the 13th conference on fungal genetics...- 3 — 発表演題および講演時間 特別講演...
TRANSCRIPT
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The 13th Conference on
Fungal Genetics and
Molecular Biology
13 2013 11 20 21
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11 月20日(月) 9:30 - 受付開始(於:講演会場) 10:30 - 10:40 開会の辞 10:40 - 13:00 口頭発表(O-1~12) 13:00 - 14:20 休憩 14:20 - 15:20 特別講演 15:20 - 16:40 ポスター発表(奇数番号) 18:00 - 懇親会 11 月 21 日(火) 9:00- 受付開始(於:ポスター会場) 9:30 - 10:50 ポスター発表(偶数番号) 11:00 - 12:40 口頭発表(O-13~20) 12:40 - 14:00 昼休み 14:00 - 16:00 シンポジウム 16:10 - 16:40 総会・表彰式 16:40 - 16:50 閉会の辞
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発表演題および講演時間 特別講演 11 月 20 日(水)14:20 - 15:20 糸状菌における菌体外消化システム:分解酵素の分子機構から見えてくるカビ・キノコのバイオマス資化戦略 東京大学 大学院農学生命科学研究科 五十嵐 圭日子
座長:阿部 敬悦 (東北大学) シンポジウム 11 月 21 日(木) 14:00 - 16:00 「糸状菌の多様性~種、ゲノム、機能」
[座長:S-1, 2:田中 千尋(京都大学);S-3, 4:本山 高幸(理化学研究所)] 14:00-14:30 S-1
14:30-15:00 S-2 Dictyocatenulata alba
15:00-15:30 S-3
15:30-16:00 S-4
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O-1 O-12 11 20 10:40 - 13:00 O-1, 2: ; O-3, 4, 5: ; O-6, 7, 8:
O-9, 10: ; O-11, 12: ; O-13, 14, 15: O-16, 17: ; O-18, 19, 20:
10:40 O-1
1 1 1 1 2 1 1 2
10:52 O-2 A. oryzae AoSO
11:04 O-3 Aospt3 1,2 1,2 1,2 1 2
11:16 O-4 Chaetomium globosum 1 2
, 1 , 2
11:28 O-5 RAM CoPag1
11:40 O-6 Trichoderma reesei
11:52 O-7 Trichoderma reesei 10 β-glucosidase isozyme
12:04 O-8 Cle/loxP 1)
1
12:16 O-9 Trichoderma reesei 1 2 1 3 3 4 1
1 2 3 4
12:28 O-10 3D
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5 —
12:40 O-11 SSH
, , , NITE
12:52 O-12
O-13 O-20 11 21 11:00 – 12:40
11:00 O-13 A. flavus A.oryzae
11:12 O-14
, ,
11:24 O-15 1 1 1,2,3 2,3 4 1 1 ,
2 3 4 / /
11:36 O-16 Ceriporiopsis subvermispora
11:48 O-17 CreD
12:00 O-18
Kieu Pham Thi Minh, , Ba Van Vu, Quoc Bao Nguyen, ,
12:12 O-19 Aspergillus fumigatus AtrR 1 2 1 1 2
1 2
12:24 O-20
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11 20 15:20 – 16:40 11 21 9:30 – 10:50 P-1 Sln1p -
1,2 3, 1, 1,2 1 , 2
, 3 Univ. of Gothenburg, Dept. of Chemistry and Molecular Biology P-2
1 , 1 , 2 1 2 P-3 11 Polyporales
CSRS David Hibett Bernard Henrrissat(CNRS) Jill Gaskel Dan Cullen (IMBT, FPL)
P-4 Cle/loxP
1) 1 P-5
1 2 3 3 1 1 2 3
P-6
P-7
P-8
1 2 1 1 1
1 2
P-9 Aspergillus oryzae
, , , , , 1, 1
, 1
P-10 L-
1 2 1 1 2 3 3 2 1 2 3
P-11 PKC
1 2 2 3 3 4, 5, 1,2 1 , 2 3 , 4 , 6
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7 —
P-12 1 3 1,2 1 2 3
P13 Aspergillus oryzae HypB
P14 A. oryzae
1 1 1
P-15 Aspergillus nidulans α-1,3-
1 2 1 1,2 1 2
P-16 Mortierella alpina 1S-4 lig4
1 1 1,2 3 4 1 1 2 3 4
P-17 Aspergillus -1,3-
1 2 3 4 4 5 1, 2
(1 , 2 , 3 4 , 5 ) P-18
⁾ ⁾ ⁾
P-19 Involvement of lectin-type cargo receptors in heterologous protein secretion in Aspergillus oryzae
Dung Huy Hoang, Jun-ichi Maruyama, Katsuhiko Kitamoto (Dept. of Biotechnol., The Univ. of Tokyo) P-20 6 CoA
1 Kenneth Bruno2 1 1 1 1 Scott Baker21 1 2
P-21 A. oryzae AoRim15
P-22 Aspergillus nidulans
P-23
P-24 Aspergillus oryzae 331-25 sense RNA, 331-25 antisense RNA
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P-25 A. oryzae EcdR
P-26 A. oryzae AoAtg9
P-27
P-28
( ) P-29 Aspergillus nidulans C sterigmatocystin
P-30 Aspergillus nidulans CON
a b Özlem Sarikaya Bayrama Özgür Bayrama Gerhard H. Brausa a b
P-31 Aspergillus nidulans
, P-32 HECT HulA
P-33
1 1 1 1 2 1 1 2
P-34 A. oryzae 2 acyl-CoA binding protein (AoAcb1 AoAcb2)
P-35 A. oryzae AoSO
P-36 Aspergillus oryzae
P-37 Aspergillus oryzae
, , P-38 Roles of AoLAH in regulating Woronin body position and function in Aspergillus oryzae
Pei HAN, Feng Jie JIN, Jun-ichi MARUYAMA, Katsuhiko KITAMOTO (Dept. of Biotechnol., The Univ. of Tokyo)
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9 —
P-39 DNA
P-40 A. oryzae
AoAtg26
P-41
P-42 MOA
P-43 Trichoderma reesei
1 2 1 3 3 4 1 1 2 3 4
P-44 Poly(ADP-ribose) glycohydrolase
1 1 2 2 1 1 1 2
P-45 Aspergillus oryzae ADAM
, , P-46 hydrophobin RolA
1 1 2 3 4 1,2 1
2 3 4 P-47
P-48 3D
P-49
P-50 Aureobasidium pullulans -4-
P-51 Aspergillus nidulans GfsA O- Galƒ
1 2 1 2 2 1 1 1 2
P-52
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P-53 Aspergillus oryzae D-(DamA)
1 1 1 1, 5 1 1 2
3 4 4 1
1 2 3 4 5JIRCAS P-54 Aspergillus oryzae pepO
P-55 Aspergillus oryzae saccharolysin homolog
( ) P-56 Trichoderma reesei 10 β-glucosidase isozyme
P-57
P-58 hydrophobin RolA cutinase CutL1 RolA
1, 1, 1, 1, 1, 2, 3, 11 2 3
P-59
1 1, 2, 2, 2, 2, , 1 1, 1 1 , 2
P-60 Phanerochaete chrysosporium
P-61 CreA CreB
P-62 AmyR::XlnR
P-63 Trichoderma reesei
P-64 Aspergillus nidulans ManS
P-65
1 1 1 2 1 1 1 (1 2 )
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P-66 Aspergillus aculeatus
P-67 Expression cluster analysis of the transcriptomes at sequential growth stages in the white-rot fungus,
Phanerochaete carnosa, grown on aspen and spruce woods. Hitoshi Suzuki (RIKEN, CSRS), Philip Wong, Chi-Yip Ho, Yunchen Gong, Kin Chan, Elisabeth Tillier and Emma Master (Univ. of Toronto)
P-68 AmyR MalR
P-69 pH PacC
1 2 1 1 1 1 1 2
P-70 xyrA larA XlnR AraR
P-71 Aspergillus aculeatus ClbR ClbR2
P-72 Molecular basis that divides ManR-dependent and ManR/McmA-dependent genes in Aspergillus
nidulans Nuo Li, Miki Aoyama, Kyoko Kanamaru, Makoto Kimura, Tetsuo Kobayashi (Grad. Sch. Bioagric. Sci., Nagoya Univ.)
P-73 Aspergillus niger PKS-NRPS
P-74 Tri6
P-75
P-76
P-77 Aospt3
1,2 1,2 1,2 1 2 P-78 Emericella variecolor
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P-79 anditomin
P-80 Aspergillus fumigatus pseurotin A
P-81 Fusarium sp. FN080326 A
1 Jun-Pil JANG2 Jae-Hyuk JANG2 1 Jong Seog AHN2 1 1 CSRS 2KRIBB
P-82 Fusarium sp. RK97-94
luc1 luc4 1,2, 1, 1, 2, 2 1 2
P-83 hstD
1 2 2 1 2 (1 2 ) P-84 Aspergillus oryzae III CsyB 3-acetyl-6-alkyl-
α-pyrone 1 1 1 1 2 1
P-85 DNA
1 1 1 2 1 (1 2 ) P-86 Roxithromycin
P-87 cAMP
, P-88 Aspergillus fumigatus
, P-89 A. fumigatus
1 2 3 2 1 2
3 P-90 3 G
1, 2 1 2 1 2
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P-91 ChSte20 ChCla4 1 2 1 1 1 1 2
P-92 Ras GTPase CoIra1 CoRas2 cAMP
CoMekk1-Cmk1 MAPK
P-93 MoCV1 MoCV1-B
( )
P-94 Alternaria alternata global regulator LaeA
1 1 2 1 2 3 1
1 2 3 P-95 BcAtg1
1 2 1 1 2 P-96 RAM CoPag1
P-97
1 2 3 4 1
1 2 3 4 P-98 RTS1 CoRTS1
, , ,
P-99 Enoyl-CoA hydratase
P-100 CoTEA4 CoMOD5
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Special Lecture
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糸状菌における菌体外消化システム:分解酵素の分子機構から見えてくる カビ・キノコのバイオマス資化戦略
CBHCDH CBH
-1,4
CDH
-Fe3+
1. 1-5
Phanerochaete chrysosporium CDH
pH
2. 6-9
Trichoderma reesei 7CBH TrCel7A
1 "m 1,000
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15 —
E212Q TrpW40A
-7 -1 +1 +2
3.
CDH TrCel7A
1. Igarashi, K. et al. Fung. Genet. Biol. (1997) 2. Igarashi, K. et al. Eur. J. Biochem. (1998) 3. Igarashi, K. et al. J. Biol. Chem. (1999) 4. Igarashi, K. et al. Biochem. J. (2002) 5. Igarashi, K. et al. FEBS J. (2005) 6. Igarashi, K. et al. FEBS J. (2006) 7. Igarashi, K. et al. FEBS J. (2007) 8. Igarashi, K. et al. J. Biol. Chem. (2009) 9. Igarashi, K., Uchihashi, T. et al. Science (2011) Extracellular digesting-system in filamentous fungi: Fungal strategy for the biomass utilization “visualized” from molecular mechanisms of degrading enzymes Kiyohiko Igarashi (Department of Biomaterial Sciences, Graduate School of Agricultural and Life Sciences, The University of Tokyo)
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Symposium
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S-1
15010 30 150
1 5
DNA 5001000
1000
3000
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17 —
20114 1 1000 3500
2010
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S-2 Dictyocatenulata alba
(RIKEN BRC-JCM)
Dictyocatenulata alba Finley & E.F. Morris
; ; 1 “1 ” “ (hyphomycete)”[1,2]
Morris and Finley[3] (anamorphic fungus) [4]
[2]
[1,4] [1,5]
D. alba
[5]
1) D. alba 11 5 2) (JCM 5358, 5359, 5360, 8401, 12918) DNA
PCR [nuSSU, nuLSU (D1/D2), ITS]
3) nuSSU
RT-PCR
1) D. alba 5
Lecanoromycetes Ostropomycetidae
2) nuLSU ITS (JCM 5359, 5360) (JCM 8401, 12918) (JCM 5358)
3) nuSSU a. I
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b. 5 D. alba 2 5
c. d. 5 3 nuLSU ITS
e. D. alba
4) 5
nuLSU ITS nuSSU –; JCM 5358, 5359, 8401 D. alba 3 (cryptic species)
species complex 5) – ; PDA, 20C 12
D. alba (lichenized fungus)
; D. alba
6) 3 D. alba Gyalecta (Ostropales, Ostropomycetidae)
(KPM-NC0017988) D. albanuLSU ITS
- - 7) (Chocorua, NH, USA) D. alba
/ D. alba
–
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20 —
[1] Seifert et al. 1987. Mycologia 79: 459–462. [2] Seifert et al. 2011. The genera of hyphomycetes. CBS biodiversity series, vol. 9 (ISBN
978-90-70351-85-4; http://www.generaofhyphomycetes.org/). [3] Morris and Finley. 1967. Am Midl Nat 77: 200–204. [4] Diederich et al. 2008. Sauteria 15: 205–214. [5] An et al. 2012. Fung Biol 116: 1134–1145.
