Da Silva Lab Molecular Biotechnology Da Silva Lab Molecular Biotechnology.

Slides:

Advertisements

Similar presentations

The post-genomic challenge Exploring function across protein families using chemical probes  The CPFM is in early stages of development  Projects focus.

Advertisements

Rosemary Dobson University of Stellenbosch

Microbial Genetics genomics.  200 level (sophomore) course  Majors in Biology, Biotechnology and those applying for professional programs (Pharmacy.

CHALLENGE BASED LEARNING PROGRAM - Mass Transport in Bioprocess JIANG, Guoqiang Ph.D. | Associate Prof. Dept. Chem. Tsinghua University, Beijing,

MB304 Industrial & Environmental Biotechnology Module 1 Industrial Microbiology 1 Prepared by: Ms. Lim Yin Sze.

SIRM Investigation of Metabolic Trafficking between Neurons and Astrocytes Fan, T. W-M. Yuan, P., Lane, A.N., Higashi, R.M. Wang, Y., Hamidi, A., Zhou,

Production of the Antimalarial Drug Precursor Artemisinic Acid in Engineered Yeast February 12, 2007 Patrick Gildea By J.D. Keasling et all.

Orm family proteins mediate sphingolipid homeostasis Presentation by: Gillian Dekkers and Soledad Ordoñez Supervisor: Joost Holthuis David K. Breslow et.

Metabolic Engineering: A Survey of the Fundamentals Lekan Wang CS374 Spring 2009.

Synthetic Biology in the Quest for Renewable Energy

Applications of Synthetic Biology Kristala L. J. Prather Department of Chemical Engineering, Massachusetts Institute of Technology NSF Synthetic Biology.

By: John Heller Period 3.  The study of the chemical processes within a living organism.

Biomolecular and Cellular Engineering Microbes Enzymes Biomolecules Metabolic Engineering Biopolymer Antibody Nano-Devices, Sensors, Environmental, Biosynthetic.

TEMPLATE DESIGN © Synthetic Consortium for Cellulose Hydrolysis and Ethanol Production David Pham, Shen-Long Tsai, Anjali.

Biopolyester Particles. Inclusions in MOs Inorganic Inclusions: – Magnetosomes Organic Inclusions: – Biopolyester granules (PHA)

Enzymatic hydrolysis of lignocelluloses Cloning, expression, and characterization of β-glucosidases Annette Sorensen 1,2, Peter S. Lübeck 1, Mette Lübeck.

Food Biotechnology Dr. Tarek Elbashiti 5. Metabolic Engineering of Bacteria for Food Ingredients.

Overview of Biotechnology Research and Capabilities at UIC  Biotechnology may be associated with images of gene sequencing, drug development, and food.

Synthetic biology Genome engineering Chris Yellman, U. Texas CSSB.

Yeast Hardening for Cellulosic Ethanol production Bianca A. Brandt Supervisor: Prof J Gorgens Co-Supervisor: Prof WH Van Zyl Department of Process Engineering.

Hochbaum Lab Hochbaum Lab

Chapter 24, Future Design Issues Paul King. Biomedical Engineering Handbook Bioelectric Phenomena Biomaterials Biomedical Sensors/Instrumentation Biomedical.

SYNBIOLOGY - An Analysis of Synthetic Biology Research in Europe and North America 4,5/4,5 CM SYNBIOLOGY: An Analysis of Synthetic Biology Research in.

Speaker: Jeng-Chen Liu(劉政成) Student ID: P

Wang Lab Nanostructured Biomaterials Wang Lab Nanostructured Biomaterials

The influence of bipolar drugs on the phospholipid biosynthetic pathway in Saccharomyces cerevisiae This study investigates a specific yeast, Saccharomyces.

Biotechnology pp WHAT IS IT?  Biotechnology : the application of technology to better use DNA and biology.

OMICS Group Contact us at: OMICS Group International through its Open Access Initiative is committed to make genuine and.

Jonathan Sun University of Illinois at Urbana Champaign BIOE 506 February 15, 2010

Genetic modification of flux (GMF) for flux prediction of mutants Kyushu Institute of Technology Quanyu Zhao, Hiroyuki Kurata.

Kevin Correia, Goutham Vemuri, Radhakrishnan Mahadevan Pathway Tools Conference, Menlo Park, CA March 6 th, 2013 Elucidating the xylose metabolising properties.

CONFIDENTIAL 2012 Ingenza NewProt Kick-off meeting 25 Jan 2012 Nijmegen Ian Archer Ingenza Ltd Roslin, Edinburgh UK.

Microbial Biotechnology Products from Microorganisms LECTURE 12: Biotechnology; 3 Credit hours Atta-ur-Rahman School of Applied Biosciences (ASAB) National.

Ragan Lab Self-Organization of Nanosystems Ragan Lab Self-Organization.

Venugopalan Lab Photons and Transport

 Alcohols for fuel: Biological energy to usable energy Beth Papanek.

1 Departament of Bioengineering, University of California 2 Harvard Medical School Department of Genetics Metabolic Flux Balance Analysis and the in Silico.

