Faculty Directory

Eisenstein, Edward

Eisenstein, Edward

Associate Professor
Fischell Department of Bioengineering
9600 Gudelsky Drive Room A231 Rockville, MD 20850

EDUCATION

Ph.D., Georgetown University, 1985

Biophysics, molecular interactions, gene-metabolite relationships in medicinal plants, molecular basis for plant disease resistance, plant metabolic engineering for improved biofuel production.

Professor Eisentein's laboratory is investigating a number of questions involving plants, including their remarkable capacity to produce a complex array of interesting compounds, the way they respond to pathogens and disease, and also the feasibility of engineering their biosynthetic apparatus for applications ranging from human health to biofuel production.

The Eisenstein Group is currently engaged in three primary research investigations:

Metabolic Engineering of Secondary Metabolite Synthesis in Medicinal Plants of Appalachia

The Eisenstein Group's aim is to identify the genes and enzymes that are involved in the biosyntheses of the important compounds found in black cohosh, Actaea racemosa (syn. Cimicifuga racemosa (L.) Nutt.), a member of the Ranunculaceae (buttercup) family, in an effort to understand the interplay of genetic and environmental factors that are involved in the production of medicinal metabolites, and to apply that knowledge to improve the phytochemical quality of plants through metabolic engineering. Our approach has focused on developing a tissue culture system to generate a useful laboratory model for black cohosh, establishing cDNA libraries for a variety of tissues in the plant, using transcriptional profiling and LC/MS approaches to develop gene-metabolite maps for the production of cimiracemates, terpene glycosides and tryptoamine derivatives in planta, as well as protein production for structural and functional analysis of the enzymes involved in metabolite biosynthesis.

Allosteric Motor Proteins Involved in Plant Disease Resistance

We are studying the classical tobacco-tobacco mosaic virus (TMV) system as a model for the molecular basis for plant-pathogen interactions. The protein encoded by the tobacco N gene is a multi-functional, allosteric, motor protein that binds and hydrolyzes ATP to promote conformational changes that function as a molecular switch to regulate signaling pathways. The N protein, a member of the largest class of polymorphic R proteins which contain a nucleotide-binding domain, a C-terminal, leucine-rich repeat domain, and an N-terminal, Toll/interluckin-1 receptor domain, binds the helicase protein of TMV to activate the hypersensitive response in tobacco. We are exploring the mechanism of N-helicase binding, the nucleotide-promoted dissociation of the TMV helicase protein, and the conformational changes that activate signaling pathways.

Engineering Designer Lignins for Improved Production of Cellulosic Biomass for Biofuels

A principal obstacle to the saccharification of lignocellulosic biomass for ethanol production is the reduction of lignin content for the more effective action of enzymes on cellulose. Our goal in this project is to produce "engineered" lignins in vivo by manipulation and control of precursor availability and biosynthesis. Our approach builds on the discovery of dirigent proteins, which are thought to guide the formation of specific intermediates and polymers of lignin. We are designing a series of proteins that bind monolignol radicals and that promote the formation of specific stereochemical dilignol products. Longer-range goals include the incorporation of oxidase activity into engineered monolignol binding proteins to create functional enzymes capable of generating a defined suite of lignin precursors.