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S-3
4000 3000
4000 3500 3000
1986 Rhizopus Absidia
2008 Aspergillus oryzae
A. oryzae
A. oryzae1990 1876
Black2005 1000Aspergillus oryzae
A. oryzae
A. oryzaeA. oryzae
2009NRRL
Northern Regional Research Laboratories
A.oryzae
NRRL 467 1920 K. Oshima TL Ao 5c Ueda, Osaka = Thom 290-4429-Ao 5c
NRRL 466 1920 K. Oshima TL Ao 5b Ueda, Osaka = Thom 290-4429-Ao 5b
NRRL 460 1920 K. Oshima TL Ao 1 = Thom 290-4429-Ao 1
NRRL 1911 1943 S.A. Waksman TL No.35
NRRL 461 1920 K. Oshima TL Ao N
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22 —
= Thom 290-4429-AoN
NRRL 462 1920 K. Oshima TL Ao P = Thom 290-4429-Ao P
NRRL 455 1920 K. Oshima TL= Thom 290-4429-A
NRRL 456 1920 K. Oshima TL = Thom 290-4429-Ao
NRRL 457 1920 K. Oshima TL = Thom 290-4429-Ao 6
NRRL 458 1920 K. Oshima TL = Thom 290-4429-Ao-Old
NRRL 459 1920 K. Oshima TL= Thom 290-4429-Ao K
NRRL 463 1920 K. Oshima TL = Thom 290-4429-Ao 2a
NRRL 464 1920 K. Oshima TL = Thom 290-4429-Ao 4a
NRRL 1919 1943 S.A. Waksman TL No.42
1 TL Aspergillus oryzae Wicklow 2002
Elander 2002 SIM News1978
1948”Cephalosporium acremonium”
Cephalosporium
acremonium CephalosporiumAcremonium Acremonium strictum
A. chrysogenum A. strctum Gams, 1971A. strictum A. strictum
Sarocladium strictum Summerbell et al., 2011
2013 1 1 1 1Acremonium
Rossman et al., 2013
Tolypocladium
inflatum Penicillium citrinum Aspergillus terreus Coleophoma sp. 1970 1990
1993
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23 —
iPS
Bills (2013)
http://www.kitasato.ac.jp/ NP Depo http://www.npd.riken.jp/npd/ja/
http://www.meti.go.jp/policy/tech_ promotion/kenkyuu/saishin/42.pdf
2012
http://www.opbio.com/http://www.hyphagenesis.co.jp
HGI2006 TAMA 10
StrMyco 22,000 ExMyco 41,000 PowKinoco 1,200
TAMA
Hypocreales
15,000 7001 10% 0.5%
600TAMA
NBRC 252 587
HGIExMyco
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24 —
MS ACCESS
ExMycoFusarium
incarnatum C NA 255Nagahashi et al., 2009
Pochonia suchlasporia pochonicine NUsuki et al., 2009
Hypomyces pseudocorticiicolaF 2928-1 F 2928-2 Kanai et al.,
2005 Mariannaea M. camptosporamariannin A B Fukuda et
al., 2011 Simplicillium lanosoniveum preussin2012
20094
ExMyco 38,8002 NH1
in silicoNH4
25http://www.chusho.meti.go.jp/keiei/sapoin/2013/0731globalkoubo.pdf
2010 CBD COP10
3CBD
1992 JBACBD
Saccharomyces cerevisiae Wang et al., 2012
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25 —
CBS-KNAW Fungal
Biodiversity Centre, Centraalbureau voor Schimmelcultures, CBSCBS
2012 Stagonospora paludosa 300
http://connect.barcodeoflife.net/forum/topics/at-the-cbs-we-are-looking-for-the-type-of-stagonospora-to-barcode
TAMA2012 231
4TAMA
Bills GF, Gloer JB, An Z. 2013. Coprophilous fungi: antibiotic discovery and functions in an
underexplored arena of microbial defensive mutualism. Current Opinion in Microbiology. 16: 1-17.
Black JG 2005 (2007) 1. In 2
1-27pp. Elander RP. 2002. University of Wisconsin contributions to the early development of Penicillin
and cephalosporin antibiotics. SIM News 52: 270-278. Fukuda T, Sudoh Y, Tsuchiya Y, Okuda T, Fujimori F, Igarashi Y. 2011. Marianins A and B,
prenylated phenylpropanoids from Mariannaea camptospora. Journal of Natural Products. 74: 1327–1330
Gams W. 1971. Cephalosporium-artige Schimmelpilze (Hyphomycetes). G. Fischer Verlag, Stuttgart. 262pp.
Kanai Y, Tatsumi Y, Tokiwa T, Watanabe Y, Fujimaki T, Ishiyama D, Okuda T. 2005. F2928-1 and -2, new antifungal antibiotics from Cladobotryum sp. Journal of Antibiotics 58: 507-513.
Koizumi T. 2004. Sake brewery as traditional and advanced technologies. In Proceedings of The 10th International Congress for Culture Collections (ICCC-10) Open Seminar “Traditional Koji mold entering a modern gate” edited by Okuda T & Bennet J. 28-33pp.
Nagahashi Y, Ito T, Masubuchi M, Yamaguchi Y, Sakamoto H, Sudoh M, Kawasaki K, Tsukuda T, Katoh H, Okuda T, Aoki M. 2009. NA255: anti-hepatitis C virus agent produced by Fusarium incarnatum and fermentation of NA808, a derivative of NA255. Proceedings of SIM Annual Meeting and Exhibition. Westin Hrbour Castle, Toronto, ON Canada, July 26-30. P96.
Rossman AY, Seifert KA, Samuels GJ, Minnis AM, Schroers HJ, Lombard L, Crous PW, Poldmaa K, Cannon PF, Summerbell RC, Geiser DM, Zhuang WY, Hirooka Y, Herrera C, Salgado-Salazar C, Chaverri P. 2013. Genera in Bionectriaceae, Hypocreaceae, and Nectriaceae (Hypocreales) proposed for acceptance or rejection. IMA Fungus 4: 41-51.
Summerbell RC, Gueidan G, Schroers HJ, de Hoog GS, Starink M, Rosete YA, Guarro J, Scott JA. 2011. Acremonium phylogenetic overview and revision of Gliomastix, Sarocladium,
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and Trichothecium. Studies in Mycology 68: 139-162. Usuki H, Toyo-oka M, Kanzaki H, Okuda T, Nitoda T. 2009. Pochonicine, a polyhydroxylated
pyrrolizidine alkaloid from fungus Pochonia suchlasporia var. suchlasporia TAMA 87 as a potent beta-N-acetylglucosaminidase inhibitor. Bioorganic & Medicinal Chemistry 17: 7248-7253.
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2008 1. In 73-93pp.
2009 46: 10-18. 1978 237pp.
1986 In 487-496pp.
2011 Simplicillium lanosoniveum (
) 3A04p03 2012
2012 5961 2012 10 11
Fungal Bank and its Industrial Application Toru Okuda (Mycology & Metabolic Diversity Research Center, Tamagawa University Research Institute)
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27 —
S-4
PCR
NRP
kb
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28 —
1 2
3,4 References 1: Ishidoh K et al 2013. Curr. Genet in press 2: Shimizu T et al 2005. Appl Environ Microbiol 71:3453-3457. 3: Sakai K et al 2009. Biotechnol Lett. 31:1911-6 4: Sakai K et al 2012 Appl Microbiol Biotechnol. 93:2011-22.
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Oral Session
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O-1 (P-33)
1 1 1 1 2 1 1 2
Virocontrol
Propidium iodideFUN-1
RNAseqresponse to stimulus, transport
Cytological and transcriptional analyses of heterogenic incompatibility in Rosellinia nacatrix. 1Takahiro Uwamori, 1Kanako Ikeda, 1Chiaki Kida, 1Hitoshi Nakayasiki, 2Satoko Kanematsu, 1Kenichi Ikeda
(1Grad. Sch. Agric. Sci, Kobe Univ. 2Nat. Inst. Fruit Tree Sci. NARO)
O-2 (P-35) A. oryzae AoSO
Aspergillus oryzae
A. oryzaeAoSOAoSO
AoSO 3 N 1-555C 1147-1195
AoSO C N
AoSOAoSO 2
AO090005001564 AosoAO090005001564 AoBni1
AoSO AO090005001564
Investigation of AoSO function in cell repair after hyphal wounding in Aspergillus oryzae Junpei KAWABATA, Kei SAEKI, Jun-ichi MARUYAMA, Katsuhiko KITAMOTO (Dept. of Biotechnol., The Univ. of Tokyo)
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30 —
O-3 (P-77) Aospt3
1,2 1,2 1,2 1 2
Aospt3secondary metabolites SMs
SMs Aospt3 SMs SMs ΔAospt3
(kojA kojR kojT) 100Aospt3
SMs laeAAospt3 laeA ΔAospt3 laeA
ΔAospt3ΔlaeAΔlaeA
Aospt3 laeA ΔlaeAspt3 ΔAospt3 laeA
Aospt3 laeA
Functional analysis of Aospt3 secondary metabolic regulator
Masato Hirose , Moriyuki Kawauchi, Kazuhiro Iwashita (Hiroshima Univ, NRIB)
O-4 Chaetomium globosum
1 2 , 1 , 2
Chaetomium globosum.
[Nakazawa et al. (2013) J. Am. Chem. Soc., in press]CGKW14; ligD pyrG
Velvet A CgveA chaetoviridin cochliodinol
aureonitol, chaetoglocin SPT10CgsptJ mollipilin coactatin
aureonitolchaetoviridin
ChIPaureonitol/mollipilin chaetoglocin/coactatin
H3K9 trimethylation CgveAcochliodinol chaetviridin
CgveA
Alternation of biosynthetic regulation and its effect on epigenetic states in Chaetomium globosum.
Takehito Nakazawa, Kan’ichiro Ishiuchi, Yasutaka Gotanda, Hiroshi Noguchi, Kenji Watanabe.
(School of Pharmaceutical Sciences, University of Shizuoka)
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31 —
O-5 (P-96) RAM CoPag1
CoKEL2cokel2Δ
CoKEL2 6
RAM (regulation of Ace2p activity and cellular morphogenesis)Pag1 (Tao3) CoPAG1 copag1Δcokel2Δ
CoPAG1CoPag1::RFP
CoPag1::RFP
Colletotrichum orbiculare CoPag1, a component of RAM network in Saccharomyces cerevisiae, is involved in
appressorium development triggered by plant-derived signals
Sayo Kodama, Ayumu Sakaguchi, Yasuyuki Kubo
(Graduate School of Life and Environmental Sciences, Kyoto Prefectural Univ.)
O-6 (P-63) Trichoderma reesei
Trichoderma reesei
PC-3-7 MFSTRP3405 PC-3-7
TRP3405PC 3405 PC-3-7
PC 3405PC 3405 PC-3-7
Influence of gene destruction of cellulose specific transporter in Trichoderma reesei
Hiroki Taniguchi, Hideyuki Kusaka, Tkanori Furukawa, Yosuke Shida, Wataru Ogasawara
(Nagaoka Univ. of Tech)
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32 —
O-7 (P-56) Trichoderma reesei 10 β-glucosidase isozyme
Trichoderma reesei β-glucosidase (BGL) BGL
10 BGL (Cel1A Cel1B Cel3A Cel3B Cel3C Cel3D Cel3E Cel3F Cel3G Cel3H)
GH1 Cel1A Cel1B GH3 BGL
BGL p-Nitrophenyl-β-D-glucoside (pNPG1) (G2) Cel3H BGL BGL
pNPG1 G2 Cel3A Cel3BCel3E Cel3C Cel3D Cel3F Cel3G
Cel1B pNPG1 G2 Cel1A G2 BGL 10% G2 pNPG1
BGL G2 BGL (Cel1 Cel3ACel3B Cel3E)
Cel1A Cel3A5.4 mg/ml 2.8 mg/ml Cel3A
Cel1A Cel1A
Enzymatic properties of β-glucosidase isozymes from Trichoderma reesei
Boyang Guo, Kouichi Nozaki, Masahiro Mizuno, Yoshihiko Amano
(Dept. of Biosci. & Textile Technol., Interdisciplinary Graduate School of Sci. and Technol., Shinshu Univ.)
