Research InterestsPlants produce a huge
variety of metabolites with very diverse structures and functions. Comparatively
few of these compounds are required for growth and development of the plant,
while others, a large group called secondary metabolites, have no direct benefit
to the plant but play a role in the interaction of the plant with its
environment. The secondary metabolites vary strongly among plant taxa, providing
each plant species with a diverse and probably unique blend of compounds. It is
the goal of my research to understand how the diversity of natural metabolites
has evolved and how these compounds have been recruited for their ecological
functions. In particular, I would like to answer the following questions:
·
How has the high
diversity of secondary products arisen in the course of evolution and how were
these compounds recruited for plant defense or plant-insect
signaling?
· How do natural plant
populations acquire and sustain several stable chemotypes that differ in their
terpene compositions and defense mechanisms?
· How do plants detect
biotic and abiotic stress and respond with the biosynthesis of specific
compounds?
The studies in my group are
focused on terpenes which form the largest group of plant products with 30,000
different structures. Many of these terpenes have an essential role in plants,
including hormones (gibberellins and
abscisic acid), membrane
components (sterols), participating in electron transfer (ubiquinone and
plastoquinone) and pigments (carotenoids). Other terpenes are apparently not
vital for plant growth or development but form oils and resins that are part of
the defense against other organisms. More recent is the discovery of volatile
terpenes that act as signals influencing the behaviour of insects and other
organisms. However, the functional role of most terpenes still needs to be
determined.
a) The evolution of terpene diversity in
maize and related grasses
Figure 1: The
sesquiterpene hydrocarbons of a maize seedling can be divided in three
differentially regulated groups of which group A is induced by herbivory, B is
ubiquitous and C is only found in the roots. The compounds are: 1: unknown, 2:
α-copaene, 3: (E)-β-caryophyllene, 4: (E)-α-bergamotene, 5:
sesquisabinene A, 6: (E)-β-farnesene, 7: unknown, 8: germacrene D, 9:
zingiberene, 10: α-muurolene, 11: unknown, 12: β-bisabolene, 13: δ-cadinene, 14:
β-sesquiphellandrene.
The enzyme class responsible
for most of the diversification are the terpene synthases which are encoded in
large gene families. The comparison of terpene synthase structure-function
relationships is therefore an excellent tool to study evolutionary processes. We
identified the terpene synthase gene family from maize and characterized their
activity by heterologous
expression, gas chromatography with isotopic tracers, mass spectrometry and
nuclear magnetic resonance (Figure 2 A). Most terpene synthases are multiproduct
enzymes producing mixtures of up to forty different terpene compounds. Mapping
and phylogenetic analysis of the maize terpene synthase family indicates a
common origin and several sub-families. We could demonstrate that two of the
terpene synthase genes are the result of a tandem duplication event about three
million years ago. Subsequently, four nucleotides mutated between the two genes
and thereby the enzymatic activity was altered (Figure 2 B, C).
The unique catalytic mechanism of
terpene synthases enables these enzymes to form multiple products. To elucidate
the reaction mechanism, we study structure-function relationships within the
active site of the enzyme. Comparisons of closely related enzymes and directed
alterations of single amino acids by in vitro mutagenesis helped us to
identify structures responsible for the formation of multiple products (Figure
3). We identified several amino acids in the active center of the enzyme that
determine product specificity and identified two catalytic pockets that appear
to catalyze partial steps of the reaction. The goal of this study is to
understand these fascinating reaction mechanisms and to engineer terpene
synthases with a specific terpene spectrum. Furthermore, the phylogenetic
analysis of structure function-relationships within maize and closely related
grasses will indicate which evolutionary processes have shaped this gene family
and yield to an understanding of its function.
b) Discovering the roles of terpenes in plant defense
Plants do not only accumulate
terpenes for herbivore defense, but also emit complex volatile blends in
response to herbivory, fungal attack and many other biotic and abiotic stresses.
These terpene-containing volatiles attract natural enemies of the attacking
herbivores but due to the complexity of these volatile blends, it is difficult
to attribute a specific function to a specific terpene.
We were able to show that
maize roots damaged by the maize pest Diabrotica virgifera emit the
sesquiterpene (E)-β-caryophyllene which attracts entomopathogenic
nematodes. These nematodes attack the larvae of D. virgifera and thereby
benefit the maize plant (Figure 4A). Above ground, the herbivory by lepidopteran
larvae induces a mixture of volatiles that is highly attractive to females of
various parasitic wasps (Figure 4B). We identify the terpene synthases that
produce the herbivore-induced terpenes (Figure 1) and utilize mutants,
transgenic plants and transposon insertion lines to study the importance of
these terpene signals for plant defense. The impact of these defenses on plant
fitness and its natural environment can be tested in field experiments. Plants
that have an increased defense capability may have promise for agricultural use.
Figure 4:
The role of terpenes as signals in plant defense. A: Volatile terpenes
released form the leaves of a maize plant after attack of a lepidopteran larvae
attract parasitic wasps that are natural enemies of the lepidopteran larvae.
B: Feeding of Diabrotica virgifera on maize roots (not shown) attracts entomopathogenic nematodes that attack the larvae of D. virgifera. Photos
by Ted Turlings.
From: Rasman et al., (2005) Nature 434: 732-737).
c) Regulation of plant natural
product biosynthesis
Detailed studies have demonstrated
how fungal elicitors trigger specific plant defense responses, but little is
known how herbivores can trigger the direct and indirect defenses of the plant.
The family of terpene synthases is well suited to study the last steps of the
complex herbivore-induced signal transduction cascades (Figure 5). The
comparison of promoter sequences will allow the identification of elements
involved in herbivory-mediated gene expression and the characterization of
trans-binding factors that interact with these elements. Our feeding
experiments with potential intermediates of the signaling cascade have already
demonstrated the existence of several parallel signaling pathways with different
kinetics. Microarray data, differential displays of gene activity and proteomic
analysis of herbivore-induced maize plants will represent the alterations in
gene expression that are part of plant signaling.
Figure 5:
Terpene synthase expression is regulated by herbivory. RNA hybridization assays
show that the transcript levels of the terpene synthases tps1 and tps2
are elevated after herbivory. However, the induction of the two genes follows
different kinetics. The lowest panel shows the 18S rRNA as loading control.
From: Schnee et al., (2002) Plant Physiology 130, 2049-2060.
d) The formation of Chemotypes in Thymus
and
Origanum
Terpene composition often shows substantial
qualitative and quantitative differences within a single species. Natural
populations of the Lamiaceae thyme and oregano consist of several chemotypes
that are defined by their terpene content. The chemotypes differ in their
resistance to particular herbivores and appear to be localized in the
environments with the herbivore communities that they are best defended against.
The goal of this study is to understand the evolution of chemotypes and the
genetic mechanisms that maintain the distinct chemotypes in mixed populations
Classical genetic studies on thymus
demonstrated an epistatic series of six loci that define each of the chemotypes.
We extend these studies towards the molecular genetics and biochemistry of
chemotype formation with the aim to characterize terpene biosynthesis and the
mechanisms that regulate chemotype formation.
 
1984 - 1990 Studies
of Biology at Ruhr-Universität
Bochum, Germany. Masters thesis on 'Developmental expression pattern of
chloroplast and nuclear genes in Arabidopsis thaliana‘
1991 - 1995 PhD thesis at University of
California at Los Angeles
‘Regulation of nuclear genes by the phytochrome system: Studies on the promoters
of the rbcS and Lhcb genes in Lemna gibba L.‘
1993 - 1994 Fellowship by German
Academic Exchange Service (DAAD)
1995 Doctoral defense to
obtain Ph.D. degree in
Biology at University of Bochum
1995 - 1999 Postdoctoral
Fellow at Cornell University und Boyce
Thompson Institute
1999 - 2008 Research group leader at
Max Planck Institute for Chemical Ecology
2001 - 2003 Habilitationsstipendium
Claussen-Simon Stiftung
2007 Habilitation for the
field Botany at Friedrich-Schiller-Universität Jena
April 2008 Professor for
Pharmaceutical Biotechnology (W3) at Martin-Luther-Universität Halle-Wittenberg
Scientific
Grants
2004-2008 Priority Programme SPP
1152 “Evolution of Metabolic Diversity“ of the German Science Foundation (DFG).
2002-2006 Grant by European Union
within Framework 5 "Quality of Life and Management of Living Resources":
I
2001-2004 Grant of the German
Department of Education and Research (BMBF) on Safety and Monitoring of
Genetically Modified Plants.
Recent Publications
| 2009 |
| 1 |
Chen F; Al-Ahmad H; Joyce B; Zhao N; Köllner TG; Degenhardt J; Stewart Jr C (2009): Within-plant distribution and emission of sesquiterpenes from Copaifera officinalis. Plant Physiology and Biochemistry, online first [no reprint] |
| 2 |
Degenhardt J; Hiltpold I; Köllner TG; Frey M; Gierl A; Gershenzon J; Hibbard BE; Ellersieck MR; Turlings TCJ (2009): Restoring a maize root signal that attracts insect-killing nematodes to control a major pest. Proceedings of the National Academy of Sciences USA 106, 13213-13218 [GER267 GER267s1 GER267s2] pdf pdf pdf |
| 3 |
Köllner TG; Gershenzon J; Degenhardt J (2009): Molecular and biochemical evolution of maize terpene synthase 10, an enzyme of indirect defense. Phytochemistry 70, 1139-1145 [GER275] pdf |
| 4 |
Pandit SS; Kulkarni R; Chidley H; Giri A; Pujari KH; Köllner TG; Degenhardt J; Gershenzon J; Gupta VS (2009): Changes in volatile composition during fruit development and ripening of 'Alphonso' mango. Journal of the Science of Food and Agriculture 89, 2071-2081 [no reprint] |
| 2008 |
| 1 |
Erb M; Ton J; Degenhardt J; Turlings TCJ (2008): Interactions between arthropod-induced aboveground and belowground defenses in plants. Plant Physiology 146, 867-874 [GER239] pdf |
| 2 |
Köllner TG; Schnee C; Li SH; Svatoš A; Schneider B; Gershenzon J; Degenhardt J (2008): Protonation of a neutral (S)-beta-bisabolene intermediate is involved in (S)-beta-macrocarpene formation by the maize sesquiterpene synthases TPS6 and TPS11. Journal of Biological Chemistry 283, 20779-20788 [GER245] pdf |
| 3 |
Köllner TG; Held M; Lenk C; Hiltpold I; Turlings TCJ; Gershenzon J; Degenhardt J (2008): A maize (E)-beta-caryophyllene synthase implicated in indirect defense responses against herbivores is not expressed in most American maize varieties. The Plant Cell 20, 482-494 [GER241 GER241s1] pdf pdf |
| 4 |
Lin C; Shen B; Xu Z; Köllner TG; Degenhardt J; Dooner HK (2008): Characterization of the monoterpene synthase gene tps26, the ortholog of a gene induced by insect herbivory in maize. Plant Physiology 146, 940-951 [GER240] pdf |
| 5 |
Yuan JS; Köllner TG; Wiggins G; Grant J; Degenhardt J; Chen F (2008): Molecular and genomic basis of volatile-mediated indirect defense against insects in rice. The Plant Journal 55, 491-503 [GER256] pdf |
| 6 |
Yuan JS; Köllner TG; Wiggins G; Grant J; Zhao N; Zhuang X; Degenhardt J; Chen F (2008): Elucidation of the genomic basis of indirect plant defense against insects. Plant Signaling & Behavior 3, 720-721 [no reprint] |
| 2007 |
| 1 |
Günnewich N; Page JE; Köllner TG; Degenhardt J; Kutchan TM (2007): Functional expression and characterization of trichome-specific (-)-limonene synthase and (+)-a-pinene synthase from Cannabis sativa. Natural Product Communications 2, 223-232 [GER219] pdf |
| 2 |
Kampranis SC; Ioannidis D; Purvis A; Mahrez W; Ninga E; Katerelos NA; Anssour S; Dunwell JM; Degenhardt J; Makris AM; Goodenough PW; Johnson C (2007): Rational Conversion of Substrate and Product Specificity in a Salvia Monoterpene Synthase: Structural Insights into the Evolution of Terpene Synthase Function. The Plant Cell 19, 1994-2005 [GER224] pdf |
| 2006 |
| 1 |