CHALLENGES FACED IN THE DEVELOPMENT OF BIOSIMILARS Dr.G.Hima Bindu MD; PG dip. diabetology Asst.Professor Dept. of Pharmacology Rajiv Gandhi Institute.

Yeast transformation Uptake of foreign DNA by a cell changes its phenotype.

Genetic Circuit Challenge Workshop Thursday 24 Nov 2011 Bentham seminar room 1.

Kwon Lab BioTherapeutics Engineering Laboratory (BioTEL)

Laboratory for Cellular and Metabolic Engineering Engineering biology to produce biomolecules, fuels, and pharmaceuticals Hal Alper Department of Chemical.

Towards Renewable Petrochemicals Engineering biology to convert waste into fuel To construct a library of defined BioBrick parts, each encoding an enzymatic.

Introduction: Acknowledgments Thanks to Department of Biotechnology (DBT), the Indo-US Science and Technology Forum (IUSSTF), University of Wisconsin-Madison.

Department of Chemical Engineering & Materials Science Michigan State University Departmental Highlights Presented By: Martin C. Hawley Professor & Chairperson.

Metabolic pathway alteration, regulation and control (3) Xi Wang 01/29/2013 Spring 2013 BsysE 595 Biosystems Engineering for Fuels and Chemicals.

Engineering microbial cell factories for biosynthesis of isoprenoid molecules: beyond lycopene Daniel Klein-Marcuschamer, Parayil Kumaran.

Cloning and Expression in Saccharomyces cerevisiae of The NAD(P)H-dependent Xylose Reductase- Encoding Gene (XYLI) From The Xylose-assimilating Yeast Pichia.

Jun Xu, Taifo Mahmud* and Heinz G. Floss* Department of Chemistry, University of Washington, Box , Seattle, WA Identification and Characterization.

Essence of Metabolic Engineering

Chapter 24, Future Design Issues Paul King. NSF SBIR/STTR solicitations Geonomics Geonomics Proteonomics Proteonomics Bioinformatics Bioinformatics Biochips.

Systems metabolic engineering of Bacillus subtilis for efficient N-acetylglucosamine production Long Liu Jiangnan University 8 th Euro Biotechnology Congress-2015.

Bio-technology.  Proving bread with leaven prehistoric  Alcoholic drinks from fermented juices prehistoric  Vinegar from fermented juices prehistoric.

Improved Galactose Fermentation of Saccharomyces cerevisiae Through Inverse Metabolic Engineering 1 조 조장 : 우대균 조원 : 김상민 박동주 박지연 이혁 길영욱.

Production of vitamin B12 in escheria coli

Self-Assembly of Surfactant-like Peptides

SEMINAR 1. Title : Generation of Nucleic Acid Biopolymers with Complex Functionalities 2. Speaker : Prof. Seung Soo Oh (Department of Materials Sci. and.

Chapter 24, Future Design Issues

BRC Science Highlight Mechanism of Ionic Liquid Toxicity and Rational Engineering of a Tolerant Yeast Strain Objective To identify genetic determinants.

Bioluminescent Yeast Reporter (BLYR)/CNC Toxicity Assay

Prof. Rui L. Reis, CEng, MSc, PhD, DSc, MD (Doctor h

Chapter 24, Future Design Issues

Investigating the Relationship between Characteristics of Heterogeneous Cellulose and Cellulase Activities Y-H Percival Zhang, Biological Systems Engineering,

Department of Chemical Engineering

More Chores for TOR: De Novo Ceramide Synthesis

Recent advance in the pharmacogenomics of human Solute Carrier Transporters (SLCs) in drug disposition Zhou F, Zhub L, Wang K, Murray M Advanced Drug Delivery.

Yanchang Wang Biomedical Sciences

BRC Science Highlight Developmental regulation of processes, pathways, and genes that affect stem growth and composition in sorghum Objective Obtain information.

Biotechnology Training & Researching in University of Natural Science

BRC Science Highlight Yeast evolved for enhanced xylose utilization reveal interactions between cell signaling and Fe-S cluster biogenesis Objective Obtain.

Presentation transcript:

