Percival Zhang

Education

Ph.D., Chemical Engineering and Biotechnology, Dartmouth College, 2002

M.S., Biochemical Engineering, East China University of Science and Technology, 1996

B.S., Biochemical Engineering, East China University of Science and Technology, 1993

Experience

Aug 2014 - present – Professor, Department of Biological Systems Engineering, Virginia Tech

Aug 2010 - July 2014 – Associate Professor, Department of Biological Systems Engineering, Virginia Tech

Aug 2005 - July 2010 – Assistant Professor, Department of Biological Systems Engineering, Virginia Tech

May 2004 - Aug 2005 – Research Scientist, Dartmouth College

May 2002 - May 2004 – Postdoc Research Associate, Dartmouth College

Selected Major Awards

  • 2014 - Academic editor, PLoS One
  • 2012 - Deputy Editor-in-Chief, Energy Science and Engineering
  • 2011 - College of Engineering Faculty Fellow Award (Virginia Tech)
  • 2010 - Daniel I.C. Wang Award (Biotechnology and Bioengineering and ACS BIOT)
  • 2009 - Sunkist Engineering Designer Award (ASABE)
  • 2008 - British Petroleum Young Scientists Award (IBS 2008)
  • 2008 - DuPont Young Faculty Award
  • 2008 - College of Engineering Outstanding New Faculty Award (Virginia Tech)
  • 2008 - Air Force Young Investigator Award (Air Force Of Scientific Research, AFOSR)
  • 2007 - American Chemical Society PRF New Faculty Award
  • 2006 - Best and Brightest of Esquire Magazine (science and technology and crazy idea)
  • 2006 - Ralph E. Powe Junior Faculty Enhancement Award
  • 2004 - 1st Class Award for Advancement of Science & Technology (Ministry of Education, China)

Courses Taught Last Five Years

  • BSE 3524 - Unit Operations In Biological Systems
  • BSE 5944 - Graduate Seminar
  • BSE 5624 - Enzyme engineering

Other Teaching and Advising

I am a member of the BSE graduate committee and  co-chair of BSE Public & Alumni Relations (Publications) Committee (2011-present).

We wish to suggest constructing the electricity-carbohydrate-hydrogen (ECHo) cycle, could meet four basic needs of humans: air, water, food and energy, while minimizing environmental footprints. In it, electricity is a universal high-quality energy carrier; hydrogen is a clear electricity carrier; and carbohydrate is a hydrogen carrier, an electricity storage compound and sources for food, feed and materials. By using this cycle, we could replace crude oil with carbohydrates (CH2O), feed the world, power cellular phone, produce renewable materials, etc.

Program Focus

We conduct our research project based on two platforms: cascade enzyme factories and microbial cell factories (e.g., E. coli and Bacillus subtilis). Based on cascade enzyme factories, our specific projects are

  1. Sweet hydrogen and sugar fuel cell vehicles.  To break the Thauer limit for natural hydrogen-producing microorganisms, we have achieved the production of theoretical yield hydrogen from hexose (i.e., 12 H2 per glucose unit). Via it, we propose the use of sugar as a hydrogen carrier. The hypothetical sugar fuel cell vehicles would be the most energy efficiency vehicles. A small fraction of the USA biomass could be sufficient to replace all gasoline.
  2. High-power and high-energy density enzymatic fuel cells (i.e., bioinspired sugar battery).  To increase fuel utilization efficiency, we have designed the pathways that can produce 24 electrons per glucose for the first time.
  3. Artificial photosynthesis for CO2 utilization.  To surpass natural limits of plant photosynthesis, we propose a new system by integrating solar cell, water electrolysis and CO2 fixation with 20-50 higher energy utilization efficiency and 500-1000 fold higher water conservation.  
  4. Enzymatic synthesis of renewable materials.  

By utilizing microbial cell factories, our specific projects include

  1. Cellulase engineering and recombinant cellulolytic Bacillus subtilis.  
  2. Enzyme engineering by rational design and directed evolution. We are developing redox enzymes that can work on low-cost biomimics.
  3. Low-cost recombinant protein production and purification as building blocks for cascade enzyme factories.

Current Projects

  • “Construction of cellulosomes and their model”  -- this multidisciplinary project funded by DOE BioEnergy Science Center.  My research topics are construct synthetic cellulosomes that can hydrolyze cellulose efficiently and develop models elucidating complicated relationship among heterogeneous substrate and different action mode cellulase components.
  • “Proof-of-concept of sweet hydrogen” – is funded by Shell Game Changer Program. At phase I, we are engineering two redox enzymes working on biomimic cofactors and increasing hydrogen generation rates by 10 fold.
  • “Synthetic Crop for Direct Biofuel Production through Rerouting the Photosynthesis Intermediates and Engineering Terpenoid Pathways”  -- this multidisciplinary project funded by DOE ARPA-E Petro.  My work helped construct synthetic metabolons in the production of terpenoid for engineered plants and redirect metabolic fluxes.
  • “High-power enzymatic fuel cell” was funded by AFOSR MURI.  Now we are funded by CALS BBRC and develop the prototype before commercialization.

