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Personal page of Yonghua Li


Updated in February 2012

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Dr. Yonghua LI

CEA Research Scientist (sept 2009 - )

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Currently serves as the review editorial board for Frontiers in Plant Metabolism and Chemodiversity (Janv 2012 - )

For complete reference on my work, please visit My Google Scholar: http://scholar.google.fr/citations?user=c9FasSUAAAAJ&hl=fr

UMR 6191, University Aix Marseille
CEA Cadarache
13108 Saint Paul lez Durance

Tel : +33 (0) 4 42 25 46 51
Fax: +33 (0) 4 42 25 62 65

Email: yonghua.li@cea.fr

   
SHORT BIOGRAPHY

Born 1974, China.
Research associate (2003-2008): lab of Professor John Ohlrogge (Michigan State University, USA)
Postdoctral Fellow (2003): lab of Professor Lorna Casselton (University of Oxford, UK)
PhD in Biological Sciences (2002): lab of Professor Colin Ratledge (University of Hull, UK)

 
RESEARCH INTERESTS

In view of global warming caused by increased CO2 emission, and soaring fossil fuel prices, there is strong interest in developing alternative and renewable source of energy including wind, hydrogen, and biofuel. Due to its high carbon fixation efficiency, and lack of competition with plants for arable lands, microalgae pose as a competitive platform for bioenergy production (Figure 1). Many microalgae species when subjected to stress such as removal of nitrogen from the media can make significant amount of oil, in some case, it can reach over 70%. This dependence on stress limits biomass therefore overall productivity of the system.

Oil is the most reduced form of energy found in nature, and represents twice more energy per gram dry biomass than other storage compounds (starch or protein). Oil (= triacylglycerols), as the name implies, is composed of three often different fatty acids which are esterified to the 3 hydroxyl groups of a glycerol backbone (Figure 2). Function and chemical properties of the oil are conferred largely by the structure of the fatty acids present. Many thousands of fatty acid structures occur in nature. They differ in the total number of carbon, degree of unsaturation, with or without further fatty acid modification (for example, hydroxylation, epoxidation, dicarboxylation etc).

Fatty acids and lipids are synthesized by all cell types. Besides their role as a major form of carbon and energy storage, fatty acids are basic building blocks of biological membranes, part of cellular signalling network, form protective outer envelopes. Research on lipids is both fundamental and applied. From a biotechnological point of view, lipids are essential part of our diet, source of chemical feedstock, and a major player as a renewable fuel.

My broad interest is to discover genes or proteins involved in lipid metabolism and use this knowledge to increase oil deposition or produce industrially important fatty acids via biotechnological means. To address these questions, we routinely apply a combination of molecular-genetic, biochemical and microscopic approaches in the model plant Arabidopsis thaliana and in the model green algae Chlamydomonas reinhardtii. Specifically, a series of questions we ask:

  1. What are the mechanisms of oil accumulation in microalgae?
  2. What are the cellular events which underlie the trigger of oil accumulation?
  3. What are the key enzymes and proteins involved in oil metabolism in algae?
  4. Is this processes regulated at a transcriptional level?
   
CURRENT PROJECTS
1. An integrated overview of oil accumulation and degradation in microalgae

As a first step toward understanding oil accumulation in Chlamydomonas reinhardtii, we followed the changes in cell morphology, chlorophyll, starch and lipid (membrane and storage) content over time (Figure 3). Upon removal of nitrogen from the media, the appearance of cellular oil droplet and starch granules is coincident with the disappearance of chlorophyll and thylakoid membranes. The stored oil and starch are rapidly degraded upon nitrogen re-availability. The molecular mechanisms of this accumulation and degradation are poorly understood. Results obtained down this line should yield important insights into the lipid homeostasis and therefore the overall fitness of cells.

2. Oil bodies

Oil bodies are subcellular compartment where neutral lipids are stored. It is ubiquitous in all eukaryotes. Other names for this cellular compartment are lipid droplets or oleosomes. Oil bodies are spherical organelles consisting of a neutral lipid core enclosed by a membrane lipid monolayer coated with proteins. Until fair recently, oil bodies are considered only as an energy and carbon storage site. Modern mass spectrometry has revealed the presence of many proteins in the isolated oil body fraction. Well characterized structural proteins of oil droplet include oleosins found in oilseeds, or perilipin in adipocytes.