Da Silva Lab Molecular Biotechnology Da Silva Lab Molecular Biotechnology Research Summary: A major focus of our research is metabolic pathway engineering in yeast, focusing on both the development of improved methods and their application to diverse pathways. The research emphasizes molecular level design combined with subsequent application and analysis. Our work ranges from engineering Saccharomyces cerevisiae for the synthesis of polyketides (a very valuable class of pharmaceuticals) and collagen-based biopolymers, to engineering yeast for biorenewable and environmental applications. Current projects in my lab include: 1. Development of Tools for Metabolic Pathway Engineering Focus is on the stable introduction and expression of multiple genes to optimize pathway engineering in yeast 2. Microbial Metabolic Engineering for the Synthesis of Biorenewable Chemicals (Member of CBiRC, an NSF Engineering Research Center) 3. Metabolic Engineering of Yeast for Biofuels Production Use of cellulosomes to control the display of enzymes on the cell surface for increased synergy and rapid uptake of the released sugars 4. Optimizing S. cerevisiae for the Synthesis of Polyketides Primary focus are the fungal iterative polyketide synthases for 6-MSA and lovastatin synthesis 5. Synthesis and Characterization of Cell-Responsive Biopolymers Expression and application of collagen-based biopolymers useful for tissue engineering, drug delivery, and stem cell research Research Summary: A major focus of our research is metabolic pathway engineering in yeast, focusing on both the development of improved methods and their application to diverse pathways. The research emphasizes molecular level design combined with subsequent application and analysis. Our work ranges from engineering Saccharomyces cerevisiae for the synthesis of polyketides (a very valuable class of pharmaceuticals) and collagen-based biopolymers, to engineering yeast for biorenewable and environmental applications. Current projects in my lab include: 1. Development of Tools for Metabolic Pathway Engineering Focus is on the stable introduction and expression of multiple genes to optimize pathway engineering in yeast 2. Microbial Metabolic Engineering for the Synthesis of Biorenewable Chemicals (Member of CBiRC, an NSF Engineering Research Center) 3. Metabolic Engineering of Yeast for Biofuels Production Use of cellulosomes to control the display of enzymes on the cell surface for increased synergy and rapid uptake of the released sugars 4. Optimizing S. cerevisiae for the Synthesis of Polyketides Primary focus are the fungal iterative polyketide synthases for 6-MSA and lovastatin synthesis 5. Synthesis and Characterization of Cell-Responsive Biopolymers Expression and application of collagen-based biopolymers useful for tissue engineering, drug delivery, and stem cell research Prof. Nancy A. Da Silva Full Professor B.S. Chemical Engineering, U. Massachusetts, Amherst (1982) M.S. Chemical Engineering, California Institute. of Technology (1985) Prof. Nancy A. Da Silva Full Professor B.S. Chemical Engineering, U. Massachusetts, Amherst (1982) M.S. Chemical Engineering, California Institute. of Technology (1985) Key Publications: S. Srikrishnan, A. Randall, P. Baldi, N.A. Da Silva* Rationally selected single-site mutants of the Thermoascus aurantiacus endoglucanase increase hydrolytic activity on cellulosic substrates. Biotechnol. Bioeng. In press. N.A. Da Silva*, S. Srikrishnan MiniReview: Introduction and expression of genes for metabolic engineering applications in Saccharomyces cerevisiae. FEMS Yeast Res. In press. F. Fang, K. Salmon, M.W.Y. Shen, K.A. Aeling, E. Ito, B. Irwin, U. Tran, G.W. Hatfield, N.A. Da Silva*, S. Sandmeyer* A vector set for systematic metabolic engineering in Saccharomyces cerevisiae. Yeast. 28: D. Shah, M.W.Y. Shen, W. Chen, N.A. Da Silva* Enhanced arsenic accumulation in Saccharomyces cerevisiae overexpressing transporters Fps1p or Hxt7p. J. Biotechnol. 150: S.W.P. Chan, S.-P. Hung, S.K. Raman, G.W. Hatfield, R.H. Lathrop, N.A. Da Silva*, S.-W. Wang* Recombinant human collagen and biomimetic variants using a de novo gene optimized for modular assembly. Biomacromolecules. 11: S.M. Ma, J.W.-H. Li, J. W. Choi, H. Zhou, K.K.M. Lee, V.A. Moorthie, X. Xie, J.T. Kealey, N.A. Da Silva, J.C. Vederas*, and Y. Tang* Complete reconstitution of a highly-reducing iterative polyketide synthase. Science. 326: Key Publications: S. Srikrishnan, A. Randall, P. Baldi, N.A. Da Silva* Rationally selected single-site mutants of the Thermoascus aurantiacus endoglucanase increase hydrolytic activity on cellulosic substrates. Biotechnol. Bioeng. In press. N.A. Da Silva*, S. Srikrishnan MiniReview: Introduction and expression of genes for metabolic engineering applications in Saccharomyces cerevisiae. FEMS Yeast Res. In press. F. Fang, K. Salmon, M.W.Y. Shen, K.A. Aeling, E. Ito, B. Irwin, U. Tran, G.W. Hatfield, N.A. Da Silva*, S. Sandmeyer* A vector set for systematic metabolic engineering in Saccharomyces cerevisiae. Yeast. 28: D. Shah, M.W.Y. Shen, W. Chen, N.A. Da Silva* Enhanced arsenic accumulation in Saccharomyces cerevisiae overexpressing transporters Fps1p or Hxt7p. J. Biotechnol. 150: S.W.P. Chan, S.-P. Hung, S.K. Raman, G.W. Hatfield, R.H. Lathrop, N.A. Da Silva*, S.-W. Wang* Recombinant human collagen and biomimetic variants using a de novo gene optimized for modular assembly. Biomacromolecules. 11: S.M. Ma, J.W.-H. Li, J. W. Choi, H. Zhou, K.K.M. Lee, V.A. Moorthie, X. Xie, J.T. Kealey, N.A. Da Silva, J.C. Vederas*, and Y. Tang* Complete reconstitution of a highly-reducing iterative polyketide synthase. Science. 326: