This document describes a study assessing resistance induction in pine seedlings against pine wilt disease. Pine seedlings of P. pinaster and P. pinea were inoculated with a non-virulent nematode strain (C14-5). After 30 days, the seedlings were re-inoculated with virulent strains. P. pinaster seedlings showed needle necrosis after virulent inoculation, while P. pinea remained unaffected, suggesting greater susceptibility in P. pinaster. Gene expression analysis found similar expression profiles in P. pinaster vaccinated with C14-5 and later exposed to virulent strains, as in P. pinea under the same conditions, indicating vaccination may have induced resistance in P.
Dr. Yao-Wei Huang - Here we go again? Emergence of a novel swine enteric alph...John Blue
Here we go again? Emergence of a novel swine enteric alphacoronavirus (SeACov) in Southern China - Dr. Yao-Wei Huang, Zhejiang University, from the 2017 North American PRRS/National Swine Improvement Federation Joint Meeting, December 1‐3, 2017, Chicago, Illinois, USA.
More presentations at http://www.swinecast.com/2017-north-american-prrs-nsif-joint-meeting
Presented by Etienne de Villiers at the African Swine Fever Diagnostics, Surveillance, Epidemiology and Control Workshop, Nairobi, Kenya, 20-21 July 2011
Dr. Yao-Wei Huang - Here we go again? Emergence of a novel swine enteric alph...John Blue
Here we go again? Emergence of a novel swine enteric alphacoronavirus (SeACov) in Southern China - Dr. Yao-Wei Huang, Zhejiang University, from the 2017 North American PRRS/National Swine Improvement Federation Joint Meeting, December 1‐3, 2017, Chicago, Illinois, USA.
More presentations at http://www.swinecast.com/2017-north-american-prrs-nsif-joint-meeting
Presented by Etienne de Villiers at the African Swine Fever Diagnostics, Surveillance, Epidemiology and Control Workshop, Nairobi, Kenya, 20-21 July 2011
Genomic surveillance of the Rift Valley fever: From sequencing to Lineage ass...ILRI
Poster prepared John Juma, Vagner Fonseca, Samson Limbaso, Peter van Heusden, Kristina Roesel, Bernard Bett, Rosemary Sang, Alan Christoffels, Tulio de Oliveira and Samuel Oyola for the Kenya One Health Online Conference, 6-8 December 2021
Presented by José M. Sánchez-Vizcaíno at the African Swine Fever Diagnostics, Surveillance, Epidemiology and Control Workshop, Nairobi, Kenya, 20-21 July 2011
Recent advances in African swine fever vaccine development at the Internation...ILRI
Presentation by Lucilla Steinaa at a Global African Swine Fever Research Alliance (GARA)/International Alliance for Biological Standardization (IABS) webinar on current efforts in African swine fever vaccines, 6 May 2021
Genomic surveillance of the Rift Valley fever: From sequencing to Lineage ass...ILRI
Poster prepared John Juma, Vagner Fonseca, Samson Limbaso, Peter van Heusden, Kristina Roesel, Bernard Bett, Rosemary Sang, Alan Christoffels, Tulio de Oliveira and Samuel Oyola for the Kenya One Health Online Conference, 6-8 December 2021
Presented by José M. Sánchez-Vizcaíno at the African Swine Fever Diagnostics, Surveillance, Epidemiology and Control Workshop, Nairobi, Kenya, 20-21 July 2011
Recent advances in African swine fever vaccine development at the Internation...ILRI
Presentation by Lucilla Steinaa at a Global African Swine Fever Research Alliance (GARA)/International Alliance for Biological Standardization (IABS) webinar on current efforts in African swine fever vaccines, 6 May 2021
Dr. Hanchun Yang - Pathogenesis and control of Chinese highly pathogenic Porc...John Blue
Pathogenesis and control of Chinese highly pathogenic Porcine Reproductive & Respiratory Syndrome (PRRSV) - Dr. Hanchun Yang, China Agricultural University, from the 2016 North American PRRS Symposium, December 3‐4, 2016, Chicago, Illinois, USA.