O-8 (P-4) Cle/loxP
1) 1
, ,
, lox Cre lox Cre/loxP, 2012 , Cre
, Cre,
adeA xynG2 Cre lox
, Cre, Cre ,
adeA , Cre adeA Cre , ligD
xynG2 , , Cre Penicillium chrysogenum (xylP)
, adeACre , adeA Cre
,
Development of a self-excising Cre/loxP marker recycling system in Aspergillus oryzae
Silai Zhang, Akihiko Ban, Naoki Ebara, Osamu Mizutani1), Mizuki Tanaka,TakahiroShintani, KatsuyaGomi
(Grad.Sch,Agric.Sci.,Tohoku Univ., NRIB1))
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33 —
O-9 (P-43) Trichoderma reesei 1 2 1 3 3 4 1
1 2 3 4
Trichoderma reesei
FT-IR
T. reesei6
GPIT. reesei GPI
Exploration of protein related to cell surface fibrous material synthesis of Trichoderma reesei
Shingo Tahara1, Mikiko Nitta2, Yosuke Shida1, Yoshiki Horikawa3, Junji Sugiyama3, Masako Osumi4, Wataru
Ogasawara1
(1Nagaoka Univ. of Technol., 2JST, 3RISH, Kyoto Univ., 4IIRS)
O-10 (P-48) 3D
Coleophoma empetri F-11899FR901379 A AAC
Micafungin AAC
AAC
AAAC A
CAPCR Pseudomonas sp. SY-77 CA
AAAC
Substrate switching of antibiotics acylase by 3D modeling Kazuki Nakayama, Masato Yamada, Hiromi Nishida, Yasuhiro Isogai (Toyama Pref. Univ., Dept. Biotech. )
-
34 —
O-11 SSH
, , , NITE
SSHYeast
ext., Sucrose, Soluble starch SSH 300Illumina MiSeq
17 SSH Blast
NEDO
Investigation of fungal SSH-libraries for biomass decomposition
Sonyon Ann, Akihiro Oguchi, Natsuko Ichikawa, Tomohiro Sekigawa, Kei Kamino
(NITE)
O-12
Production of useful materials from fungi with blue light stimulation
Masanobu Kojima1, Ryuhei Miura1, Satoshi Mihara2, Masaki Ichimura2
(1Grad. Sch. Agri., Shinshu Univ.; 2JA Nakanoshi)
-
35 —
O-13 A. flavus A.oryzae
Aspergillus flavusA. oryzae A. flavus ,
,A. flavus Aspergillus ,Circumduti ,Flavi A.oryzae
2,
ATCC,ARS Culture collection,NRRL A. flavus 31 2 NBRC NRRLITS ,ISSR DNAchip
ITS
,6 A.sojaeA. oryzae 13 ISSR1 (GTG)5 ISSR2(GACA)4
ISSR , 3A. oryzae , A. flavus
, ISSR A. flavus DNAchip
A. oryzae 13 A. flavus Gene springA. flavus A. oryzae
Genome wide phylogenetic analysis of Aspergillus flavus and A. oryzae
Tamy Ohota, Ken Oda, Kazuhiro Iwashita, Nami Goto (NRIB)
O-14
, ,
NO
NO
Aspergillus nidulans NO
ntpA ntpA cysteine-rich 23 aa NO ntpA
NO NO
NO-inducible
nitrosothionein (iNT) iNT thioredoxin thioredoxin reductase
iNT iNT NO iNT
iNT NO
Discovery of an NO-resistant peptide nitrosothionein from Aspergillus nidulans.
Shengmin Zhou, Toshiaki Narukami, Shunsuke Masuo, Naoki Takaya
(Graduate School of Life and Environmental Sciences, Univ. of Tsukuba)
-
36 —
O-15
1 1 1,2,3 2,3 4 1 1 , 2
3 4 / /
660 nm 528 nm 467 nm 375 nmLED
JPS56131319(A)-1981-10-14 2
2
WC1 WC2 Gf.WC1 Gf.WC2
Gf.BMR1Bipolaris oryzae BMR1
Gf.BMR1Gf.BMR1
Gf.BMR1
Grifola frondosa distinguishes between blue light and near-ultraviolet light.
Atsushi Kurahashi1, Shimoda Takafumi1, Masayuki Sato1,2,3, Fujimori Fumihiro2,3, Jyuniji Hirama2, Kozo Nishibori1
(1Yukiguni Maitake, 2 Hyphagenesis, 3Tokyo Kasei Univ. 4Kanazawa Inst. Tech. EOE)
O-16 Aspergillus fumigatus
Ceriporiopsis subvermispora
Ceriporiopsis subvermispora
Phanerochaete chrysosporium C.
subvermispora C. subvermispora
ceriporic acid
Suppression Subtractive Hybridization
Vanillin-induced cellular response in the selective white rot fungus, Ceriporiopsis subvermispora
Takahito Watanabe, Kenichiro Mori, Ayako Kido, Takahiro Hasegawa, Hiroshi Nishimura, Yoichi Honda, Takashi
Watanabe (RISH, Kyoto Univ.)
-
37 —
O-17 CreD
CreD , , ,
CreB ( , 2012), CreD( , 2012) , CreD
CreD , CreD
creB creD creB , CreDCreD Rod1 , Snf1
, CreD 2 Snf1, , 2
creB CreD, , CreD
, CreD HECT HulA, CreD HulA
Regulation of glucose repression through dephosphorylation of arrestin-like protein CreD in Aspergillus
oryzae.
Mizuki Tanaka, Tetsuya Hiramoto, Takahiro Shintani, Katsuya Gomi
(Div. Biosci. Biotechnol. Future Bioind., Grad. Sch. Agric. Sci., Tohoku Univ.)
O-18
Kieu Pham Thi Minh, , Ba Van Vu, Quoc Bao Nguyen, ,
7HMT HMT
MoHMT4SET1
MoHMT4 H3K4H3K4me2 ChIP-seq
H3K4me2 RNA-seqMoHMT4
MoHMT4 MoHMT4
Histone lysine methyltransferases are involved in various aspects of pathogenesis in Magnaporthe oryzae.
Kieu Pham Thi Minh, Yoshihiro Inoue, Ba Van Vu, Quoc Bao Nguyen, Ken-ichi Ikeda, Hitoshi Nakayashiki.
(Fac. of Agri., Kobe Univ.)
-
38 —
O-19 Aspergillus fumigatus AtrR
1 2 1 1 2 1 2
Aspergillus fumigatus
A. fumigatus AtrR
bHLH SrbA(cyp51A, erg3,
erg24A, erg25A) atrR srbA atrR srbA
ABC AbcC/CdrB
srbA abcC/cdrB atrRabcC/cdrB AtrR
ABC
AtrR plays a crucial role in azole-resistance in Aspergillus fumigatus
Daisuke Hagiwara1 Ayumi Ohba2 Kiminori Shimizu1 Susumu Kawamoto1 Katsuya Gomi2
1MMRC, Chiba Univ. 2Grad. Sch. of Agric. Sci., Tohoku Univ.
O-20
Colletotrichum orbiculare
3 NIS1 CoDN3 CoMC69
CoDN3
SEC4SEC4 ER-Golgi SEC22
ER-Golgi
Effector Delivery toward Ring-Shaped Interface Developed between Colletotrichum orbiculare and Its Host
Cucumber
Hiroki Irieda, Hitomi Maeda and Yoshitaka Takano
(Grad. School of Agriculture, Kyoto Univ.)
-
Poster Session
-
39 —
P-1 Sln1p -
1,2 3, 1, 1,2 1 , 2 , 3 Univ.
of Gothenburg, Dept. of Chemistry and Molecular Biology
AtETR1 (HK)HK
(EBD) HK Sln1p HK HKTcsB HKD HK HK
AtETR1 EBD Sln1p Aspergillus nidulans TcsB HKD HK
Sln1p ScSln1pAtETR1(EBD)-ScSln1p(HKD) AtETR1(EBD)-AnTcsB(HKD) ScSln1p HK
HK HOG
Functional complementation and ethylene response of plant-fungal fusion histidine kinase in a
temperature-sensitive sln1 yeast mutant.
Mayumi Nakayama1,2, Kentaro Furukawa3, Akira Yoshimi1, Keietsu Abe1,2
(1NICHe., Tohoku Univ., 2Grad. Sch. Argric. Sci., Tohoku, Univ., 3 Univ. of Gothenburg, Dept. of Chemistry and
Molecular Biology)
P-2
1 , 1 , 2 1 2
0-24 DNA
PCR
DGGE
DNA
24 3141
Effects of aging treatment on bacterial community in bamboo sawdust 1Yuji Nakada, 1Makoto Yoshida, 2Koji Takabatake
(1Tokyo Univ. of Agric. and Technol., 2Toyama Prefectural Agric, Forestry and Fisheries Research Center, Forestry
Research Institute)
-
40 —
P-3 11 Polyporales
CSRS David Hibett Bernard
Henrrissat(CNRS) Jill Gaskel Dan Cullen (IMBT, FPL)
Polyporales
11 Polyporales
3 Bjerkandera adusta Ganoderma sp. Phlebia brevispora 11 Polypore CAZy
75 -
±
±
Genome-wide analysis of polysaccharides degrading enzymes in eleven white- and brown-rot Polyporales
Chiaki Hori (CSRS, RIKEN), Kiyohiko Igarashi, Masahiro Samejima (Agri., Univ. of Tokyo), David Hibbett (Clark
Univ), Bernard Henrissat (CNRS), Jill Gaskel and Dan Cullen (USDA-FPL) P-4 (O-8)
Cle/loxP 1) 1
,
, , lox Cre lox Cre/loxP
, 2012 , Cre , Cre
, adeA xynG2 Cre lox
, Cre, Cre ,
adeA , Cre adeA Cre , ligD
xynG2 , , Cre Penicillium chrysogenum (xylP)
, adeACre , adeA Cre
,
Development of a self-excising Cre/loxP marker recycling system in Aspergillus oryzae
Silai Zhang, Akihiko Ban, Naoki Ebara, Osamu Mizutani1), Mizuki Tanaka,TakahiroShintani, KatsuyaGomi
(Grad.Sch,Agric.Sci.,Tohoku Univ., NRIB1))
-
41 —
P-5
1 2 3 3 1 1 2
3
Monitoring filamentous fungi existing in the cultural properties from infinitesimal quantity samples
Tomoko Wada1, Kiyohiko Igarashi2, Yuko Fujiwara3, Yoshihisa Fujii3, Ken Okada1
(1Cent. for Conservation and Restoration Techniques, Nat. Res. Ins. for Cultural Properties, Tokyo, 2Grad. School of
Agricultural and Life Sciences, Univ. of Tokyo, 3Grad. School of Agriculture, Kyoto Univ.)
P-6
1, 2, 3, , 1, 2, 2, 4, 5, 5, 3, 1, 6 1 , 2 , 3 , 4 ,5
, 6
hydrophobin(-RolA) Aspergillus fumigatus hydrophobin ( )
RolA
(Fe3O4) ( 200 nm) RolA
in vivo RolA RolA
pH
Development of imaging nano-particles coated with immune-response free (stealth) fungal materials
Daiki Sato1, Kana Matumura2, Shintaro Takahashi3, Kimihide Muragaki1, Ishi Keiko2, Kazuyoshi Kawakami2,
Takanari Togashi4, Seiichi Takami5, Masafumi Ajiri5, Manabu Fukumoto3, Keietsu Abe1, 6
(1Grad Sch Agric Sci Tohoku Univ, 2Grad Sch Med Tohoku Univ, 3IDAC Tohoku Univ, 4Sci Yamagata
Univ.5IMRAM Tohoku Univ, 6NICHe Tohoku Univ)
-
42 —
P-7
1 1
Production of materials with anticancer activity from oyster mushroom mycelia by blue light stimulation
Ryuhei Miura1, Kazuya Toda1, Hiroshi Fujii1, Masanobu Kojima1, Satoshi Mihara2, Masaki Ichimura2
(1Grad. Sch. Agri., Shinshu Univ.; 2JA Nakanoshi)
P-8
1 2 1 1 1 1 2
Lyophyllum shimejiAgrobcterium tumefaciens pPZP-HYG2
EHA104PCR 20
A. tumefaciens 3 6
TAIL-PCR
Agrobacterium tumefaciens Mediated Transformation of Lyophyllum shimeji
Mayumi Yamamoto1, Kosuke Izumitsu2, Yuki Kitade1, Kanako Hatoh1, Chihiro Tanaka1
(1Grad. Sch. of Agri., Kyoto Univ., 2Sch. of Environmental Science, Univ. of Shiga Pref. )
-
43 —
P-9 Aspergillus oryzae
, , , , , 1, 1
, 1 [ ] Aspergillus
(PLoS ONE(2013) 8, e62512)
[ ] A. oryzae ∆Aoatg8 amyB
12 ∆Aoatg8 1 2
EGFP
Improved production of a heterologous protein in Aspergillus oryzae by autophagy deficiency.
Hiroshi Teramoto, Kiyomi Kagami, Kaihei Kojima, Hiroaki Udagawa, Shinobu Takagi, Jun-ichi Maruyama1,
Katsuhiko Kitamoto 1
(Novozymes Japan Ltd, 1 Department of Biotechnology, The University of Tokyo)
P-10 L-
1 2 1 1 2 3 3 2 1
2 3
Aspergillus oryzae L-
A. oryzae RIB40
lactate dehydrogenase (LDH)LDH A. oryzae LDHΔ871 100 g/L 50 g/L
A. oryzae LDHΔ871 100 g/L 30 g/L 99.9% L
L-
L-lactic acid production from starch by simultaneous saccharification and fermentation in Aspergillus oryzae
Satoshi Wakai1, Toshihide Yoshie2, Nanami Asai1, Ryosuke Yamada1, Chiaki Ogino2, Hiroko Tsutsumi3, Yoji Hata3,
Akihiko Kondo2
(1Org. Adv. Sci. Tech., Kobe Univ., 2Dept. Chem. Sci. Eng., Grad. Sch., Kobe Univ., 3Res. Inst., Gekkeikan)
-
44 —
P-11 PKC 1 2 2 3 3 4, 5, 1,2 1
, 2 3 , 4 , 6
CWISC PKC
Aspergillus nidulans PKC AnPkcA PKC MgPkc1PKC
MgPkc1 MgPkc1
MgPkc1 Z-705 Z-705 Z-705
PKC1 PKC PKC Z-705
Z-705 PKCPKC PKC1
Construction of yeast screening system for novel chemical agents that inhibit PKC of filamentous fungi.
Fumio Shoji1, Mayumi Nakayama2, Akira Yoshimi2, Tomonori Fujioka3, Kiyoshi Kawai3, Hiroyuki Horiuchi4,
Hideaki Umeyama5, Keietsu Abe1,2 (1Grad. Sch. Argric. Sci. & 2NICHe. Tohoku Univ., 3Kumiai Chemical Industry
Co., Ltd., 4 Grad. Sch. Agric. Sci. Tokyo Univ., 5Facul. Sci. Engin. Chuo Univ.)