Selected Recent Publications

(* undergraduate student, ** graduate student, *** post-doc)

  • Zhang Y-HP, Sun JB, Ma YH. 2017. Biomanufacturing: history and perspective. Journal of Industrial Microbiology & Biotechnology. Epub. DOI: 10.1007/s10295-016-1863-2.
  • Kim J-E**, Zhang Y-HP. 2016. Biosynthesis of D-xylulose 5-phosphate from D-xylose and polyphosphate through a minimized two-enzyme cascade.  Biotechnology and Bioengineering. 113, 275-282.
  • Rollin JA**, Martin del Campo JS**, Myung S**, Sun FF**, You C***, Bakovic AE*, Castro RL*, Chandrayan S*, Wu C-H, Adams MWW, Senger R, Zhang Y-HP. 2015. High-yield hydrogen production from biomass by in vitro metabolic engineering: Mixed sugars coutilization and kinetic modelling. Proceedings of the National Academy of Sciences of the United States of America. 112: 4964-4969.
  • Zhu Z.G.**, T.K. Tam***, F.F. Sun**, C. You, Y.-H.P. Zhang. 2014. A high-energy-density sugar biobattery based on a synthetic enzymatic pathway. Nature Communications 5: 3026.
  • You C., H.G. Chen, S. Myung**, N. Sathisuksanoh**, H. Ma***, X.Z. Zhang***, J.Y. Li, Y.-H.P. Zhang. 2013. Enzymatic transformation of non-food biomass to starch. Proceedings of the National Academy of Sciences of the USA 110: 7182-7189. (Highlighted by Science magazine.)
  • Martin del Campo J.S.**, J.R. Rollin**, S. Myung**, C. You, S. Chandrayan, R. Patiño,  M.W.W. Adams, Y.-H.PZhang. 2013. Dihydrogen production from xylose and water mediated by synthetic cascade enzymes. Angewandte Chemie International Edition 52:4587-4590. (Editor’s choice paper).
  • You C***, S. Myung**, Y.-H.P. Zhang. 2012. Self-assembled trifunctional enzyme complex facilitated substrate channeling. Angewandte Chemie International Edition 51: 8787-8790.
  • Zhang Y.-H.P., Huang WD***2012. Constructing the electricity-carbohydrate-hydrogen cycle for sustainability revolution. Trends in Biotechnology 30: 301-306 (Opinion).
  • Zhang Y.-H.P. 2011. Substrate channeling and enzyme complexes for biotechnological applications. Biotechnology Advances 29: 715-725.   
  • Huang W.D.***, Y.-H.P. Zhang. 2011. Analysis of biofuels production from sugar based on three criteria: Thermodynamics, bioenergetics, and product separation. Energy and Environmental Science 4:784-792.                      

10 selected publications from 150+ peer-reviewed jounral publications and invited book chapters. The complete publication list is available at google scholar website.

Selected Recent Funding

  • DOE EERE. Sweet hydrogen: High-yield hydrogen production from biomass sugars catalyzed by in vitro synthetic biosystems. PI, Y-HP Zhang, $926,587. 06/2015-06/2017.
  • NSF SBIR II. High-power and high-energy-density enzymatic fuel cell through an in vitro synthetic enzymatic pathway. $667,745. 04/2014-04/2016.
  • DOE ARPA-E. “Synthetic Crop for Direct Biofuel Production through Rerouting the Photosynthesis Intermediates and Engineering Terpenoid Pathways”, Co-PI, Y-HP Zhang, $112,291, DOE ARPA-E Petro, 02/2012-07/2013.
  • “Proof-of-concept of sweet hydrogen”, PI, Y-HP Zhang, $450,000, Shell Game Changer, 12/2011-11/2013.
  •  “MURI – Bioengineering fuel cells”, Co-PI, Y-HP Zhang, $273,310, AFOSR, 03/2009-06/2011.
  • AFOSR. YIP-Accelerating the Rate-Limiting Step of Novel Enzymatic Hydrogen Production by Enzyme Engineering. PI, Y-HP Zhang, $352,538, 03/2008-06/2011.
  • DOE BioEnergy Science Center – Construction of cellulosomes and their model, PI, Y-HP Zhang, $1,500,000, DOE, 09/2007-06/2012.
Percival Zhang

(540) 231-7414

ypzhang@vt.edu

Biofuels and Carbohydrates Lab