More presentations at http://www.swinecast.com/2016-north-american-prrs-symposium
A presentation prepared by Yaima Arocha and John Lucas for the ASARECA/ILRI Workshop on Mitigating the Impact of Napier Grass Smut and Stunt Diseases, Addis Ababa, June 2-3, 2010.
Mycoviruses of filamentous fungi and their relevance to plant pathologyNageshb11
Myco-viruses of filamentous fungus its relevance in plant pathology
different class of virus by ICTV classification act as obligate parasitic nature for fungal disease management
Phylogenetic Analysis of Newcastle Disease Virus from Indonesian Isolates Bas...UniversitasGadjahMada
This study was conducted to analyze phylogenetic of Indonesian newcastle disease virus(NDV) isolates based on fusion (F) protein-encoding gene, with aim to determine which genotype group of Indonesian NDV isolates, compared to vaccine strain that circulating in Indonesia.
Report on Rabies vaccine in India. Rabies is caused by lyssavirus which is a deadly virus which affects the CNS. And its genetic material consists of mainly RNA and it undergoes reverse transcription mechanism and multiply in the host.
1. MATERIALS AND METHODS
A) Nematode inoculums preparation:
Nematode strains (C14-5, HF, 20 and 8A )
were grown on sterilized barley medium with
Botrytis cinerea;
Nematode cultures were extracted using the
Baermann funnels technique;
C) RNA Extraction and Gene expression:
Total RNA was extracted (Provost et al., 2007),
and contaminant DNA removed using the Turbo-DNA
free kit (Ambion). RNA quantification was made on a
spectrophotometer Nanophotometer (Implen);
c-DNA was synthesis and expressed genes of
interested determined (18S internal loading control);
PCR products were loaded on 1.5% agarose gels, for
45 minutes at 120V in TAE buffer;
Nematode culture
Bursaphelenchus xylophilus (Steiner and Buhrer) Niclke is a pine wood nematode (PNW) responsible for causing pine wilt disease (PWD) in
pine trees. Resistance to plant pathogens has been widely addressed over the last decade [1]. However, it is not known how and which genes
are induced and trigger plants defense mechanism, to overcome the infection, producing a systematic defence or a local response to the
virulent agent [1, 2]. Previous studies have demonstrated the induction of P. thunbergii tree resistance by inoculating plants with non-
virulent PWN strains, suggesting that the creation of a biological control on PNW is possible (“Vaccination”) [3]. Moreover, this induced
resistance can also provide an experimental system to clarify physiological interactions between the PNW and pine trees [1,3]. The aim of
this work was to assess the resistance induction to pine wilt disease on young pine seedlings, under sterile conditions. Subsequent
inoculations were induced by (i) non-virulent isolate of B. xylophilus (C14-5) and (ii) virulent nematodes strains (20, HF and 80), on Pinus
pinaster and P. pinea. seedlings. The resistance mechanisms of PWN were assessed and the effect of seedling inoculation was determined in
terms of the expression of several Pinus genes potentially involved in the disease response. Finally, PWN progression was also monitored to
confirm successful seedling inoculation, and the possibility for full tree nursery seedlings resistance induction will be addressed.
INTRODUCTION
Inoculated seedlings of P. pinaster (A) and P.
pinea (B) with non virulent and virulent nematode
strains.
A BSeedling inoculation: (I) Cuts were made horizontally with the help of a sterile
blade and a paper tissue was fixed with parafilm surrounding the wound area. (II)
Nematode suspension was added to the tissue paper and closed (III) with parafilm
to prevent drying out of the suspension.
I II III
RESULTS AND DISCUSSION
References:
[1] Kosaka et al. (2001) Eur. J. Plant Pathol. 107: 667–675;
[2] Kuroda, K. (2008) in, Pine Wilt Disease, Springer
[3] Nose & Shiraishi (2008 ) in, Pine Wilt Disease, Springer
[4] Provost et al., (2007) Biol Res 40: 291.297.
