Volume 4, Issue 3 (Suppl)

Adv Crop Sci Tech

ISSN: 2329-8863 ACST, an open access journal

Page 31

Notes:

Plant Genomics 2016

July 14-15, 2016

conferenceseries

.com

July 14-15, 2016 Brisbane, Australia

4

th

International Conference on

Plant Genomics

The

rpg4

/

Rpg5

integrated decoy resistance to wheat stem rust race

TTKSK

in barley: Towards

effector identification

Robert Saxon Brueggeman

1

, Roshan Sharma Poudel

1

, Shyam Solanki

1

, Shiaoman Chao

2

and

Jonathan Richards

1

1

North Dakota State University, USA

2

United States Department of Agriculture-Agricultural Research Service, USA

T

he barley

rpg4

/

Rpg5

locus confers resistance against wheat stem rust caused by

Puccinia graminis

f. sp.

tritici

(

Pgt

) including

race

TTKSK

(A.K.A.

Ug99

)

.

The 70 kb region harbors two NLR R-genes,

Rpg5

and

HvRga1

that are required together for

resistance.

HvRga1

and

Rpg5

contain typical NLR resistance-protein structure; however,

Rpg5

has an additional C-terminal

serine threonine protein kinase (STPK) domain. The transcription factor,

HvVOZ1

was identified by yeast-two-hybrid of a

library constructed from RNA of the

rpg4

/

Rpg5+

line Q21861; 48 hours post inoculation, utilizing the Rpg5-STPK domain

as bait. We hypothesize that the Rpg5-STPK acts as an integrated decoy that HvVOZ1 binds to negatively regulate defense

activation or binds after activation as part of a signaling complex. The second NLR, HvRga1, may guard theHvVOZ1-Rpg5

interaction or surveil the

Rpg5

-STPK domain for

Pgtrpg4

/

Rpg5

-Avr (

r45-Avr

) effector manipulation. Thus,

HvRga1

is possibly

the guard that detects manipulation of the

Rpg5

STPK or possibly HvVOZ1 by the

r45-Avr

effector eliciting a strong effector

triggered immunity defense response. The

r45-Avr

needs to be identified to thoroughly investigate these mechanisms and test

our hypothesis. To accomplish this a panel of 37 wheat stem rust isolates collected in North Dakota, many with differential race

typing on the wheat differentials and differential reactions on

rpg4/Rpg5

and

Rpg1

in barley were genotyped using restriction

site associated DNA-genotyping-by-sequencing (RAD-GBS). This RAD-GBS produced 4,919 informative SNPs and this initial

genotyping was used to select 24 diverse isolates (16

avrRpg4/rpg5

and 8

Avrrpg4/Rpg5

+) that were used to conduct in planta

RNA-seq analysis during

Pgt

colonization 5 days post inoculation on the susceptible barley cultivar Harrington. The RNA-seq

data was utilized to identify ~181,000 variant calls (SNPs and indels) within these

Puccinia graminis

transcriptomes during

the infection process. The robust genotyping and phenotyping on these diverse differential isolates should allow us to identify

candidate

r45-Avr

genes utilizing association mapping.

Biography

Robert Saxon Brueggeman has completed his PhD in 2009 from Washington State University and Postdoctoral studies also from Washington State University

Department of Crop and Soil Science. He is currently an Associate Professor at North Dakota State University as the Barley Pathologist/Molecular Geneticist.

He has published more than 32 papers in reputed journals covering the topics of the cloning and characterization of barley disease resistance genes and fungal

effectors.

Robert.Brueggeman@ndsu.edu

Robert Saxon Brueggeman et al., Adv Crop Sci Tech 2016, 4:3 (Suppl)

http://dx.doi.org/10.4172/2329-8863.C1.002