P-12
1 3 1,2 1 2 3
Aspergillus oryzae
(CFGD) CFGD(Comprehensive Aspergillus oryzae genome database: CAoGD)
http://nribf21.nrib.go.jp/CFGD/ RIB40 9 27
Roche 454 GS FLX titanium 37 RIB RIB40
AspGD A. nidulans FGSC A4 A. niger CBS513.88
Development and publication of Comprehensive Aspergillus oryzae Genome Database (CAoGD) Ken Oda1, Yasuo Uemura3, , Kazuhiro Iwashita1,2 (1NRIB, 2Hiroshima Univ., 3Genaris Inc.)
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45 —
P-13 Aspergillus oryzae HypB
Hydrophobin
Hydrophobin Hydrophobin
Aspergillus oryzae HydrophobinhypA~C hypB
HypBhypB egfp A. oryzae
HypB-EGFP Proteinase KEGFP HypB
HypB
Construction of cell surface display systems using hydrophobin (HypB) with functional peptides in
Aspergillus oryzae
Shintaro Ohashi, Keisuke Domae, Satoshi Nakama, Asuka Kase, Harushi Nakajima
(Dept. of Agricultural Chemistry, Univ. of Meiji)
P-14
A. oryzae 1 1
1
1)
Aspergillus oryzae
A. oryzae cDNA A. oryzae tef1
cDNA amyBP-glaA142 HA His6
AmyB Kex2A. oryzae 10 NSlD-ΔP10 2) 5 DPY 4
Ni-NTASaccharomyces cerevisiae
Pho36p AO090003000602, AO090026000756 A. oryzae
1) Narasimhan et al. (2005) Mol. Cell 17, 171-180. 2) Yoon et al. (2011) Appl. Microbiol. Biotechnol. 89, 747-759.
Production and purification of plant osmotins in Aspergillus oryzae
Hiromasa ITO, Jun-ichi MARUYAMA, Koji NAGATA1, Masaru TANOKURA1, Katsuhiko KITAMOTO
(Dept. of Biotechnol., The Univ. of Tokyo; 1Dept. of Appl. Biol. Chem., The Univ. of Tokyo)
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46 —
P-15 Aspergillus nidulans α-1,3-
1 2 1 1,2 1 2
AG AG
AGAG
AG AG
AGAG
Morphologic properties and penicillin production of Aspergillus nidulans α-1,3-glucan deficient mutants
under liquid culture conditions. Masahiro Hitosugi1, Akira Yoshimi2, Azusa Inaba1, Keietsu Abe1,2(1Grad. Sch. Sci.,& Tohoku,Univ. 2NICHe, Tohoku Univ.)
P-16 Mortierella alpina 1S-4 lig4
1 1 1,2 3 4 1 1 2
3 4
(PUFA)
Mortierella alpina 1S-4 PUFA PUFAPUFA
DNA LIG4lig4 lig4
PCR lig4lig4 lig4
93 3 lig4 3%lig4 4 1
25% lig4
A lig4 gene-disrupted strain from oleaginous fungus Mortierella alpina 1S-4
Hiroshi Kikukawa1, Eiji Sakuradani1, Akinori Ando1,2, Misa Ochiai3, Sakayu Shimizu4, Jun Ogawa1 (1Div. Appl.
Life Sci., Grad. Sch. Agric., Kyoto Univ., 2Res. Uni. Physiol. Chem., Kyoto Univ., 3Suntory Global Innovation
Center Ltd., 4Fac. Bioenviron. Sci., Kyoto Gakuen Univ.)
-
47 —
P-17 Aspergillus -1,3-
1 2 3 4 4 5 1, 2 (1 , 2
, 3 4 , 5 )
Aspergillus A. oryzae A. nidulans -1,3-
AG A. nidulans AG AGCongo Red - Lysing Enzymes
AGAG
Histoplasma capslatum Magnaporthe grisea AG
AG AG AG
AGAG
AG 2 25 AGAG AG
AG
Production of alpha-1,3-glucan oligosacchalides from cell wall of Aspergilli and its functional analysis
Akira Yoshimi1, Azusa Inaba2, Shigekazu Yano3, Hiroaki Sasaki4, Tomoo Goto4, Kazuyoshi Kawakami5, Keietsu
Abe1, 2 (1NICHe, 2Grad. Sch. Agric. Sci., 5Sch. of Med. Tohoku Univ., 3Grad. Sch. Sci. & Eng. Yamagata Univ., 4Gifu Shellac MFG) P-18
⁾ ⁾ ⁾
Phoma betae DNA polymeraseAspergillus oryzae ⁾
TP$
GFP RFP
2 Cytochrome P450
TP
1) Fujii et al., Biosci. Biotechnol. Biochem., 75, 1813-1817 (2011)
Subcellular localization of aphidicolin biosynthetic enzymes expressed in the heterologous host, Aspergillus
oryzae.
Akihiko Ban, Mizuki Tanaka, Ryuya Fujii¹⁾, Atsushi Minami¹⁾, Hideaki Oikawa¹⁾, Takahiro Shintani, Katsuya Gomi ( Div. Biosci. Biotechnol. Future Bioind., Grad. Sch. Agric. Sci., Tohoku Univ., ¹Hokkaido Univ.)
-
48 —
P-19 Involvement of lectin-type cargo receptors in heterologous protein secretion in Aspergillus oryzae Dung Huy Hoang, Jun-ichi Maruyama, Katsuhiko Kitamoto (Dept. of Biotechnol., The Univ. of Tokyo)
Aspergillus oryzae has a superior capacity to secrete a large amount of proteins into the medium, and is being
industrially used for the production of commercially important proteins. In order to further improve the strain, detailed knowledge about its secretory pathway is crucial. However, current understanding on how elements of A. oryzae’s secretory pathway interact with secreted proteins is still very scarce. Cargo receptor is a class of membrane proteins that are responsible for the efficient recruiting and packaging of cargo proteins into anterograde or retrograde vesicles for trans-organelle transportation. One subclass of cargo receptor, the lectin cargo receptor, specifically interacts with glycoproteins via their lectin domain. In recent years, lines of evidence are implying that lectin cargo receptor not only recruits cargo proteins into transport vesicles but also functions in quality control of secretory proteins. It is then very interesting to investigate the relationship between lectin cargo receptors and heterologous proteins in A. oryzae. The mammalian Vip36 and yeast Emp47p are well-studied lectin cargo receptors, with the former being reported to be involved in post-ER quality control of certain secretory proteins. A BLAST search on the A. oryzae genome database returned two homologs of these two proteins. The two genes ID are AO090026000428 and AO090102000145, which were named Aovip36 and Aoemp47, respectively. Fluorescence microscopy observation revealed that the two lectin cargo receptors mostly colocalized with an early Golgi marker. Deletion of each cargo receptor gene improved the secretion of heterologously expressed bovine chymosin and human lysozyme into the culture supernatant. Moreover, analysis of the ER-enriched fractions revealed that deletion of each gene reduced the degree of heterologous protein accumulation, suggesting that those two cargo receptors may be involved in the retention of heterologous proteins along the secretory pathway. Further studies to investigate the interaction mechanism between those two cargo receptors and heterologous proteins are being conducted. P-20
6 CoA 1 Kenneth Bruno2 1 1 1 1 Scott Baker2 1
1 2
Aspergillus oryzae
CoA CoA
S. cerevisiae A. nidulans
61 1
4
Analysis on the Roles of Six Fatty Acyl-CoA Synthetase Homologs in the Growth of Aspergillus oryzae
Koichi Tamano1, Kenneth Bruno2, Hideaki Koike1, Tomoko Ishii1, Ai Miura1, Myco Umemura1, Scott Baker2,
Masayuki Machida1 (1AIST, 2PNNL)
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49 —
P-21 A. oryzae AoRim15
Rim15
Rim15 Aspergillus oryzae Aorim15
Rim15 A. oryzae Aorim15PD
Aorim15 EGFP AoRim15S. cerevisiae A. oryzae
AoRim15 Rim15C Rim15
AoRim15 C
Functional analysis of the stress response regulator protein AoRim15 in Aspergillus oryzae
Hidetoshi NAKAMURA, Takashi KIKUMA, Katsuhiko KITAMOTO
(Dept. of Biotechnol., Univ. of Tokyo) P-22
Aspergillus nidulans
,
188 15P-8
Aspergillus nidulansA. nidulans 12
0.1 3 24 RNA DNA
GO No. 46395 1901575 6631Flavin-containing monooxygenase Cytochrome
P450 AN10582 AN7522
A. nidulans
Analysis of soil humic acid degradation by the fungus Aspergillus nidulans
Nami Nakazawa, Ken-Ichi Oinuma, Naoki Takaya
(Grad. School of Life and Environmental Sciences, Univ. of Tsukuba)
-
50 —
P-23
Aspergillus oryzaeA. oryzae 50
(Ishitani et al. 1956) A. oryzaeA. oryzae
A. oryzae A. oryzae
A. oryzae (ΔpyrG) (ΔadeB)2
PCR
AoFus3 AoSO
DPY
Investigation of nutrition effects in hyphal fusion efficiency of Aspergillus oryzae
Wakako TSUKASAKI, Jun-ichi MARUYAMA, Katsuhiko KITAMOTO
(Dept. of Biotechnol., The Univ. of Tokyo)
P-24 Aspergillus oryzae 331-25 sense RNA, 331-25 antisense RNA
EST , 331-25 mRNA , 528 EST 43 ,
331-25 sense RNA ( SN RNA) 331-25 antisense RNA ( AS RNA) (1) 331-25 ,
mRNA brlA , PCR
AS RNA , AS RNA , 331-25 331-25 ,
, , 331-25 , , , 331-25
, ( , ) ,, , , 331-25
, 331-25 SN RNA, AS RNA , (1) , 12 p. 46 (2012)
Analysis of 331-25 sense RNA, 331-25 antisense RNA in Aspergillus oryzae
Masaru Tsujii, Hiroto Morita, Hiroshi maeda, Yohei Yamagata, Michio Takeuchi
Dept. of Applied Biological Science, Tokyo Univ. of Agriculture and Technology
-
51 —
P-25 A. oryzae EcdR
Aspergillus oryzaeMAT1-1 MAT1-2
SclR2
ecdR A. oryzae
A. oryzaeEGFP mDsRed
ecdR 2sclR ecdR
A. oryzae
Promotion effects of deleting a sclerotial formation repressor EcdR for discovery of sexual reproduction in
Aspergillus oryzae
Yuki TANAKA, Feng Jie JIN, Jun-ichi MARUYAMA, Katsuhiko KITAMOTO
(Dept. of Biotechnol., The Univ. of Tokyo) P-26
A. oryzae AoAtg9
/
Atg9 Atg9 Atg
pre-autophagosomal structure(PAS)Aspergillus oryzae
AoAtg9Aoatg9
AoAtg8 EGFPAoatg9
AoAtg9 A. oryzae AoAtg9AoAtg9-EGFP
AoAtg9-EGFP mDsRed-AoAtg8AoAtg9 PAS
Aoatg AoAtg9
Localization and functional analysis of the autophagy-related membrane protein AoAtg9 in Aspergillus
oryzae
Kohei Fujiki, Takashi Kikuma, Katsuhiko Kitamoto
(Dept. of Biotechnol., Univ. of Tokyo)
-
52 —
P-27
50%
Aspergillus oryzaeAO080569000108
AO080569000108
Congo red Calcofluor whiteGlcNAc EGFP
AO080569000108-EGFPFM4-64 AO080569000108
Functional analysis of functionally-unknown gene related cell wall stress resistance in Aspergillus oryzae.
Nao Tokunaga1, Ayako Senoo3,4, Taiki Futagami2, Kaoru Takegawa2, Kazuhiro Iwashita3,4, Masatoshi Goto2
(1Grad. Sch. Biores. Bioenviron., Kyushu Univ., 2Faculty of Agriculture, Kyushu Univ., 3Grad. Sch. Adv. Sci. Mat., Hiroshima Univ., 4NRIB) P-28
( )
8% (Aspergillus
oryzae)
DNAGeneral amino acid permease (Gap1) (GapA)
1) GapA
PCRGapA
GapA Gap1GapA
GapAGap1
1) 2012
Functional analysis of the Aspergillus oryzae amino acid transporter
Hiromu Hamanaka, Akihiro Kaneko, Harue Kitagawa, Motoaki Sano, Kenji Ozeki, Shinichi Ohashi (KIT)
-
53 —
P-29 Aspergillus nidulans C sterigmatocystin
Aspergillus nidulans C PKC pkcA
PkcAPkcA cell wall integrity CWI
BckA MkkA MpkA MAPPkcA
sterigmatocystin STaflR mRNA pkcA PkcA
ST STPkcA PkcA ST ST
PkcA STCWI PkcA rlmA
ST MkkA MkkA ST ST PkcA ST
CWI MAP
Functional analysis of Protein kinase C in sterigmatocystin biosynthesis in Aspergillus nidulans
Takuya Katayama and Hiroyuki Horiuchi (Dept. of Biotechnol., Univ. of Tokyo)
P-30 Aspergillus nidulans CON
a b Özlem Sarikaya Bayrama Özgür Bayrama Gerhard H. Brausa
a b 1980
con con-6 con-10CON-6 CON-10
96 86CON-6 CON-10
conF conJ GFPFM4-64
Role of CON-6 and CON-10 homologue in Aspergillus nidulans
Satoshi Suzukia b Özlem Sarikaya Bayrama Özgür Bayrama Gerhard H. Brausa
(a Georg-August-Universität Göttingen b NFRI)
-
54 —
P-31 Aspergillus nidulans
,
Aspergillus nidulans AmyR
AmyR STAmyR ΔamyR
AmyR A. nidulans
ΔamyRDNA ΔamyR ST PKS
NRPSAmyR AmyB ΔamyB
ΔamyRgphA ΔgphA ΔamyB
AmyB GphAA. nidulans GphA AmyB
ΔamyR STST
Analysis for glycogen and sterigamtocystin metabolisms by Aspergillus nidulans
Airi Komatsuzaki, Yosuke Kamimura, Naoki Takaya
(Grad Sch Life Environment Sci, Univ. of Tsukuba) P-32
HECT HulA
MalP
Rsp5CreD
MalP 2012Rsp5 HulA MalP
HulA 3 WW CreD-3FLAG GST-HulA-WW domainCreD HulA WW
HulAsGFP-MalP HulAsGFP-MalP HulA MalP
HulA WW CreDPPLY 3 PXY CreD-HulA
Involvement of HECT ubiquitin ligase, HulA, in degradation of maltose permease in Aspergillus oryzae
Yuka Matsuura, Mizuki Tanaka, Tetsuya Hiramoto, Takahiro Shintani, Katsuya Gomi
(Div.Biosci.Biotechnol.Future Bioind.,Grad.Sch.Agric.Sci.,Tohoku Univ.)
-
55 —
P-33 (O-1)
1 1 1 1 2 1 1 2
Virocontrol
Propidium iodideFUN-1
RNAseqresponse to stimulus, transport
Cytological and transcriptional analyses of heterogenic incompatibility in Rosellinia nacatrix. 1Takahiro Uwamori, 1Kanako Ikeda, 1Chiaki Kida, 1Hitoshi Nakayasiki, 2Satoko Kanematsu, 1Kenichi Ikeda
(1Grad. Sch. Agric. Sci, Kobe Univ. 2Nat. Inst. Fruit Tree Sci. NARO)
P-34
A. oryzae 2 acyl-CoA binding protein (AoAcb1 AoAcb2)
acyl-CoA binding protein (Acb1) Acb1 Acb1
ACBP (Acyl-CoA Binding Protein) Acb1 ACBP
2 Aspergillus oryzae 2 acyl-CoA binding protein (AoAcb1 AoAcb2)
AoAcb1-EGFPAoAcb2-EGFP Aoacb2 thiA
Aoacb2Aoatg1 Aoatg4 Aoatg8
AoAcb1Aoatg15 AoAcb1
AoAcb1Aoacb2 AoAcb1 AoAcb2
Analysis of two acyl-CoA binding proteins (AoAcb1, AoAcb2) in Aspergillus oryzae
Kouhei KAWAGUCHI, Takashi KIKUMA, Katsuhiko KITAMOTO
(Dept. of Biotechnol., Univ. of Tokyo)
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56 —
P-35 (O-2) A. oryzae AoSO
Aspergillus oryzae
A. oryzaeAoSOAoSO
AoSO 3 N 1-555C 1147-1195
AoSO C N
AoSOAoSO 2
AO090005001564 AosoAO090005001564 AoBni1
AoSO AO090005001564
Investigation of AoSO function in cell repair after hyphal wounding in Aspergillus oryzae
Junpei KAWABATA, Kei SAEKI, Jun-ichi MARUYAMA, Katsuhiko KITAMOTO
(Dept. of Biotechnol., The Univ. of Tokyo)
P-36 Aspergillus oryzae
hydrophobin70~150a.a.
Aspergillus oryzae hypA,B,C
hypA,B,C , HypA HypB HypChypA hypB
HypA HypBhypB hypA hypA hypB
eGFP, DsRed hypA, hypBHypA, HypB
HypA hypAhypA ,hypA -400~-200bp
Characterization and localization of hydrophobins in Aspergillus oryzae
Yui Yamakawa, Chie Ishida, Fuyuka Hayakawa, Yuka Mizuno, Harushi Nakajima
(Dept. of Agricultural Chemistry, Univ. of Meiji)
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57 —
P-37 Aspergillus oryzae
, ,
Aspergillus oryzae
Polyphosphate metabolism and stress response in Aspergillus oryzae
Sawaki Tada, Hikaru Ohkuchi, Ken-Ichi Kusumoto (NFRI, NARO) P-38 Roles of AoLAH in regulating Woronin body position and function in Aspergillus oryzae Pei HAN, Feng Jie JIN, Jun-ichi MARUYAMA, Katsuhiko KITAMOTO (Dept. of Biotechnol., The Univ. of
Tokyo) Woronin body is a Pezizomycotina-specific organelle observed in the vicinity of septum, and plugs the septal
pore in response to cellular wounding. Previously, we characterized AoHex1 as the major protein of Woronin body in Aspergillus oryzae1), and investigated the Woronin body differentiation from the peroxisome2). Recently, the Leashin (LAH) protein was identified to tether Woronin bodies to the cell cortex in Neurospora crassa3). In this study we attempted to investigate the roles of Leashin protein in regulating Woronin body position and function in A. oryzae.
We predicted Aolah gene encoding a single polypeptide of 5,727 amino acids, which is homologous to the N. crassa lah gene expressed into two distinct proteins3). AoLAH-EGFP expressed from the endogenous locus was detected as Woronin body-like dots along the hyphae and closely associated with the septum. Transmission electron microscopic analysis demonstrated that the Aolah gene disruption led to no tethering of Woronin bodies in the vicinity of septum. We also observed excessive loss of the cytoplasm upon hyphal injury in Aolah disruptant, suggesting the functional involvement of AoLAH in the septal plugging ability of Woronin body.
N-terminal conserved region of AoLAH (AoLAH[1-2039]) was expressed as EGFP fusion protein, and it was detected at both sides of the septal pore, which is typical for Woronin body localization, suggesting a role of AoLAH N-terminal region in association with Woronin body. C-terminal conserved region of AoLAH (AoLAH[4710-5727]) expressed as EGFP fusion protein was detected closely to the septal pore both in the wild-type strain and Aolah disruptant, indicating that AoLAH[4710-5727] itself functions for associating to the septum. When AoLAH N- and C-terminal fusion fragment lacking the unconserved middle region was expressed in Aolah disruptant, Woronin bodies were re-discovered in the vicinity of septum, however, the cytoplasm was still excessively lost upon hyphal injury. This suggests that the unconserved middle region of AoLAH has a role in the septal plugging ability of Woronin body, which is being further evaluated. 1) Maruyama et al. (2005) Biochem. Biophys. Res. Commun. Vol. 331, 1081-1088. 2) Escaño et al. (2009) Eukaryot. Cell Vol. 8, 296-305. 3) Ng et al. (2009) PLoS Genet. Vol. 5, e1000521.
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P-39 DNA
DNA DNADNA NHEJ
DNANHEJ
SSA MMEJNHEJ SSA MMEJ
TAIL-PCRDNA
The mode of random integration of exogenous DNA in Neurospora crassa
Ryuhei Kamada, Shuuitsu Tanaka, Shin Hatakeyama
(Lab. Genet., Dept. Regulatory Biol., Saitama Univ.) (1Division Appl. Biol., Fac. Tex. Sci. Tech., Shinshu Univ., 2Mushroom Lab. Hokuto Co.)
P-40
A. oryzaeAoAtg26
Atg26Pichia pastoris PpAtg26
Sccharomyces cerevisiae atg26A. oryzae AoAtg26
A. oryzae Aoatg26
A. oryzaeAoAtg26
EGFP-AoAtg8 Aoatg26Cvt AoApe1-EGFP
Aoatg26 CvtAoAtg26
Aoatg26
Analysis of the autophagy-related sterol glucosyltransferase AoAtg26 in Aspergillus oryzae Takashi Kikuma, Takayuki Tadokoro, Katsuhiko Kitamoto
(Dept. of Biotechnol., Univ. of Tokyo)
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59 —
P-41
Effects on growth and repression of A.oryzae GapA gene disruption.
Akihiro Kaneko, Hiromu Hamanaka, Motoaki Sano, Kenji Ozeki, Shinichi Ohashi
(Kanazawa Institute of Technology)
P-42 MOA
Aspergillus oryzae 1)
4-methyl-2-oxopentanoic acid (MOA)
MOA 2-
5MOA NAD(P)H MOA
5 1 NAD(P)H MOA TEF1
MOA 1) Suzuki, M. Yoneyama, H. Koizumi, T. (1982) The mechanism of formation of ethyl leucinate, an important aroma component in sake. Hakkokogaku, 60, 19-25.
Overexpression and characterization of a novel 4-methyl-2-oxopentanoic acid (MOA) reductase in Aspergillus
oryzae.
Tatsuya Yamamoto, Emiri Koide, Tiaki Mori, Takeura Kengo, Miki Daikoku Motoyuki, Shimizu, Masashi Kato
(Fac. of Agri., Meijo Univ.)
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60 —
P-43 (O-9) Trichoderma reesei 1 2 1 3 3 4 1
1 2 3 4
Trichoderma reesei
FT-IR
T. reesei6
GPIT. reesei GPI
Exploration of protein related to cell surface fibrous material synthesis of Trichoderma reesei
Shingo Tahara1, Mikiko Nitta2, Yosuke Shida1, Yoshiki Horikawa3, Junji Sugiyama3, Masako Osumi4, Wataru
Ogasawara1
(1Nagaoka Univ. of Technol., 2JST, 3RISH, Kyoto Univ., 4IIRS)
P-44
Poly(ADP-ribose) glycohydrolase 1 1 2 2 1 1 1 2
(ADP- ) (ADP-
) poly(ADP-ribose) polymerase (PARP) poly(ADP-ribose) glycohydrolase (PARG) 2 PARPDNA Aspergillus nidulans
parp ortholog 1 A. nidulans parg ortholog
A. nidulans 7 parg 1 Mg2+
(ADP- ) fungal PARG (fPARG) A. nidulans DNA (MMS) parp fparg
fPARG DNA fparg
Identification and Characterization of the Novel Poly(ADP-ribose) Glycohydrolase of Filamentous Fungus
Aspergillus nidulans.
Mio Hirano1, Miho Sudo1, Shunsuke Masuo2, Naoki Takaya2, Motoyuki Shimizu1, Masashi Kato1 (1Fac. Of Agri.,
Meijo Univ., 2Grad. Sch. of Life & Env. Of Tsukuba)
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61 —
P-45 Aspergillus oryzae ADAM
, ,
Aspergillus oryzae , ADAM ( A Disintegrin And Metalloproteinase ) 2 , 2
admA, admB ADAM , , ADAM 30
ADAM , , , ADAM , A. fumigatus ADM-B
sheddase Schizosaccharomyces pombe Mde10 ,
, A. oryzae ADAM admA, admB ∆admA ∆admB , ∆admA∆admB
, , calcofluor white congo red ,
37 , ,
, A. oryzae ADAM
Functional analysis of intracellular metalloprotease ADAM in Aspergillus oryzae
Takuji KOBAYASHI, Hiroshi MAEDA, Michio TAKEUCHI, Youhei YAMAGATA
(Dept. of Applied Biological Chemistry, Tokyo Univ. of Agriculture and Technology) P-46
hydrophobin RolA 1 1 2 3 4 1,2 1 2
3 4
hydrophobin RolA PBSA PBSACutL1 PBSA hydrophobin kinetics
RolA Leu137, Leu142 PBSA pH4-10 PBSARolA pH4 PBSA pH4-10 0
RolA pI=4.6-4.8 PBSA RolA
RolA RolA QCMpH4, 7, 10
RolApH4, 7 pH10 RolA
RolARolA pH4
RolA RolA
RolA kinetics
Analysis of the interaction between Aspergillus oryzae hydrophobin RolA and solid surfaces
Takumi Tanaka1, Hiroki Tanabe1, Toru Takahashi2, Takanari Togashi3, Toshihiko Arita4, Keietsu Abe1,2 (1 Grad. Sch.
Agric. Sci., Tohoku Univ., 2 NICHe., Tohoku Univ., 3 Dept. Sci., Yamagata Univ., 4 IMRAM., Tohoku Univ.)
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62 —
P-47
Aspergillus oryzae 3 pepstatin insensitive protease (PIP) 317-062315-005 306-018 PIP
DGDT W(F/Y)EW(F/Y/L)P ED(F/Y) PIP aspartic protease
glutamic protease A. oryzae PIP
PIP 3 mRNA317-062 315-005 Pichia pastoris 306-018
Aspergillus nidulans 317-062 306-018315-005 8 M urea
3 PIP pH317-062 306-018 pH pH
315-005
Enzymatic Properties of Pepstatin Insensitive Protease in Aspergillus oryzae
Marii Takeuchi, Ayako Okamoto, Haruka Abo, Hiroshi Maeda, Youhei Yamagata, Michio Takeuchi
(Division of Applied Biological Chemistry, Tokyo Univ. of Agriculture and Technology)
P-48 (O-10) 3D
Coleophoma empetri F-11899FR901379 A AAC
Micafungin AAC
AAC
AAAC A
CAPCR Pseudomonas sp. SY-77 CA
AAAC
Substrate switching of antibiotics acylase by 3D modeling Kazuki Nakayama, Masato Yamada, Hiromi Nishida, Yasuhiro Isogai (Toyama Pref. Univ., Dept. Biotech.)
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63 —
P-49
4
chymosin chymosin - casein Phe105 – Met106Aspergillus oryzae
A. oryzae RIB40 11
1
AOchymosin 1 A. nidulans A89AOchymosin 1
pH 30 pH 5.5 A. luchuensisALchymosin 1
Characterization of milk clotting enzymes in Aspergilli
Yoko Takyu, Ayako Okamoto, Hiroshi Maeda, Yohei Yamadata, Michio Takeuchi
( Division of Applied Biological Chemistry, Tokyo Univ. of Agriculture and Technology ) P-50 Aureobasidium pullulans -4-
Aureobasidium pullulans ATCC 20524-L- abfB DNA 4,996 bp
DNA abfB -4-(bphA) A. pullulans ATCC 20524 cDNA
RACE (Rapid Amplification of cDNA Ends) bphA
A. pullulans ATCC 20524 30 3mRNA cDNA cDNA RACE
5� RACE 3� RACE bphA PCRabfB 555 bp bphA ORF 1,512 bp
54 bp 1 bphA 96 bp TATA63 bp 114 bp A bphA
bphA cDNA ORF EcoRI NotIpET-26b
pBPH103 E. coli BL21 (DE3) bphA cDNA BphA
Characterization of benzoate-4-hydroxylase gene from Aureobasidium pullulans.
Chihiro Higashida, Kazuyoshi Ohta
(Dept. Biochem. Appl. Biosci., Univ. of Miyazaki)
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64 —
P-51 Aspergillus nidulans GfsA O- Galƒ
1 2 1 2 2 1 1 1 2
, Aspergillus nidulans GfsA (Galƒ)
, GfsA O- Galƒ∆gfsA (GMP) ,
GfsA-3xFLAG UDP-Galƒ , EB-A240-200 kDa GMP PNGase F
-elimination , PNGase F-elimination , O- pmtA pmtC
GMP wt , O-WscA-HA wt, ∆gfsA , WscA-HA
HA EB-A2 , ∆gfsA WscA-HA EB-A2, ∆gfsA WscA-HA GfsA-3xFLAG
in vitro Galƒ , WscA-HA Galƒ, GfsA O- Galƒ
GfsA is a novel glycosyltransferase involved in biosynyhesis of galactofuranose antigen of O-glycan in
Aspergillus nidulans.
Haruka Motomatsu1, Taiki Futagami2,Keisuke Ekino1, Kaoru Takegawa2,Masatoshi Goto2,Yoshiyuki
Nomura1,Takuji Oka1(1 Univ. of Sojo,2Univ. of Kyusyu)
P-52
1- -3-
LOXN001 2 LOX
PoLOX1 PoLOX2 LOXPoLOX1 PoLOX2 cDNA PoLOX1 PoLOX2
PCR PoLOX1 PoLOX2 cDNA
PoLOX1 PoLOX2 640 72 kDa 661 74 kDa1 PoLOX1 PoLOX2 cDNA pET16b
BL21(DE3) SDS-PAGE72 kDa 74 kDa pH PoLOX1
pH 11.5 PoLOX2 pH 5.5 7.0 PoLOX1 PoLOX2 Km Vmax0.05 mM 0.22 µmol/min 0.18 mM 0.90 µmol/min
Functional analysis of two lipoxygenase genes of Pleurotus ostreatus strain N001
Daiki Kobayashi, Kenta Oguro, Yuji Tasaki
(Dept. of Mater. Eng., Nagaoka Col. of Technol.)
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65 —
P-53 Aspergillus oryzae D-
(DamA) 1 1 1 1, 5 1 1 2
3 4 4 1 1 2 3 4
5JIRCAS
β- (BapA) N β- (β-Ala )(Heck, T et, al. 2007, 2012) BapA
(AO090138000075) Aspergillus oryzaeA. oryzae N His-Tag
17 (L 13 , D 3 , β 1) aminoacyl-p-nitroanilide (pNA) β-Ala-pNA BapA D-Leu-pNA
D-Phe-pNA D-stereoselective aminopeptidase (DamA)D-Leu-NH2 LC/MS/MS D-Leu-OH
D-Leu-D-Leu-NH2 DamA BapAD-Leu-pNA 3.0 M NaCl DamA pNA 3.1
DamAM. Matsushita-Morita et al.
Appl. Biochem. Biotechnol. (in press) Characterization of a D-stereoselective aminopeptidase (DamA) from Aspergillus oryzae Mayumi Matsushita-Morita1, Hiroyuki Nakagawa1, Sawaki Tada1, Junichiro Marui1,5, Satoshi Suzuki1, Ryota Hattori1, Hitoshi Amano 2, Hiroki Ishida3, Youhei Yamagata4, Michio Takeuchi4, Ken-Ichi Kusumoto1
(1 Natl. Food Res. Inst., NARO, 2Amano Enzyme, 3Gekkeikan, 4Tokyo Univ. of Agric. Tech., 5 JIRCAS.)
P-54 Aspergillus oryzae pepO
Aspergillus oryzae RIB 40
126 RIB 40 APase PepO
pepO pyrG pepO
pepO pepO pepORIB 40 5
APasepepO antipain
antipain AorsinAZ-Arg-Arg-MCA RIB 40 pepO aorsinA
RIB 40PepO AorsinA
Extracellular endoproteases of Aspergillus oryzae pepO gene deletion strain
Ayako UENO , Hiroshi MAEDA , Youhei YAMAGATA , Michio TAKEUCHI (Division of Applied Biological Chemistry,Tokyo Univ. of Agriculture and Technology)
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66 —
P-55 Aspergillus oryzae saccharolysin homolog
( ) [ ] A. oryzae S. cerevisiae 1 saccharolysin homolog oryzalysin ( Ols ) A , B , C Saccharolysin
A. oryzae ols A , ols B , ols C 3 A. oryzae Ols A. oryzae
oryzalysin [ ] ols A , ols B , ols C
ols A , ols B , ols C 2 , 4 – dinitrophenol olsA
olsA ols A , ols B , ols C olsC
olsA olsC olsA olsA olsC
Functional analysis of intracellular metalloproteases saccharolysin homolog in Aspergillus oryzae
Yuichiro ISHIKAWA,Hiroshi MAEDA,Michio TAKEUCHI,Youhei YAMAGATA (Division of Applied Biological Chemistry, Tokyo Univ. of Agriculture and Technology)
P-56 (O-7) Trichoderma reesei 10 β-glucosidase isozyme
Trichoderma reesei β-glucosidase (BGL) BGL
10 BGL (Cel1A Cel1B Cel3A Cel3B Cel3C Cel3D Cel3E Cel3F Cel3G Cel3H)
GH1 Cel1A Cel1B GH3 BGL
BGL p-Nitrophenyl-β-D-glucoside (pNPG1) (G2) Cel3H BGL BGL
pNPG1 G2 Cel3A Cel3BCel3E Cel3C Cel3D Cel3F Cel3G
Cel1B pNPG1 G2 Cel1A G2 BGL 10% G2 pNPG1
BGL G2 BGL (Cel1 Cel3ACel3B Cel3E)
Cel1A Cel3A5.4 mg/ml 2.8 mg/ml Cel3A
Cel1A Cel1A
Enzymatic properties of β-glucosidase isozymes from Trichoderma reesei
Boyang Guo, Kouichi Nozaki, Masahiro Mizuno, Yoshihiko Amano
(Dept. of Biosci. & Textile Technol., Interdisciplinary Graduate School of Sci. and Technol., Shinshu Univ.)
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67 —
P-57
Tricholoma matsutakeL- Phe
PhePhe PAL PAL
TmPAL1 cDNA DNA PALTmPAL1
PAL NBRC30605 RNA RT-PCR 3 5 RACE TmPAL1 cDNA
TmPAL1 PAL 60%TmPAL1 PCR 3 5 PCR
cDNA 74 DNA TmPAL1
pET-28 BL21(DE3)TmPAL1
Structure and functional characterization of a phenylalanine ammonia-lyase gene, TmPAL1, in Tricholoma
matsutake.
Hayato Miyakawa, Naoki Katsuda, Yuji Tasaki
(Dept. of Mater. Eng., Nagaoka Col. of Technol.)
P-58
hydrophobin RolA cutinase CutL1 RolA
1, 1, 1, 1, 1, 2, 3, 1
1 2 3
hydrophobin , Aspergillus oryzae, polybutylene succinate-co-adipate(PBSA)
hydrophobin RolA PBSA cutinase CutL1 PBSA RolACutL1 , PBSA CutL1 PBSA
, RolA CutL1 , RolA His32, Lys34 CutL1 Glu31, Asp142, Asp171 , RolA , H32S/K34SCutL1 , E31S/D142S/D171S , NaCl
, RolA CutL1 NaCl
, RolA CutL1RolA
RolA , QCM RolA-CutL1 , RolA His32, Lys34 Lys41, Lys46, Lys51 , His32, Lys34
CutL1 , Kd
Aspergillus oryzae hydrophobin RolA possesses positive residues involving in RolA-cutinase Cutl1 interaction
Yusei Tsushima1, Daiki Sato1, Yoonkyung Kim1, Kimihide Muragaki1, Kenji Uehara1, Toru Takahashi2, Youhei
Yamagata3, Keietsu Abe1 (1 Grad. Sch. Agric. Sci., Tohoku Univ., 2 NRIB., 3 Tokyo univ. of Agric. And Technol)
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68 —
P-59
1 1, 2, 2, 2, 2, , 1 1, 1 1 , 2
Aspergillus kawachii
25 40 3040 RNA DNA Agilent
Technologies 2296 250 Gene Ontology
40 30
Transcriptome analysis of white koji mold in a barley koji-making process
Taiki Futagami1, Kazuki Mori1, Shotaro Wada2, Yasuhiro Kajiwara 2, Hideharu Takashita2, Toshiro Omori2,
Kosuke Tashiro1, Satoru Kuhara1, Masatoshi Goto1
(1Kyushu Univ., 2Sanwa Shurui Co., ltd.) P-60
Phanerochaete chrysosporium
Phanerochaete chrysosporium
2% w/v 4% w/v2% w/v Cel7
4% w/v
9 Cel7 14
Static cultivation of Phanerochaete chrysosporium to unveil responses to xylan components
Yuki Nakamura, Chiaki Hori, Kiyohiko Igarashi, Masahiro Samejima
(Dept. Biomat. Sci., Univ. of Tokyo)
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69 —
P-61 CreA CreB
CreA Aspergillus nidulans CreA
CreB CreA creA, creB
creA/creB creA creA/creB creB
-
creA creA/creB - creA/creB
creA -
Hyperproduction of amylases by double deletion of CreA and CreB involved in carbon catabolite repression
in Aspergullus oryzae
Sakurako Ichinose, Mizuki Tanaka, Takahiro Shintani, Katsuya Gomi
(Div. Biosci. Biotechnol. Future Bioind., Grad. Sch. Agric. Sci., Tohoku Univ.) P-62
AmyR::XlnR
XlnR
AmyR N
FLAG-His-tag AmyR DNA N 68aa XlnR DNA
C 812aa AmyR::XlnR amyR
FLAG AmyR::XlnR
AmyR::XlnR CMC
A model chimeric transcription factor: construction and characterization of an AmyR::XlnR hybrid
transcription factor.
Yuhei KANEKO1, Hisaki TANAKA2, Jun-ichiro MARUI , Motoyuki SHIMIZU1, Tetsuo KOBAYASHI2, Masashi
KATO1. 1Meijo Univ., 2 Nagoya Univ.
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70 —
P-63 (O-6) Trichoderma reesei
Trichoderma reesei
PC-3-7 MFSTRP3405 PC-3-7
TRP3405PC 3405 PC-3-7
PC 3405PC 3405 PC-3-7
Influence of gene destruction of cellulose specific transporter in Trichoderma reesei
Hiroki Taniguchi, Hideyuki Kusaka, Tkanori Furukawa, Yosuke Shida, Wataru Ogasawara
(Nagaoka Univ. of Tech)
P-64 Aspergillus nidulans ManS
A. oryzae ManRA. nidulans manR manS manR manS
manS , manS konjac glucomannan (KG) 24 ,
RNA RNA manC, manE, manF ManS ManR manB manC
manC ManR ManS ManRManS manC eglA eglB cbhA cbhD
faeC ManR ManSCMC manS EglA EglB ManS
ManRKG manSNorthern
Physiological function of ManS, a fungal-specific transcription factor in Aspergillus nidulans
Ayako Watanabe, Miki Aoyama, Kyoko Kanamaru, Makoto Kimura, Tetsuo Kobayashi
(Graduate Sch. of Bioagric. Sci., Nagoya Univ. )
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71 —
P-65
1 1 1 2 1 1 1
(1 2 )
Ca2+ CaM
Phanerochaete chrysosporium
Pleurotus ostreatus Lac
MnP PC9 CaM
shRNA Lac MnP
CaM W-7 Lac MnP
CaM
Lac MnP
Role of calmodulin in regulation of ligninolytic enzymes expression in Pleurotus ostreatus.
Takashi Suetomi1, Takaiku Sakamoto1, Yoshitaka Tokunaga1, Yoichi Honda2, Kousuke Izumitsu1, Kazumi Suzuki1
and Toshikazu Irie1
(1Unvi. of Shiga Pref., 2Kyoto Univ.)
P-66 Aspergillus aculeatus
Aspergillus aculeatus
cellobiohydrolase I (cbhI) orotidine 5’-phosphate
decarboxylase T-DNA 5-fluoroorotic acid (5-FOA) 5-FOA
cbhI cbhI (B7 ) inverse PCR B7 T-DNA
pPTRII B7 (gene1) cbhI gene1
Identification of regulator(s) controlling the expression of cellulase genes in Aspergillus aculeatus
Syota Yuki, Emi Kunitake, Shuji Tani, Jun-ichi Sumitani, Takashi Kawaguchi
(Grad. Sch. Life & Env. Sci., Osaka Pref. Univ.)
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72 —
P-67 Expression cluster analysis of the transcriptomes at sequential growth stages in the white-rot fungus, Phanerochaete carnosa, grown on aspen and spruce woods. Hitoshi Suzuki (RIKEN, CSRS), Philip Wong, Chi-Yip Ho, Yunchen Gong, Kin Chan, Elisabeth Tillier and Emma Master (Univ. of Toronto)
A white-rot fungus, Phanerochaete carnosa, is a natural decomposer of coniferous wood and has an ability to degrade various types of softwood and hardwood tissues. While proteins produced by P. carnosa are expected to comprise promising enzymes for bioprocessing lignocellulose including fibre from coniferous wood, genome sequencing revealed that a large contingent of likely relevant proteins remain uncharacterized. Here, we performed gene expression cluster analysis using multiple P. carnosa transcriptomes obtained at different stages of fungal growth on trembling aspen and white spruce. The results revealed co-expression pairs and clusters of known lignocellulolytic genes associated with genes of unknown functions (UNKs), suggesting participation of those unknowns in the lignocellulolytic system of this fungus.
P-68
AmyR MalR
AmyR
MalR 2
AmyR MalR 1AmyR MalR
AmyR MalR thiA AmyR
MalR
AmyR MalRMalR AmyR
AmyR phosphatasePhos-tag SDS-PAGE
1 12 p.57
Post-translational modification and stability of transcription factors, AmyR and MalR, in Aspergillus oryzae.
Kuta Suzuki, Mizuki Tanaka, Takahiro Shintani, Katsuya Gomi (Div. Biosci. Biotechnol. Future Bioind., Grad. Sch. Agric. Sci., Tohoku Univ)
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73 —
P-69 pH PacC
1 2 1 1 1 1 1 2
Aspergillus nidulans pH PalC
PalC C2H2 PacCPalC PacC
pacC pH (pH 4.2) (pH 8.2)
qRT-PCRΔpacC
eglAPacC pH PacC eglA
qRT-PCRPacC
RNA-seq ManRΔpacC PacC
TLC ΔpacCPacC ManR
pH
The pH-signaling transcription factor PacC regulates expression of cellulase genes in Aspergillus nidulans.
Emi Kunitake1, Daisuke Hagiwara2, Kentaro Miyamoto1, Kyoko Kanamaru1, Makoto Kimura1, Tetsuo Kobayashi1
(1Graduate Sch. of Bioagric. Sci., Nagoya Univ., 2MMRC, Chiba Univ.)
P-70
xyrA larA XlnR AraR
XlnR AraR Aspergillus Zn(II)2Cys6
xyrA larA XlnR AraR
XlnR AraR DNA xyrA larADNA EMSA xyrA XlnR 2
5’-GGCTAA-3’ AraR 5’-CGGGTAAA-3’60 bp XlnR AraR 11 bp larA
AraR 3 XlnR 5’-GGATAA-3’1 AraR 40bp XlnR
AraR XlnR AraRXlnR AraR
xyrA larA
Co-regulation of A. oryzae xyrA and larA expression by XlnR and AraR
Kana Ishikawa, Tomomi Kawase, Yuji Noguchi, Kyoko Kanamaru, Makoto Kimura, Tetsuo Kobayashi
(Graduate Sch. of Bioagric. Sci, Nagoya Univ)
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74 —
P-71 Aspergillus aculeatus ClbR ClbR2
Aspergillus aculeatus cellobiose
response regulator (ClbR) XlnR ClbR
ClbR XynIa Yeast Two Hybrid (Y2H)
ClbR ClbR 42% ClbR2 C (ClbR21-295) clbR2 clbR
ClbR2 ClbR ManR ClbR FIa-xylanase (xynIa), FIb-xylanase (xynIb)
ClbR in vitro DNA ClbR (MalE-ClbRwhole)
xynIa Electrophoresis mobility shift assayY2H ClbR ClbR2 C
(MalE-ClbR21-295) ClbR ClbR2 xynIa manR
Functional analysis of cellobiose response regulator (ClbR) and its paralog (ClbR2) in Aspergillus aculeatus.
Ayano Kawamura, Emi Kunitake, Shuji Tani, Jun-ichi Sumitani, Takashi Kawaguchi
(Grad. Sch. Life & Env. Sci., Osaka Pref. Univ.) P-72 Molecular basis that divides ManR-dependent and ManR/McmA-dependent genes in Aspergillus nidulans Nuo Li, Miki Aoyama, Kyoko Kanamaru, Makoto Kimura, Tetsuo Kobayashi
(Grad. Sch. Bioagric. Sci., Nagoya Univ.) Fungal hydrolytic gene expression is tightly controlled at the transcription level. Besides the traditional XlnR-dependent mechanism, a novel McmA-ManR mechanism involved in regulation of cellulolytic and hemicellulolytic genes has been identified recently. Both transcription factors are essential to inductive expression of eglA, encoding endoglucanase A, because ManR requires McmA for binding to CeRE (Cellulose Responsive Element) on the promoter. Based on RNA sequencing analysis, highly expressed cellulolytic genes are under control by both McmA and ManR (ManR/McmA dependent). But at the same time a number of genes are ManR-dependent but not McmA-dependent (ManR-dependent). The ManR-dependent genes include some mannanolytic and xylanolytic genes. In this report, we confirmed the requirement of McmA for ManR-binding using the promoter of eglB, another endoglucanse gene, and also examined whether ManR without McmA could bind the promoter of the ManR-dependent gene mndB encoding β-mannosidase. Binding of His-tagged McmA and Flag-tagged ManR DNA binding domain to various probes were examined by EMSA. When binding to the eglB was examined results similar to eglA were obtained. ManR did not bind to the promoter in the absence of McmA, while it bound to CeRE containing DNA fragments in its presence. McmA alone could bind to various locations on the promoter, but CeRE was required for recruitment of ManR. This implies ManR not only binds to McmA but also to DNA. In contrast, ManR could bind to the mndB promoter in the absence of McmA. Since no CeRE-like sequence exists on the promoter, it appeared that ManR recognized a sequence different from CeRE. Further study will focus on the identification of the binding site for ManR on the mndB promoter. This work was supported by the Programme for Promotion of Basic and Applied Research for Innovation in Bio-oriented Industry.
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75 —
P-73 Aspergillus niger PKS-NRPS
Aspergillus niger polyketide synthase – non-ribosomal peptide synthase (PKS-NRPS)
PKS-NRPS An11g00250 (pynA) (pyn ) PynpynR PynR GAL4
A. niger ATCC 1015 PEG- pynRgpdA promoter pynR
pyn RT-PCRpynR pynA
pynaga pynR
NMR MS pyranonigrin E
Expression of the dormant PKS-NRPS gene cluster in Aspergillus niger
Takayoshi Awakawa, Xiao-Long Yang, Toshiyuki Wakimoto, Ikuro Abe
(Grad. School of Pharm. Sci., Univ. of Tokyo)
P-74
Tri6
Fusarium graminearum
Tri Tri6Tri10 Tri5
Tri4 Tri6 Tri TRI6Tri6
Tri6 Tri6_nsm Tri6_nsm Tri6Tri6_nsm Tri6_nsm
Tri6_nsm TRI6Tri6::GFP Tri6_nsm
Tri6 TRI10 TRI6 zinc finger GFPTRI10 TRI6 TRI10
Tri Tri6Tri TRI6
Functional analysis of Tri6 that encodes a transcriptional factor for trichothecene biosynthesis. Yuichi Nakajima, Yoshiyuki Kito, Kazuyuki Maeda, Hinayo Ichikawa, Tetsuo Kobayashi, Makoto Kimura (Graduate Sch. of Bioagric. Sci., Nagoya Univ.)
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76 —
P-75
ACATE Eg5
E
Chaunopycnis alba RK99-F33
C6
LaeA p38 MAPKLaeA Lae1
LaeA
Production control mechanism of terpendole mycotoxins
Takayuki Motoyama, Hiroyuki Osada
(Antibiotics Lab., RIKEN) P-76
1 DMSO
p38 MAP OSM1LaeA
LaeA LAE1 DMSODMSO p38 MAP
OSM1 LAE1DMSO p38 MAP LAE1
Bioactivity of tenuazonic acid and its production control mechanism in Magnaporthe oryzae.
Choong-Soo Yun, Takayuki Motoyama, Yusi Hutamura, Hiroyuki Osada
(Antibiotics Lab., RIKEN)
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77 —
P-77 (O-3) Aospt3
1,2 1,2 1,2 1 2
Aospt3secondary metabolites SMs
SMs Aospt3 SMs SMs ΔAospt3
(kojA kojR kojT) 100Aospt3
SMs laeAAospt3 laeA ΔAospt3 laeA
ΔAospt3ΔlaeAΔlaeA
Aospt3 laeA ΔlaeAspt3 ΔAospt3 laeA
Aospt3 laeA
Functional analysis of Aospt3 secondary metabolic regulator
Masato Hirose , Moriyuki Kawauchi, Kazuhiro Iwashita
(Hiroshima Univ, NRIB)
P-78 Emericella variecolor
Emericella variecolor II
variecolin ophiobolin astellatol variculanolE. variecolor
E. variecolor Aspergillus
clavatus ophiobolin F synthase (AcOS) 3 AcOS
Phomopsis amygdali fusicoccadiene synthase
Aspergillus oryzae
The search for sesterterpene synthases from Emericella variecolor Takaaki Mitsuhashi, Yudai Matsuda, Takayoshi Awakawa, Ikuro Abe
(Graduate School of Pharmaceutical Sciences, Univ. of Tokyo)
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78 —
P-79 anditomin
Aspergillus variecoloranditomin [2,2,2]Diels-Alder
anditomin anditominDiels-Alder Diels-Alderase
anditomin 13
25
5 Aspergillus oryzae
7 5Diels-Alderase
Biosynthetic studies on a fungal meroterpenoid anditomin
Yudai Matsuda, Takayoshi Awakawa, Ikuro Abe
(Graduate School of Pharmaceutical Sciences, Univ. of Tokyo) P-80 Aspergillus fumigatus pseurotin A
Pseurotin A Aspergillus fumigatus immunoglobulin
E
2007Turner A. fumigatus polyketide synthase - non-ribosomal peptide synthetase (Afu8g00540) pseurotin A
Aspergillus oryzaepTAex3 pUSA pAdeA pPTRI
AmyB Afu8g00540 hydrolase (Afu8g00530 Afu8g00570) P450(Afu8g00560) methyl transferase (Afu8g00550) A. oryzae NSAR1
Functional analysis of pseurotin A biosynthetic gene cluster in Aspergillus fumigatus
Koichiro Shiomura, Yudai Matsuda, Takayoshi Awakawa, Ikuro Abe
(Grad. School of Pharm. Sci., Univ. of Tokyo)
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79 —
P-81 Fusarium sp. FN080326 A
1 Jun-Pil JANG2 Jae-Hyuk JANG2 1 Jong Seog AHN2 1
1 CSRS 2KRIBB
A Fusarium sp. FN080326Fusarium
PKS-NRPS
FN080326
PKS-NRPS 1eqxS Kakule TB, et al. 2013 ACS Chem Biol
8:1549-1557 eqxfsa
fsa P450 fsa9
Identification of fusarisetin A biosynthetic gene cluster of Fusarium sp. FN080326 Naoki Kato1, Jun-Pil Jang2, Jae-Hyuk Jang2, Shunji Takahashi1, Jong Seog Ahn2, Hiroyuki Osada 1 (1RIKEN CSRS, 2KRIBB)
P-82 Fusarium sp. RK97-94
luc1 luc4 1,2, 1, 1, 2, 2 1 2
(1) Fusarium sp. RK97-94
p53 1NG-391(2) 1 2 PKS-NRPS luc5
8 1luc1 luc4
luc4 2
1 Luc4 1
1 2 Luc4luc1 1
2 1 (3) Luc12
1
Functional analysis of the methyltransferase gene luc1 and the transporter gene luc4 in the lucilactaene
biosynthesis gene cluster of the producing fungus Fusarium sp. RK97-94
Sho Kato1,2, Takayuki Motoyama1, Hiroshi Hirota1, Takashi Kamakura2, Hiroyuki Osada1
(1Antibiotics Lab., RIKEN, 2Tokyo Univ. of Sci.)
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80 —
P-83 hstD
1 2 2 1 2 (1 2 )
Histone deacetylase sirtuin hstD laeAhstD
LC-Q/TOF-MS hstD 4 RNA
Control ΔhstD 5% 2228 160
PKS NRPSFungiFun FunCat
[secondary metabolism] [detoxification]
hstD 4 SM(methanol : dichloromethane : ethyl acetate=1:2:3 1% formic acid)LC-Q/TOF-MS
hstD
Activation of secondary metabolism in the hstD disruptant of Aspergillus oryzae.
