Contact Info

Primary Title: 
Director - Center for Genome Research & Biocomputing
Center for Genome Research and Biocomputing
Department of Botany and Plant Pathology
Email Contact: 
Voice Contact: 
(541) 737-3347
Office/Lab: ALS 3021/3137


Ph.D.,1981 University of Melbourne, Australia


Research Description: 
  • Systems biology of infectious disease
  • Comparative and functional genomics of oomycete plant pathogens
  • Molecular analysis of oomycete virulence proteins, especially effectors
  • Functional genomics of quantitative disease resistance and infection responses in plants
  • Computational prediction of gene functions
  • Mathematical modeling of complex cellular responses

Much of the Tyler group's research is focused on the systems biology of microbe-host interactions, with a focus on the interactions of oomycete pathogens with their hosts. This research spans molecular biology, structural and functional genomics, bioinformatics, data mining and mathematical modeling.

Molecular basis of virulence and microbe-host recognition

P. sojae avirulence genes, effectors and the RXLR-dEER motif

So-called avirulence genes in pathogens directly or indirectly encode molecules that are recognized by plant receptors encoded by major resistance genes (R genes). There are 13 major resistance (Rps) genes in soybean against P. sojae, and matching single dominant avirulence genes in P. sojae. We have cloned the avirulence gene Avr1b-1. Avr1b-1 encodes a small secreted protein and is specifically expressed during infection in P. sojae strains that are avirulent (cannot infect) soybean cultivars containing resistance gene Rps1b. In strains that can infect Rps1b cultivars, there are large numbers of amino acid substitutions encoded by the Avr1b-1 gene or else Avr1b-1 mRNA does not accumulate (Shan et al, 2004). P. sojae transformants containing Avr1b-1 not only gain avirulence to Rps1b, but also to Rps1k, indicating the Avr1b protein is recognized by both Rps1b and Rps1k gene products. Rps1k encodes an intracellular NBS-LRR resistance protein. Rps1b is an allele of Rps1k and so is presumed also to encode an NBS-LRR resistance protein.

Sequence comparisons between Avr1b-1 and three other cloned oomycete Avr genes (Avr3a from P. infestans, and ATR13 and ATR1 from Hyaloperonospora parasitica) reveal two conserved motifs in addition to the secretory leader at the N-terminus (Rehmany et al, 2005; Tyler et al, 2006).  The first is the RXLR motif occurring within 50 residues of the secretory leader. The second is a short adjacent region that is enriched in acidic residues termed the "dEER" domain. The RXLR domain is exciting because of its resemblance to a host-targeting signal that mediates translocation of secreted virulence proteins to the cytoplasm of host erythrocytes, across the host parasitiphorous vacuolar membrane, suggesting that this motif is responsible for transit of oomycete effectors in plant cells.

Bioinformatic screens of the P. sojae and P. ramorum genome sequences (see below) reveal approximately 350 genes in each species that have secretory leaders and RXLR+DEER motifs, called Avh (Avirulence homolog) or "RXLR" genes. Many of these have sequence similarity with Avr1b-1. The Hyaloperonospora parasitica genome contains about 150 RXLR genes and the P. infestans Expressed Sequence Tag (EST) set includes about 60 RXLR-containing unigenes. The P. sojae  and P. ramorum genes show extensive divergence between the two species; only 83 can be identified as putative orthologs by bi-directional BLAST analysis, and of these only 18 have syntenic locations. The rapid diversification of the RXLR gene family is driven presumably by selection pressure from the host defense machinery, implying that many if not all of the genes in the superfamily are involved in infection. 

This project has been supported by grants from the National Research Initiative of the USDA Cooperative State Research, Education and Extension Service, #2001-35319-14251, 2002-35600-12747 and 2004-35600-15055, and from the National Science Foundation, #MCB-0242131 and EF-0412213.

Genomics of host-pathogen interactions

Sequencing of oomycete genomes

The complete genome sequence of an organism is an excellent starting point for identifying genes involved in pathogenicity, or any other process of interest. The genome sequence can also aid substantially in developing genetic tools for detecting and tracking the pathogen. In collaboration with the DOE Joint Genome Institute (JGI), we have completed draft genome sequences of P. sojae and P. ramorum. The 95-Mb genome of P. sojae was sequenced to a depth of 9x while the 65-Mb genome of P. ramorum was sequenced to a depth of 7x, both by whole-genome shotgun sequencing. Recently, we have begun sequencing the 75-Mb genome of the Arabidopsis downy mildew pathogen Hyaloperonospora parasitica in collaboration with John McDowell (Virginia Tech), Jim Beynon (Warwick University, UK), Washington University Genome sequencing Center, and the Sanger Sequencing Center (UK).

We have completed the identification and annotation of genes in the genomes of P. sojae and P. ramorum (Tyler et al, 2006). Automated gene calling software identified 19 027 predicted genes (called gene models) in the genome of P. sojae and 15 743 gene models in the genome of P. ramorum. Of these gene models, 9768 are similar enough in sequence between P. sojae and P. ramorum that they are predicted to have the same function. These highly similar genes, sometimes called orthologs, are arranged in very similar orders along the chromosomes (i.e. exhibit synteny). Preliminary analysis of the H. parasitica genome sequence has revealed that gene order is also well conserved in that species compared to the two Phytophthora species. Despite the conservation of gene order, large segments of genome sequence in the P. sojae genome appear to be absent from P. ramorum, which partially accounts for the larger genome size of P. sojae.

Although 9768 genes appear to be orthologous between P. sojae and P. ramorum, a very large number (49% in P. sojae; 38% in P. ramorum) have diverged so much that they have no matching gene in the other species. Of these divergent genes, 1755 P. sojae genes are unique to that species and 624 appear unique to P. ramorum. The remainder of the genes represent gene families that are present in both species but whose members do not match one another precisely. Proteins that are secreted by the pathogen during infection, as well as being divergent between P. sojae and P. ramorum, are excellent candidates for proteins that function to promote the infection process.  A major finding from the genome sequencing was the discovery of a very large, very diverse superfamily of genes with similarity to the oomycete avirulence genes, as described above.

A further inference from the oomycete genome sequences is that oomycetes evolved from a photosynthetic ancestor, in common with photosynthetic members of the Stramenopile kingdom such as diatoms. Many examples of oomycete genes with close affinity to plant and algal genes were found.

The Phytophthora genome sequences can be found at,, and Blast searches of these sequences, and also the draft H. parasitica sequence, can be carried out at A community annotation tool is available at

In addition to these genome sequences, there are over 30,000 P. sojae ESTs, including 9,512 sequences from P. sojae-infected soybean tissue, and 75,757 ESTs from P. infestans. These are available at

These projects have been supported by grants from the National Research Initiative of the USDA Cooperative State Research, Education and Extension Service, #00-52100-9684, 2002-35600-12747 and 2004-35600-15055, and from the National Science Foundation, #MCB-0242131 and EF-0412213, and by funds from the DOE Joint Genome Institute and from VBI.

Gene ontology terms for plant-associated microbes

The Gene Ontology (GO; is a set of standardized terms for describing biological processes, molecular functions and cellular components of living organisms (The Gene Ontology Consortium, 2000). The use of these terms to annotate the roles of genes greatly aids in identifying similarities among organisms. In collaboration with Joao Setubal at VBI and researchers at Cornell University (Alan Collmer), the University of Wisconsin (Nicole Perna and Jeremy Glasner), Wells College (Candace Collmer), North Carolina State University (Ralph Dean and David Bird) and the Institute for Genome Research (Michelle Gwinn-Giglio and Owen White), we are developing new terms for annotating the contributions of genes to interactions between bacteria, fungi, oomycetes and nematodes and their hosts, to assist in identifying similarities among plant-associated microbes in general (more information is available at

This project is supported by grants from the National Research Initiative of the USDA Cooperative State Research, Education and Extension Service, #2005-35600-16370, and from the National Science Foundation, # EF-0523736.

Functional genomics of early infection in P. sojae

In order to identify the tool sets that Phytophthora sojae uses to overcome the defenses of its host soybean, it is necessary to identify genes and gene products specifically expressed during infection. This project is focused on the earliest steps of infection prior to penetration of the host tissue, and during the first 24 hours of infection when the success of the infection is primarily determined. The objectives of the project are:

1.  Use global gene expression profiles, assayed with Affymetrix GeneChips, to identify sets of genes specifically expressed during germination of cysts, growth on a solid substrate and formation of appressoria in the presence of root exudates.

2. Characterizing the proteome of cysts and appressoria using two-dimensional HPLC in conjunction with tandem mass spectrometry (MUDPit; Multidimensional Protein Identification Technology), in collaboration with Kurt Lamour (University of Tennessee, Knoxville) and Hayes McDonald at the Oak Ridge National Laboratory.

3. Search for potential master regulatory genes controlling pathogenicity in planta, by assaying the expression of genes predicted to encode transcription factors, signal transduction proteins and receptors, during the first hours following penetration of host tissue, using real time PCR (RT-PCR).

4. Collaborator KurtLamour (University of Tennessee, Knoxville) will directly test the function of potential master regulatory genes using TILLing technology.

5. As part of this project, we are also exploring the potential for using Laser Microdissection to isolate RNA directly pathogen infection structures.

This project is supported by a grant from the National Research Initiative of the USDA Cooperative State Research, Education and Extension Service, #2005-35604-15525.

Dissection of quantitative resistance in soybean against P. sojae using functional genomics

Much has been learnt over the last decade regarding the mechanism by which plants are protected from disease by major resistance genes, also called vertical resistance. Much less is known about mechanisms of quantitative resistance, also known as horizontal or partial resistance, which protects a plant species against all genetic forms of a pathogen, albeit not completely. This project combines Quantitative Trait Loci (QTL) analysis with global expression assays to dissect the mechanisms of quantitative resistance in soybean against the oomycete pathogen Phytophthora sojae. Gene expression profiles of both the host and the pathogen are being examined during infection of soybean cultivars varying in quantitative resistance, and in a large population of soybean progeny (300) segregating for quantitative resistance. The transcriptional profiles are being measured using an Affymetrix GeneChip that contains probes for 38 000 soybean genes and 15 800 P. sojae genes. The information obtained from this study will be valuable for understanding how legumes may be protected from a wide variety of pathogens, and how many hosts may be protected against oomycete pathogens. This project is a multidisciplinary collaboration involving Saghai Maroof (Virginia Tech), Ina Hoeschele (VBI), Anne Dorrance (Ohio State) and Steve St. Martin (Ohio State).

We have completed an analysis of the transcriptional profiles of eight cultivars with varying levels of quantitative resistance. Infected roots were assayed 3 and 5 days after inoculation with P. sojae and compared to mock inoculated roots. The major findings of this analysis were:

1. A very high proportion of soybean genes detectable by the arrays (>80%) showed significant changes in expression following pathogen inoculation.

2. Each of the four most resistant cultivars showed expression changes that were unique to that cultivar, suggesting that each cultivar had some unique mechanisms of resistance.

3. A set of genes could be identified that showed expression changes common to all four resistant cultivars, suggesting some common mechanisms of resistance.

The identification of potentially different mechanisms of resistance in the four resistant cultivars was supported by the finding that cultivars Conrad and V71-370 contained QTLs for resistance that mapped to different loci.  These observations suggest strategies for improving quantitative resistance by hybridizing different resistant cultivars. More information on this project can be found at

This project is supported by cooperative agreement DBI-0211863 from the National Science Foundation Plant Genome Research Program.

Cross-kingdom comparative functional genomics: a mathematical approach

Much of what we know about molecular biology has been derived from intensive study of a small number of model organisms, such as E. coli, yeast, Arabidopsis, Drosophila, the nematode Caenorhabditis, and mouse, as well as man. This information has been very useful in studying the molecular biology of species closely related to these model organisms. However an increasing number of genomics studies are focused on organisms such as oomycetes and the malaria parasite Plasmodium, that belong to kingdoms of life very different than those of these model organisms. Therefore, even with the genome sequences of these diverse organisms in hand, identifying the functions of the genes encoded in the genomes is very difficult.

The aim of this project is to develop novel computational approaches for comparing gene functions of organisms from different kingdoms. Thus far the project has focused on a comparison of the oxidative stress response of organisms from three different kingdoms, yeast (fungi), Arabidopsis (plants), Phytophthora sojae (oomycetes), using transcriptional and metabolic profiling. Mathematical modeling is being used to represent the responses of each species in a way that facilitates sequence-independent comparison. This project is being carried out in collaboration with VBI faculty Vladimir Shulaev, Pedro Mendes and Reinhard Laubenbacher.

Research Group Members

  • Felipe Arredondo
  • Julio Vega-Arreguin
  • Qunqing Wang
  • Hua Wise
  • Sucheta Tripathy
  • Trudy Torto-Alalibo
  • Yufeng Fang
  • Danielle Choi
  • Wenwu Ye

Graduate Students

  • Kai Tao (MCB PhD expected 2016)

Related Links

Oomycete Molecular Genetics Research Collaboration Network

Plant-Associated Microbe Gene Ontology


Dong S Yin W. Kong G. Yang X. Gutob D. Chen Q. Kale S.D. Sui Y. Zhang Z. Dou D. Zheng X Gijzen M. Tyler B.M. Wang Y. Phytophthora sojae avirulence effector Avr3b is a secreted NADH and ADP-ribose pyrophosphorylase that modulates plant immunity". PLoS Pathogens. 2011;7(11):e1002353. 

Dong S, Yu D, Cui L, et al. Sequence variants of the Phytophthora sojae RXLR effector Avr3a/5 are differentially recognized by Rps3a and Rps5 in soybean. PLoS One. 2011;6:e20172.

Falin LJ, Tyler BM. Using interpolation to estimate system uncertainty in gene expression experiments. PLoS One. 2011;6:e22071.

Gu B Kale S.D. Wang Q. Pan Q. Cao H. Meng Y. Kang Z. Tyler B.M. Shan W. The secreted protein Ps87 of Puccinia striiformis is conserved in diverse fungal pathogens and contains an RXLR-like motif sufficient for translocation into plant cells. PLoS One. 2011;6(11):e27217.  

Kale SD, Tyler BM. Assaying effector function in planta using double-barreled particle bombardment. Methods Mol Biol. 2011;712:153–172.

Kale SD, Tyler BM. Entry of oomycete and fungal effectors into plant and animal host cells. Cell Microbiol. 2011.

Plett JM, Kemppainen M, Kale SD, et al. A secreted effector protein of Laccaria bicolor is required for symbiosis development. Curr Biol. 2011;21:1197–1203.

Rouxel T, Grandaubert J, Hane JK, et al. Effector diversification within compartments of the Leptosphaeria maculans genome affected by Repeat-Induced Point mutations. Nat Commun. 2011;2:202.

Wang Q, Han C, Ferreira AO, et al. Transcriptional programming and functional interactions within the Phytophthora sojae RXLR effector repertoire. Plant Cell. 2011;23:2064–2086.

 Dou D, Kale SD, Liu T, et al. Different domains of Phytophthora sojae effector Avr4/6 are recognized by soybean resistance genes Rps4 and Rps6. Mol Plant Microbe Interact. 2010;23:425–435.

Kale SD, Gu B, Capelluto DG, et al. External lipid PI3P mediates entry of eukaryotic pathogen effectors into plant and animal host cells. Cell. 2010;142:284–295.

Levesque CA, Brouwer H, Cano L, et al. Genome sequence of the necrotrophic plant pathogen Pythium ultimum reveals original pathogenicity mechanisms and effector repertoire. Genome Biol. 2010;11:R73.

Torto-Alalibo T, Collmer CW, Gwinn-Giglio M, et al. Unifying themes in microbial associations with animal and plant hosts described using the Gene Ontology. Microbiol. Molec. Biol. Rev.. 2010;74:in press.  

Tucker DM, Maroof MAS, Mideros S, et al. Mapping Quantitative Trait Loci for Partial Resistance to Phytophthora sojae in a Soybean Interspecific Cross. Crop Science. 2010;50:628–635.  

Tyler BM. Towards a systems-level understanding of oomycete-plant interactions. Minneapolis: American Phytopathological Society; 2010. Proceedings of the 10th US-Japan seminar: Genome-Enabled Integration of Research in Plant Pathogen S.  

Wang H-H, Waller L, Tripathy S, et al. Discovery of genes underlying soybean QTL conferring partial resistance to Phytophthora sojae. Plant Genome. 2010;3:14–22.  

 Chibucos MC, Collmer CW, Torto-Alalibo T, et al. Programmed cell death in host-symbiont associations, viewed through the Gene Ontology. BMC Microbiol. 2009;9 Suppl 1:S5.

Chibucos MC, Tyler BM. Common themes in nutrient acquisition by plant symbiotic microbes, described by the Gene Ontology. BMC Microbiol. 2009;9 Suppl 1:S6.

Dong S, Qutob D, Tedman-Jones J, et al. The Phytophthora sojae avirulence locus Avr3c encodes a multi-copy RXLR effector with sequence polymorphisms among pathogen strains. PLoS One. 2009;4:e5556.

Kale SD, Tyler BM. Assaying effector function in planta using double-barreled particle bombardment. In: McDowell JM, ed. Methods in Molecular Biology. The Plant Immune Response. Totowa, NJ: Humana; 2009:in press.  

Meng S, Torto-Alalibo T, Chibucos MC, Tyler BM, Dean RA. Common processes in pathogenesis by fungal and oomycete plant pathogens, described with Gene Ontology terms. BMC Microbiol. 2009;9 Suppl 1:S7.

Qutob D, Tedman-Jones J, Dong S, et al. Copy number variation and transcriptional polymorphisms of Phytophthora sojae RXLR effector genes Avr1a and Avr3a. PLoS One. 2009;4:e5066.

Torto-Alalibo T, Collmer CW, Lindeberg M, Bird D, Collmer A, Tyler BM. Common and contrasting themes in host cell-targeted effectors from bacterial, fungal, oomycete and nematode plant symbionts described using the Gene Ontology. BMC Microbiol. 2009;9 Suppl 1:S3.

Tseng TT, Tyler BM, Setubal JC. Protein secretion systems in bacterial-host associations, and their description in the Gene Ontology. BMC Microbiol. 2009;9 Suppl 1:S2.

Tyler BM. Viewing the microbial world through the lens of the Gene Ontology. Trends Microbiol. 2009;17:259–261.

Tyler BM. Entering and breaking: virulence effector proteins of oomycete plant pathogens. Cell Microbiol. 2009;11:13–20.

Tyler BM. Ch. 18 Effectors. In: Lamour K, Kamoun S, eds. Oomycete Genetics and Genomics: Diversity, Interactions and Research Tools. Hoboken, New Jersey: Wiley-Blackwell; 2009:361–385.  

Tyler BM, Sanchez C(eds). Special issue: Gene Ontology for Microbiologists. Trends Microbiol.. 2009;17:259–336.  

Zhou L, Mideros SX, Bao L, et al. Infection and genotype remodel the entire soybean transcriptome. BMC Genomics. 2009;10:49.

 Dou D, Kale SD, Wang X, et al. Conserved C-terminal motifs required for avirulence and suppression of cell death by Phytophthora sojae effector Avr1b. Plant Cell. 2008;20:1118–1133.

Dou D, Kale SD, Wang X, et al. RXLR-mediated entry of Phytophthora sojae effector Avr1b into soybean cells does not require pathogen-encoded machinery. Plant Cell. 2008;20:1930–1947.

Jiang RH, Tripathy S, Govers F, Tyler BM. RXLR effector reservoir in two Phytophthora species is dominated by a single rapidly evolving superfamily with more than 700 members. Proc Natl Acad Sci U S A. 2008;105:4874–4879.

Tyler BM. Genomics of Fungal- and Oomycete-Soybean Interactions. In: Stacey G, ed. Soybean Genomics. New York: Springer; 2008:243–267.  

Tyler BM, Dou D, Kale SD, et al. The effector repertoire of Phytophthora sojae: structure, function and evolution. In: Lorito M, Woo S, Scala F, eds. Biology of Molecular Plant-Microbe Interactions. Vol. 6. St. Paul, Minnesota: International Society for Molecular Plant-Microbe Interactions; 2008.  

Tyler BM, Jiang RHY, Zhou L, et al. Functional genomics and bioinformatics of the Phytophthora sojae-soybean interaction. In: Gustafson P, Stacey G, Taylor J, eds. The Genomics of Disease. New York: Kluwer Academic/Plenum Publisher; 2008:67–78.  

 Martin FN, Bensasson D, Tyler BM, Boore JL. Mitochondrial genome sequences and comparative genomics of Phytophthora ramorum and P. sojae. Curr Genet. 2007;51:285–296.

Torto-Alalibo TA, Tripathy S, Smith BM, et al. Expressed sequence tags from phytophthora sojae reveal genes specific to development and infection. Mol Plant Microbe Interact. 2007;20:781–793.

Tyler BM. Phytophthora sojae: root rot pathogen of soybean and model oomycete. Mol Plant Pathol. 2007;8:1–8.

 Jiang RH, Tyler BM, Govers F. Comparative analysis of Phytophthora genes encoding secreted proteins reveals conserved synteny and lineage-specific gene duplications and deletions. Mol Plant Microbe Interact. 2006;19:1311–1321.

Jiang RH, Tyler BM, Whisson SC, Hardham AR, Govers F. Ancient origin of elicitin gene clusters in Phytophthora genomes. Mol Biol Evol. 2006;23:338–351.

Krampis K, Tyler BM, Boore JL. Extensive variation in nuclear mitochondrial DNA content between the genomes of Phytophthora sojae and Phytophthora ramorum. Mol Plant Microbe Interact. 2006;19:1329–1336.

Tripathy S, Pandey VN, Fang B, Salas F, Tyler BM. VMD: a community annotation database for oomycetes and microbial genomes. Nucleic Acids Res. 2006;34:D379–81.

Tripathy S, Tyler BM. The repertoire of transfer RNA genes is tuned to codon usage bias in the genomes of Phytophthora sojae and Phytophthora ramorum. Mol Plant Microbe Interact. 2006;19:1322–1328.

Tyler BM. Genomics of Fungal Plant Pathogens. Encyclopedia of Plant and Crop Science. 2006:1–5.

Tyler BM, Tripathy S, Zhang X, et al. Phytophthora genome sequences uncover evolutionary origins and mechanisms of pathogenesis. Science. 2006;313:1261–1266.

Valer K, Fliegmann J, Frohlich A, Tyler BM, Ebel J. Spatial and temporal expression patterns of Avr1b-1 and defense-related genes in soybean plants upon infection with Phytophthora sojae. FEMS Microbiol Lett. 2006;265:60–68.

Zhang X, Scheuring C, Tripathy S, et al. An integrated BAC and genome sequence physical map of Phytophthora sojae. Mol Plant Microbe Interact. 2006;19:1302–1310.

 Rehmany AP, Gordon A, Rose LE, et al. Differential recognition of highly divergent downy mildew avirulence gene alleles by RPP1 resistance genes from two Arabidopsis lines. Plant Cell. 2005;17:1839–1850.

 Shan W, Cao M, Leung D, Tyler BM. The Avr1b locus of Phytophthora sojae encodes an elicitor and a regulator required for avirulence on soybean plants carrying resistance gene Rps1b. Mol Plant Microbe Interact. 2004;17:394–403.

Waugh ME, Tyler BM, Mitchell T, et al. The Phytophthora Genome Consortium Database.; 2004. NAR Molecular Biology Database Collection entry number 98.

 Hirsch AM, Bauer WD, Bird DM, Cullimore J, Tyler B, Yoder JI. Molecular Signals and Receptors: Controlling Rhizosphere Interactions between Plants and Other Organisms. Ecology. 2003;84:858–868.

 MacGregor T, Bhattacharyya M, Tyler BM, Bhat R, Schmitthenner AF, Gijzen M. Genetic and physical mapping of Avr1a in Phytophthora sojae. Genetics. 2002:949. 

Tyler BM. Molecular basis of recognition between phytophthora pathogens and their hosts. Annu Rev Phytopathol. 2002;40:137–167.

 Chamnanpunt J, Shan WX, Tyler BM. High frequency mitotic gene conversion in genetic hybrids of the oomycete Phytophthora sojae. Proc Natl Acad Sci U S A. 2001;98:14530–14535.

Tyler BM. Genetics and genomics of the oomycete-host interface. Trends Genet. 2001;17:611–614.

 de la Serna I, Cujec TP, Shi Y, Tyler BM. Non-coordinate regulation of 5S rRNA genes and the gene encoding the 5S rRNA-binding ribosomal protein homolog in Neurospora crassa. Mol Gen Genet. 2000;263:987–994.