Using mass spectrometry on purified oil bodies from Chlamydomonas, our lab together with several other labs have identified a novel structural protein of algal oil bodies – named Major Lipid Droplet Protein (MLDP). Besides this protein, numerous metabolic enzymes or lipid trafficking proteins are also present for example acyl activating enzymes, acyltransferases or lipases. The enzymes present span the key steps of the triacylglycerol synthesis pathway and including a glycerol-3-phosphate acyltransferase (GPAT), a lysophosphatidic acid acyltransferase (LPAT) and a putative phospholipid:diacylglycerol acyltransferase (PDAT) (Figure 4). Oil bodies are now believed to be not only the storage compartments (sink) but also are dynamic structures (node) likely to be involved in processes such as oil synthesis, degradation and lipid homeostasis.

Detailed characterization of these oil body associated proteins should yield important insight into the compartmentalization and the role of oil bodies in algae.

 
3. Genetic approaches

Most of our current knowledge on oil synthesis in algae is deduced from plant pathways based on comparative genomics or sequence homologies. Few proteins of lipid metabolisms have been characterizes so far. To reveal novel players of oil metabolism in algae, we have set up a forward genetic screen (Figure 5). Chlamydomonas is a unicellular microalga and most of its life cycle stays as haploid. Generation of mutants is therefore a very powerful approach because the mutant phenotype can be seen in the first generation. Several methods of high throughput screening have been set up (Nile Red neutral lipid staining coupled with flow cytometer, cell counter and HP-TLC; direct transmethylation and GC-FID). Screening of mutants with one of the following phenotypes is underway:

  1. Mutants that store more cellular oil than its progenitor
  2. Mutants that can store oil in non-stress conditions
  3. Mutants that produce oil with an altered, preferentially improved, fatty acid profile
   
PUBLICATIONS
  1. Li-Beisson Y (2012). Triacylglycerol biosynthesis in eukaryotic microalgae - the biological basis for a sustainable 3rd generation biofuel. Lipid library, American Society of Oil Chemist (AOCS), edited by William Bill Christie.
  2. Nguyen HM, Baudet M, Cuiné S, Adriano JM, Barthe D, Billion E, Bruley C, Beisson F, Peltier G, Ferro M, LI-BEISSON Y* (2011). Proteomic profiling of oil-bodies isolated from the unicellular green microalga Chlamydomonas reinhardtii: with focus on proteins involved in lipid metabolism. Proteomics(*corresponding author)
  3. Li-Beisson Y and Peltier G (2011). Biocarburants: le défi des microalgues. Pour la Science issue 78 (in French) (invited contribution)
  4. Siaut M, Cunié S, Cagnon C, Fessler B, Nguyen M, Carrier P, Beyly A, Beisson F, Triantaphylidès C, LI-BEISSON Y* and Peltier G (2011), Oil accumulation in the model green alga Chlamydomonas reinhardtii: characterization, variability between common laboratory strains and relationship with starch reserves. BMC Biotechnology , 11:7 doi:10.1186/1472-6750-11-7 (*corresponding author)
  5. LI-BEISSONY (2011). Cutin and Suberin. In: Encyclopedia of Life Sciences (ELS), John Wiley & Sons, Ltd: Chichester Doi: 10.1002/9780470015902.a0001920.pub2 (revue)
  6. LI-BEISSON Y*, Shorrosh B, Beisson F, Andersson M, et al. (2010) Acyl Lipid Metabolism: in The Arabidopsis Book, Rockville, MD: American Society of Plant Biologists doi: 10.1199/tab.0133 (*corresponding author)
  7. Manas-Fernandez A, Li-Beisson Y, Alonso, DL and Garcia-Maroto F (2010). Cloning and molecular characterization of a glycerol-3-phosphate Oacyltransferase (GPAT) gene from Echium (Boraginaceae) involved in the biosynthesis of cutin polyesters. Planta (in press).
  8. Yang W, Pollard M, Li-Beisson Y, Beisson F, Feig M, Ohlrogge J (2010) A distinct type of glycerol-3-phosphate acyltransferase with sn-2 preference and phosphatase activity producing 2-monoacylglycerol. Proc Natl Acad Sci USA 107:12040
  9. Stork J, HarrisD, WilliamsB, Griffiths J, HaughnG, BeissonF, Li-Beisson Y, MenduV, DeBolt S (2010) CELLULOSE SYNTHASE9 serves a non-redundant role in secondary cell wall synthesis in the radial wall of Arabidopsis epidermal testa cells. Plant Physiology 153:580
  10. Li-Beisson Y, Pollard M, Sauveplane V, Pinot F, Ohlrogge J and Beisson F (2009), Nanoridges that characterize the surface morphology of flowers require the synthesis of cutin polyester. Proc Natl Acad Sci USA, 106:22008
  11. Molina I, Li-Beisson Y, Beisson F, Ohlrogge J and Pollard M (2009) Identification of an Arabidopsis feruloyl-CoA transferase required for suberin synthesis. Plant Physiol 151:1317
  12. DeBolt S, Scheible W, Schrick K, Auer M, Beisson F, Bischoff V, Bouvier-Navé P, Carroll A, Hematy K, Li Y, Milne J, Nair M, Schaller H, Zemla M and Somerville C (2009) Mutations in UDP-glucose:sterol-glucosyltransferase in Arabidopsis cause transparent testa phenotype and suberization defect in seeds. Plant Physiol 151:78
  13. Li Y* and Beisson F (2009). The biosynthesis of cutin and suberin as an alternative source of enzymes for the production of bio-based chemicals and materials. Biochimie 91: 685 (*corresponding author). (review)
  14. Pollard M, Beisson F, Li Y and Ohlrogge J (2008) Building lipid barriers: biosynthesis of cutin and suberin. Trends in Plant Sciences 13:236. (review)
  15. Li Y, Beisson F, Koo A, Molina I, Pollard M and Ohlrogge J (2007) Identification of acyltransferases required for cutin biosynthesis and production of cutin with suberin-like monomers. Proc Natl Acad Sci USA 104:18339
  16. Li Y, Beisson F, Ohlrogge J and Pollard M (2007) Monoacylglycerols are components of root waxes and can be produced in the aerial cuticle by ectopic expression of a suberin-associated acyltransferase. Plant Physiol 144:1267
  17. Beisson F*, Li Y*, Bonaventure G, Pollard M and Ohlrogge J (2007) The acyltransferase GPAT5 is required for synthesis of suberin in seed coat and root of Arabidopsis. Plant Cell 19:1 (*co-first authors)
  18. Li Y, Beisson F, Pollard M and Ohlrogge J (2006) Oil content of Arabidopsis seeds: the influence of seed anatomy, light and plant-to-plant variation. Phytochemistry 67:904
  19. Li Y, Adams IP, Wynn JP and Ratledge C (2005) Cloning and characterisation of a gene encoding a malic enzyme involved in anaerobic growth in Mc circinelloides. Mycological Research 109:461
  20. Li Y, Challen M, Elliott T and Casselton L (2004) Molecular analysis of breeding behaviour in Agaricus species. Mushroom Science 16:103
  21. Song Y, Wynn JP, Li Y, Granham D and Ratledge C (2001) A pre-genetic study of the isoforms of malic enzyme associated with lipid accumulation in Mucor circinelloides. Microbiology 147:1507
  22. Wynn JP, Hamid AA, Li Y and Ratledge C (2001) Biochemical events leading to the diversion of carbon into storage lipids in the oleaginous fungi Mucor circinelloides and Mortierella alpine. Microbiology 147:2857
   