Köllner TG; O'Maille PE; Gatto N; Boland W; Gershenzon J; Degenhardt J (2006): Two pockets in the active site of maize sesquiterpene synthase TPS4 carry out sequential parts of the reaction scheme resulting in multiple products. Archives of Biochemistry & Biophysics 448, 83-92 [GER172] pdf |
| 2 |
Schnee C; Köllner TG; Held M; Turlings TCJ; Gershenzon J; Degenhardt J (2006): The products of a single maize sesquiterpene synthase form a volatile defense signal that attracts natural enemies of maize herbivores. Proceedings of the National Academy of Sciences USA 103, 1129-1134 [GER154] pdf |
| 2005 |
| 1 |
Rasmann S; Köllner TG; Degenhardt J; Hiltpold I; Toepfer S; Kuhlmann U; Gershenzon J; Turlings TCJ (2005): Recruitment of entomopathogenic nematodes by insect-damaged maize roots. Nature 434, 732-737 [GER202] pdf |
| 2004 |
| 1 |
Hoballah ME; Köllner TG; Degenhardt J; Turlings TCJ (2004): Costs of induced volatile production in maize. Oikos 105, 168-180 [GER084] pdf |
| 2 |
Köllner TG; Schnee C; Gershenzon J; Degenhardt J (2004): The variability of sesquiterpenes emitted from two Zea mays cultivars is controlled by allelic variation of two terpene synthase genes encoding stereoselective multiple product enzymes. The Plant Cell 16, 1115-1131 [GER090] pdf |
| 3 |
Köllner TG; Schnee C; Gershenzon J; Degenhardt J (2004): The sesquiterpene hydrocarbons of maize (Zea mays) form five groups with distinct developmental and organ-specific distributions. Phytochemistry 65, 1895-1902 [GER095] pdf |
| 2003 |
| 1 |
Degenhardt J; Gershenzon J (2003): Terpenoids. In: Brian T; Murphy DJ; Murray BG (Eds.): Encyclopedia of Applied Plant Sciences. Elsevier, Amsterdam. pp. 500-504 [GER068] pdf |
| 2 |
Degenhardt J; Gershenzon J (2003): Genetics of crop improvement: Genetic modification of secondary metabolism terpenoids. In: Thomas B; Murphy DJ; Murray BG (Eds.): Encyclopedia of Applied Plant Sciences. Elsevier Science, London. pp. 500-504 [GER152] pdf |
| 3 |
Degenhardt J; Gershenzon J; Baldwin IT; Kessler A (2003): Attracting friends to feast on foes: engineering terpene emission to make crop plants more attractive to herbivore enemies. Current Opinion in Biotechnology 14, 169-176 [GER050] pdf |
| 4 |
Köllner TG; Schnee C; Gershenzon J; Degenhardt J (2003): Terpene formation in maize and its ecological and evolutionary significance. Chemicke Listy 97, 319-327 [GER075] pdf |
| 2002 |
| 1 |
Schnee C; Köllner TG; Gershenzon J; Degenhardt J (2002): The maize gene terpene synthase 1 encodes a sesquiterpene synthase catalyzing the formation of (E)-beta-farnesene, (E)-nerolidol, and (E,E)-farnesol after herbivore damage. Plant Physiology 130, 2049-2060 [GER012] pdf |
| 2000 |
| 1 |
Degenhardt J; Gershenzon J (2000): Demonstration and characterization of (E)-nerolidol synthase from maize: a herbivore-inducible terpene synthase participating in (3E)-4,8-dimethyl-1,3,7-nonatriene biosynthesis. Planta 210, 815-822 [GER009] pdf |
| 1999 |
| 1 |
Degenhardt J; Gershenzon J (1999): A herbivore-inducible nerolidol synthase activity and its role in regulating homoterpene synthesis in maize. Plant Biology, 17 [FL] |
| 1998 |
| 1 |
Degenhardt J; Larsen PB; Howell SH; Kochian LV (1998): Aluminum resistance in the Arabidopsis mutant alr-104 is caused by an aluminum-induced increase in rhizosphere pH. Plant Physiology 117, 19-27 [GER028] pdf |
| 2 |
Larsen PB; Degenhardt J; Tai CY; Stenzler LM; Howell SH; Kochian LV (1998): Aluminum-resistant Arabidopsis mutants that exhibit altered patterns of aluminum accumulation and organic acid release from roots. Plant Physiology 117, 9-18 [GER029] pdf |
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