures. Tuberculosis.
2012. 92:38. PMID: 22033469
6. Multi-scale modeling studies of plant cell wall components
and Degradation by cocktail of enzymes
a. Gao D, Chundawat SP, Sethi
A, Balan V, Gnanakaran S
and Dale BE. Increased enzyme binding to
substrate is not necessary for more efficient cellulose
hydrolysis. Proc. Natl. Acad. Sci. 2013.
110(27):10922. PMCID:
PMC3703979
b. L用ez CA, Bellesia G, Redondo A, Langan P, Chundawat PS, Dale BE, Marrink SJ
and Gnanakaran S. MARTINI
coarse-grained model for crystalline cellulose microfibers. J. Phys. Chem. B. 2015. 119 (2), pp 465–473. PMID: 25417548
c. Asztalos A, Daniels M, Sethi
A, Shen T, Langan P,
Redondo A and Gnanakaran S. A coarse-grained model for synergistic action of multiple enzymes on
cellulose. Biotechnol Biofuels. 2012. Aug 1;5(1):55.
d. R. Parthasarathi, R. A. Romero, A.
Redondo, and S. Gnanakaran. Theoretical study of the remarkably
diverse linkages in lignin. J. Phys. Chem. Letters. 2011. 2, 2660–2666.
e. Mayes
HB, Tian J, Nolte MW, Shanks BH, Beckham GT, Gnanakaran and Broadbelt LJ. Sodium ion interactions with aqueous
glucose: insights from quantum mechanics, molecular dynamics, and experiment.
Journal of Physical Chemistry B. 2013.
118(8), 1990-2000.