PATENTS
  1. Ohlrogge J, Beisson F, Li Y, Pollard M (Jan 15 2007). Engineered plant extracellular lipids using acyltransferases and fatty acid omega-oxidases ( PCT/US2008/067887).
  2. Li Y, Beisson F, Pollard M and Ohlrogge J (Jun 22 2006). Acyltransferases for altering lipid production on plants ( PCT/US2007/014690).
  3. Ohlrogge J, Ruuska S, Li Y (March 29 2011). F-Box protein targeted plant oil production. United States Patent 7,915,480 ( PCT/US2006/037111).
   
ORAL PRESENTATIONS in international meetings
  • July 2010 Polyester Biosynthesis as a Source of Fatty Acid Hydroxylases and Acyltransferases with New Substrate Specificities. 19th International Symposium on Plant Lipids (ISPL) Carines, Australia (invited speaker)
  • Feb. 2009 Biosynthesis and function of plant cuticular polyesters. Gordon Conference (2009), USA (invited speaker)
  • July 2008 A member of an orphan family of cytochrome P450 monooxygenases is required for the synthesis of hydroxy fatty acids in plants. 5th Lipidomics Meeting (GERLI), France
  • June 2005 Characterization of an acyltransferase mutant of Arabidopsis with altered seed coat lipid metabolism. National Plant Lipid Cooperative Meeting, USA (invited speaker)
  • July 2001 Initiation of lipid biosynthesis in oleaginous fungi. “New Concepts in Lipid Research” national meeting of SCI/RSC Lipid Group, London, UK

Figure 1: Chlamydomonas reinhardtii as a model for studying biofuel production.

Figure 2: An example of a triacylglycerol molecule.

Figure 3: Oil accumulation processes in response to nitrogen starvation. Top panel: Nile red stained cells; bottom panel shows the loss of chlorophyll from the cultures of Chlamydomonas reinhardtii in response to nitrogen depletion with time.

Figure 4: Tentative structure of oil bodies of Chlamydomonas reinhardtii and mapping of major oil-body associated proteins to major reactions of lipid synthetic pathways.

Figure 5: Generation of mutant banks of Chlamydomonas reinhardtii for genetic screens.