  • Yamniuk, A. P., Edavettal S. C., Bergqvist S., Yadav S. P., Doyle M. L., Calabrese K., et al. (2012).  ABRF-MIRG Benchmark Study: Molecular Interactions in a Three-Component System.. J Biomol Tech. 23(3), 101-14.
  • McElroy, C. A., Holland P. J., Zhao P., Lim J-M., Wells L., Eisenstein E., et al. (2012).  Structural reorganization of the interleukin-7 signaling complex.. Proc Natl Acad Sci USA. 109(7), 2503-8.
  • Spiering, M. J., Urban L. A., Nuss D. L., Gopalan V., Stoltzfus A., and Eisenstein E. (2011).  Gene identification in black cohosh (Actaea racemosa L.): expressed sequence tag profiling and genetic screening yields candidate genes for production of bioactive secondary metabolites. Plant cell reports. 30(4), 613-29.
  • Asim K. Bera, Vesna Atanasova, Howard Robinson, Edward Eisenstein, James P. Coleman, Everett C. Pesci and James F. Parsons (2009) "Structure of PqsD, A Pseudomonas Quinolone Signal Bioynthetic Enzyme, in Complex with Anthranilate," Biochemistry 48, 8644-8655.
  • Iva Naratilova, Edward Eisenstein, David G. Myszka (2005) Measuring Long Association Phases using Biacore, Analytical Biochemistry 344, 295-297.
  • D.Travis Gallagher, Dianna Chinchilla, Heidi Lau and Edward Eisenstein (2004) Local and global control mechanism in allosteric threonine deaminase, Methods in Enzymology 380, 85-106.
  • James F. Parsons, Fenhong Song, Lisa Parsons, Kelly Calabrese, Edward Eisenstein and Jane E. Ladner (2004) "Structure and Function of the Phenazine Biosynthesis Protein PhzF from Pseudomonas fluorescens 2-79," Biochemistry43, 12427-12435.
  • D. Cheon Yeh, James F. Parsons, Lisa M. Parsons, F. Liu, Edward Eisenstein and John Orban (2004) "NMR assignment of the hypothetical protein HI0004 from Haemophilus influenzae, a putative essential gene product," J. Biomol. NMR 29, 101-102.
  • David G. Myszka, Yasmina N. Abidiche, Fumio Arisaka, Olwyn Byron, Edward Eisenstein, Preston Hensley, James A. Thomson, Christian R. Lombardo, Frederick Schwarz, Walter Stafford and Michael L. Doyle (2003) The ABRF-MIRG'02 study: assembly state, thermodynamic, and kinetic analysis of an enzyme/inhibitor interaction, J. Biomolecular Techniques 14, 247-269.
  • Susan Krueger, Susan K. Gregurick, James Zondlo, and Edward Eisenstein (2003) Interaction of GroEL and GroEL/GroES complexes with a Non-native Subtilisin Variant: A Small-Angle Neutron Scattering Study, J. Structural Biology 141, 240-258.
  • James F. Parsons, Pia, Y. Jensen, Abraham S. Pachikara, Andrew J. Howard, Edward Eisenstein and Jane E. Ladner (2002) Structure of Escherichia coli Aminodeoxychorismate Synthase: Architectural Conservation and Diversity in Chorismate Utilizing Enzymes. Biochemistry 41, 2198-2208.
  • Edward Eisenstein, Gary L. Gilliland, Osnat Herzberg, John Moult, John Orban, Roberto J. Poljak, linda Banerjei, Delwood Richardson and Andrew J. Howard (2000) "Biological function made crystal clear—annotation of hypothetical proteins via structural genomics," Curr. Opinion in Biotechnology 11, 25-30.
  • D. Travis Gallagher, Gary L. Gilliland, Gaoyi Xiao, James Zondlo, Kathryn E. Fisher, Diana Chinchilla and Edward Eisenstein (1998) "Structure and Control of Pyridoxal Phosphate-Dependent Allosteric Threonine Deaminase," Structure 6, 465-475.
  • Zhanglin Lin, Frederick P. Schwarz and Edward Eisenstein (1995) "The Hydrophobic Nature of GroEL-Substrate Binding," J. Biol. Chem270, 1011-1014.
  • Edward Eisenstein, Kathryn E. Fisher, Hoon Dae Yu, Karin R. Ducote, Dominick A. Iacuzio and Frederick P. Schwarz (1995) "An Expanded Two State Model Accounts for Homotropic Cooperativity in Biosynthetic Threonine Deaminase," Biochemistry 34, 9403-9412.

Brick by Brick: The Clark School Celebrates LGBTQ+ Engineers

At Maryland Engineering, we celebrate the diversity of experiences, stories, and contributions among our community of innovators.  

Agents of Positive Change: Highlighting Women Maryland Engineers

In celebration of Women's History Month, we highlight some of the important contributions of women engineers within our campus community.

24 Teams Present at BIOE Capstone Competition Including First BCE Students

On May 8, 2023, 24 teams presented novel designs at the BIOE Capstone Design Competition.

BIOE Capstone Competition Highlights 24 Novel Projects

The Bioengineering Senior Capstone Design competition returned to in-person on Monday, May 2.

BIOE Capstone Class Virtually Presents 24 Novel Projects

BIOE seniors present Capstone projects and celebrate winners virtually.

BIOE Capstone Class Presents 20 Novel Projects

Student projects include novel pediatric medical devices, a hemofiltration system, and a tracheostomy device.

UMD iGEM Team Awarded Gold Medal for Plastic Degradation Project

Students earn international recognition for synthetic biology approach to address plastic pollution crisis.

Researchers Investigate How to Protect an Emerging Biofuel Crop from Disease

$1.1M U.S. Department of Energy (DOE) grant awarded

BIOE Capstone 2017: Projects Focus on Pediatric Care, Physical Therapy, Pulmonary Tumors, and More

BIOE hosted it's largest-ever Capstone Design competition on May 10th, 2017.

BioE Capstone 2016: New Projects Focus on Improved Healthcare for Underserved Communities, Pediatric Patients, and More

Affordable RT-PCR for clinical diagnostics, fear mitigation device for pediatric MRIs tie for first place.

UMD iGEM Team Earns Second Consecutive Gold Medal in International Competition

UMD student researchers recognized for innovative approach to accelerate construction of biodesigns.

BioE Capstone 2014: New Projects Focus on Cardiological Health, Surgical Tools and More

Students' inventions range from diagnostic devices to accident prevention products.

Bryan, Eisenstein Join BioE Faculty

Professors bring expertise in structural biology, biophysics to department.