Pinus pinaster and P. pinea seedling plant health
C14-5 survival % on the inoculated pine seedlings was determined before re-inoculation
with virulent strains [0% on P. pinaster (PP) and 70% on P. pinea (PPi)];
No seedling death or needle discoloration was observer between the inoculation with
non-virulent strain and the re-inoculation with the virulent ones;
However, resin exudates stopped on the 6th day after the re-inoculation with virulent
strains on both pine seedlings;
Plant health was reevaluated 12d after virulent inoculation. P. pinaster seedlings showed
needle necrosis and discoloration on 90% of the inoculated seedlings. As for P. pinea,
virulent inoculation showed no visual effects;
Results suggest P. pinaster is more susceptible to virulent strains than P. pinea.
P. pinaster (PP) and P. pinea (PPi) seedlings were inoculated with
4000 C14-5. Non-inoculated controls were also established
6 days after inoculation, the % of C14-5 nematode viability was
determined
Seedlings were re-inoculated 30 days after first inoculation with
2000 Nematode virulent strains (HF, 20 and 80). Non-inoculated
controls were made
B) Experimental design:
- Inoculation technique:
Expressed genes
Target gene expression were analyzed according to the effect
vaccination produced on P. pinaster and P. pinea seedlings inoculated
with non-virulent and virulent strains;
Ordination analysis showed that P. pinaster re-inoculated with
virulent strains (20 and 8A) had the same gene expression than P.
pinea seedlings, under the same conditions;
Results suggest that a “vaccination” effect may have been induced on
P. pinaster seedlings. However, the induced mechanisms are not yet
clear.
Figure 2- Principal component analysis of the expressed genes (Actin, Ubiq,
Perox, Pora, Sep1, Mat/Sam, myb1, myb2, pr4, PsylAP4, Shep, ATTRX1, TT7,
MSD1, PR10) in Pinus pinaster (PP) and Pinus pinea (PPi). Axis 1 and 2 explain
79% of the variation observed (P<0.05).
Figure 1 – Expressed genes of interest on P. pinaster (PP) and P. pinea (PPi). Legend: PPiA – P. pinea
inoculated with C14-5 strain; PPA - P. pinaster inoculated with C14-5 strain; PPiA+HF - P. pinea
inoculated with C14-5 and HF strains; PPA+HF - P. pinaster inoculated with C14-5 and HF strains;
PPiHF - P. pinea inoculated with HF strain; PPHF - P. pinaster inoculated with HF strain; PPiA-8A - P.
pinea inoculated with C14-5 and 8A strains; PPA+8A - P. pinaster inoculated with C14-5 and 8A
strains; PPi8A - P. pinea inoculated with 8A strain; PP8A - P. pinaster inoculated with 8A strain;
PPiA+20 - P. pinea inoculated with C14-5 and 20 strains; PPA+20 - P. pinaster inoculated with C14-5
and 20 strains; PPi20 - P. pinea inoculated with 20 strain; PP20 - P. pinaster inoculated with 20
strain.
PPiA
PPA
PPiA+HF
PPA+HF
PPiHF
PPHF
PPiA+8A
PPA+8A
PPi8A
PP8A
PPiA+20
PPA+20
PPi20
PP20
0
0
40 80
40
80
Axis 1
Axis2
Pine seedling
PP
PPi
PPiA
PPA
PPiA+HF
PPA+HF
PPiHF
PPHF
PPiA+8A
PPA+8A
PPi8A
PP8A
PPiA+20
PPA+20
PPi20
PP20
0
0
40 80
40
80
Axis 1
Axis2
Pine seedling
PP
PPi
Gene PPiA PPA PPiA+HF PPA+HF PPiHF PPHF PPiA+8A PPA+8A PPi8A PP8A PPiA+20 PPA+20 PPi20 PP20
18S
Actin
Ubiquinin
Peroxidase
PORA
MAT2/SAM2
Myb1
Shepherd
ATTRX1
MSD1
PR10
Conclusions and future work:
The presented results suggest that plant
vaccination is possible and may be an important tool
on plant disease control.
Vaccinated seedlings will be continually monitored.
Further proteomic and metabolomic studies will be
conducted.