Moriyuki Kawauchi1 2 Rieko Toyoura 2 Kazuhiro Iwashita1 2
(1 Grad. Sch. Adv. Sci. Mat., Hiroshima Univ., 2 NRIB)
P-84 Aspergillus oryzae III CsyB
3-acetyl-6-alkyl- α-pyrone
1 1 1 1 2 1
III CsyB A. oryzae3-acetyl-α-pyrone csypyrone B (CPB) CPB fatty acyl-CoA
pre CPBin vitro
csyB pET22b BL21(DE3) HPLC C15
6 pre CPB in vitro pColdTF Ni-NTA
butyryl-CoA malonyl-CoA acetoacetyl-CoA C3pre CPB (pre CPB-C3) hexanoyl-CoA
octanoyl-CoA pre CPB-C5 -C7CsyB fatty acyl-CoA malonyl-CoA acetoacetyl-CoA 3-acetyl-6-alkyl-α-pyrone
Production of 3-acetyl-6-alkyl-α-pyrones by a type III polyketide synthase CsyB from Aspergillus oryzae
Makoto Hashimoto1, Hiroaki Takahashi1, Tsukasa Koen1, Chihiro Suda1, Katsuhiko Kitamoto2, Isao Fujii1
(1School of Pharmacy, Iwate Medical Univ., 2Dept. of Biotechnol., The Univ. of Tokyo)
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81 —
P-85 DNA
1 1 1 2 1 (1 2 )
DNA (DSBs) 1 (NHEJ)
DSBs (HR) 18 I-SceI ,
DSBs ,DSBs HR ( 24) DSBs (GT)
, Zinc finger nucleases (ZFNs) DSBs ,
HR GT 1 Scytalone dehydratase (SDH) 2 ZFNs GT
ZFNs SDH 163 bp 412 bp 18 bpZFN 2A
GT 5 %ZFNs 10 HR
,DSBs HR DNA double-strand breaks mediated targeted gene replacement in the rice blast fungus
Tetsuya Younomaru1, Takayuki Arazoe1, Shuichi Ohsato1, Tsutomu Arie2, Shigeru Kuwata1
(1Sch. Agric., Meiji Univ., 2Grad. Sch. Agric. Sci., Tokyo Univ. of Agric. & Tech.)
P-86 Roxithromycin
(Magnaporthe oryzae),
,
, ,14 Roxithromycin(RXM)
, RXM, , RXM
, RXM ,T7 RXM ,CDC27
, ,RXM , ,
RXM ,,RXM ,
RXM ,
A Possible alternative Target of Roxithromycin in Fungi
Mayu Kumasaka, Akira Ishii, Shinji Kamisuki, Kouji Kuramochi, Fumio Sugawara, Megumi Narukawa-Nara,
Takashi Kamakura
(Dept. of Applied Biological Sci., Tokyo Univ. of science)
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82 —
P-87 cAMP
,
cAMP
(Cochliobolus heterostrophus)A(PKA)
PKA (PKR)cAMP
(Cyclase associated protein: CAP)CAP (CAP1)
cAMP
CAP1 CAP1
CAP1PKA1 PKA2 PKR
(PDEL PDEH) cAMP
Characterizations of cAMP signaling pathway associated genes of Cochliobolus heterostrophus
Satoshi Yutani, Takuya Sumita, Yuuki Kitade, Kousuke Izumitsu, Chihiro Tanaka
(Grad. School of Agriculture, Kyoto Univ. )
P-88 Aspergillus fumigatus
,
A. fumigatusA. fumigatus
A. fumigatus
A. fumigatus
dectin1 TLR4
Functional analysis of pathogen related factor in Aspergillus fumigatus.
Kanae Sakai, Motoko Oarada, Tohru Gonoi
(MMRC, Univ. of Chiba)
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83 —
P-89 A. fumigatus
1 2 3 2 1 2 3 Aspergillus fumigatus
A. fumigatus
A. fumigatus 44 ( )2 RNA 4
(illumina Miseq) 1. partitivirus 2. chrysovirus 2 3. 4.
A. fumigatus
Isolation and characterization of four types of Mycoviruses in opportunistic pathogen Aspergillus fumigatus Misa Yahara1, Azusa Takahashi-Nakaguchi2, Hiromitu Moriyama3, Tohru Gonoi2 (1Grad. School of Medical and Pharm. Sci., Chiba Univ., 2MMRC, Chiba Univ., 3Tokyo Univ. of Agric. & Tech.)
P-90
3 G 1, 2 1 2 1 2
α β γ G
Gα GβγGγ Gβ
G cAMPGγ ΔGγ
Gβ ΔGβ, Nishimura et al., 2003 Gβγ
GFP Gβ GFP: GβGFP: Gβ ΔGγ
Gγ GβΔGγ ΔGβ 0 cAMP 50
ΔGβ ΔGγ ΔGγΔGβ 10%
ΔGγ ΔGβΔGγ ΔGβ Gβγ
Gβγ
Analyses on a heterotrimeric G-protein γ subunit in Magnaporthe oryzae
Shizuka Kazama1, 2 Hisashi Kawasaki1 Marie Nishimura2 1Tokyo Denki Univ. 2NIAS
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84 —
P-91 ChSte20 ChCla4
1 2 1 1 1 1 2
Chk1 MAP
Chk1 MAP PAK-likeSte20 Cla4 ChSte20
ChCla4 ChSte20ChCla4
ChSte20 ChCla4ChSte20 ChCla4
ChSte20 ChCla4PAK-like
ChCla4ChSte20
Characterization of ChSte20 and ChCla4 genes in Cochliobolus heterostrophus
Yuki Kitade1, Kosuke Izumitsu2, Takuya Sumita1, Satoshi Yutani1, Chihiro Tanaka1
(1Grad. Sch. of Agriculture, Kyoto Univ., 2Sch.of Environmental Science,Univ. of Shiga Pref.)
P-92 Ras GTPase CoIra1 CoRas2
cAMP CoMekk1-Cmk1 MAPK
Ras GTPase CoIRA1 CoIra1
, Ira1/2 Ras1/2 cAMP , coira1 cAMP, coira1 cAMP ,CoIra1 cAMPCoIRA1 CoRAS2 coras2 ,
, coras2 ,CoRAS2,CoRas2 CoRAS2 RFP ,CoRas2, CoRas2 , CoRAS2
, coira1 CoRas2CoIra1 CoRas2 , CoRas2 CoMekk1-Cmk1
MAPK CoRAS2 CoMEKK1Δcoras2 CoMEKK1 , , Δcomekk1
CoRAS2 ,CoRas2 CoMekk1-Cmk1CoIra1 CoRas2 cAMP CoMekk1-Cmk1
MAPK
Ras GTPase activating protein CoIRA1 is involved in cAMP signaling transduction pathway and
CoMekk1-Cmk1 MAPK pathway as an upstream regulatory factor in Colletotrichum orbiculare.
Ken Harata Yasuyuki Kubo
(Life and Environmental Science, Univ. of Kyoto Prefectual)
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85 —
P-93 MoCV1 MoCV1-B
( ) Magnaporthe oryzae chrysovirus 1 (MoCV1) 5 dsRNA
MoCV1Magnaporthe oryzae chrysovirus 1-B (MoCV1-B) MoCV1
ORF3(dsRNA3 ) ORF4(dsRNA4 ) 83kDa, 85kDa 58kDa, 70kDa MoCV1
MoCV1-B MoCV1MoCV1-B dsRNA1(79.6%), dsRNA2(76.3%), dsRNA3(71.3%), dsRNA4(72.4%), dsRNA5(96.2%) ORF1(92.5%), ORF2(80.1%), ORF3(87.8%), ORF4(89.4%), ORF5(97.1%) ORF2 N ( 200aa) 51.1% ORF3
C ( 200aa) 34.1 CORF1, ORF4 OFR3, ORF4
Comparison of genome structures between Magnaporthe oryzae chrysovirus 1 and Magnaporthe oryzae
chrysovirus 1-B
Ryoko Takai, Syun-ichi Urayama, Hirofumi Sakoda,Yu Katoh, Yuri Kimura, Toshiyuki Fukuhara, Tsutomu Arie,
Tohru Teraoka, Hiromitsu Moriyama (Faculty of Agriculture, Tokyo Univ. of Agri. & Tech)
P-94 Alternaria alternata global regulator LaeA
1 1 2 1 2 3 1 1 2
3 methyltransferase LaeA Aspergillus nidulans global regulator
(Alternaria alternata tomato pathotype, ) LaeA
AaLAEA . (A. alternata strawberry pathotype) (A. alternata apple pathotype) LaeA (KO)
A. alternata 3. KO
LaeA
Functional analysis of the global regulator LaeA homologues in the plant pathogenic Alternaria alternata
Kazumi Takao1, Yasunori Akagi1, Yoshiaki Harimoto2, Toru Ishihara1, Takashi Tsuge2, Eiji Nanba3, Motoichiro
Kodama1
(1Fac. Agric., 3Fac. Medicine, Tottori Univ., 2Grad. Sch. Bioagric. Sci., Nagoya Univ.)
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86 —
P-95 BcAtg1
1 2 1 1 2
Botrytis cinerea
Saccharomyces cerevisiaeAtg1 BcAtg1
BcAtg1BcAtg1
BcAtg1BcAtg1
BcAtg1
Characterization of the autophagy-related gene BcAtg1 in Botrytis cinerea
Takuya Sumita1, Kosuke Izumitsu2, Chihiro Tanaka1
(1Grad. Sch. of Agriculture, Kyoto Univ., 2Sch. of Environmental Science, Univ. of Shiga Pref.)
P-96 (O-5) RAM CoPag1
CoKEL2cokel2Δ
CoKEL2 6
RAM (regulation of Ace2p activity and cellular morphogenesis)Pag1 (Tao3) CoPAG1 copag1Δcokel2Δ
CoPAG1CoPag1::RFP
CoPag1::RFP
Colletotrichum orbiculare CoPag1, a component of RAM network in Saccharomyces cerevisiae, is involved in
appressorium development triggered by plant-derived signals
Sayo Kodama, Ayumu Sakaguchi, Yasuyuki Kubo
(Graduate School of Life and Environmental Sciences, Kyoto Prefectural Univ.)
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87 —
P-97
1 2 3 4 1
1 2 3 4
(Alternaria alternata tomato pathotype) AALGiberella
AALALT FUM
ALT AALALT 1 Mb conditionally dispensable
chromosome (CDC) CDC CDCCDC optical mapping rare cutting enzyme (NotI)
RFLP (isochromosome) CDC FISH
CDC
Structural analysis of a pathogenicity chromosome in Alternaria alternata tomato pathotype.
Yasunori Akagi1, Masatoki Taga2, Takashi Tsuge3, Eiji Nanba4, Motoichiro Kodama1
(1Fac. Agric., 4Fac. Medicine, Tottori Univ., 2Fac. Sci., Okayama Univ., 3Grad. Sch. Bioagric. Sci., Nagoya Univ.)
P-98 RTS1 CoRTS1
, , ,
, spindle position checkpoint (SPOC) 1
BUB2 CoBUB2 , G1 / S, Bub2 RTS1 CoRTS1 Rts1
SPOC , , rts1RTS1
corts1 , , , ,
, , corts1 CoRTS1::GFP ,
, CoRts1 CoRTS1corts1 , , ,
CoRTS1,
CoRTS1, the homolog of Saccharomyces cerevisiae RTS1 regulating septin dynamics, is required for proper
conidiation and appressorium formation in Colletotrichum orbiculare.
Kou Kawabata, Fumi Fukada, Ayumu Sakaguchi, Yasuyuki Kubo
(Graduate School of Life and Environmental Sciences, Kyoto Prefectural Univ.)
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88 —
P-99 Enoyl-CoA hydratase
ATMTColletotrichum orbiculare Path-1 TAIL PCR Path-1
enoyl-CoA hydrataseCoEch1 CoEch1
CoEch1CoEch1 PDA
CoEch1
CoEch1 CoEch1-GFPCoEch1-GFP Mitotracker
Enoyl-CoA hydratase CoEch1 is essential for pathogenicity of Colletotrichum orbiculare
Kosuke Izumitsu, Yasuka Tatara, Kaori Komatsu, Aya Yokoyama, Takuya Taniguchi, Mami Maruyama, Toshikazu
Irie, Kazumi Suzuki (Sch. of Environmental Science, Univ. of Shiga Pref.)
P-100 CoTEA4 CoMOD5
2TEA1 CoKEL2 Tea1
Tea1 Tea4 Mod5CoTEA4 CoMOD5 cotea4
comod5 cotea4cokel2
CoTEA4
Functional analysis of putative cell polarity factors, CoTEA4 and CoMOD5, from Colletotrichum orbiculare
Midori Kawashimo, Ayumu Sakaguchi, Yasuyuki Kubo, Gento Tsuji
(Grad.sch.of Life and Environ. Sci.of Kyoto Prefectural Univ.)
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89 —
P-101 terretonin
Aspergillus terreus terretonin farnesyl
terretoninterretonin D
terretonin Aspergillus oryzaeterretonin
terretonin Trt9 short chain dehydrogenase Trt3 FAD-dependent monooxygenase 5
preterretonin A preterrenoidterrenoid
Trt6 P450 Trt7 non-heme iron-dependent dioxygenase Trt14 hypothetical protein
Functional analysis of the tailoring enzymes involved in the biosynthesis of a fungal meroterpenoid terretonin
Taiki Iwabuchi, Yudai Matsuda, Takayoshi Awakawa, Ikuro Abe
(Graduate School of Pharmaceutical Sciences, Univ. of Tokyo)
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90 —
----------- B -------------- Ba Van Vu 37 Bernard Henrrissat 40 ----------- C ------------ Chi-Yip Ho 72 ----------- D ------------ Dan Cullen 40 David Hibett 40 Dung Huy Hoang 48 ----------- E ------------ Elisabeth Tillier 72 Emma Master 72 ----------- F ------------ Feng Jie JIN 57 ----------- G ------------ Gerhard H. Braus 53 ----------- J ------------ Jae-Hyuk JANG 79 Jill Gaskel 40 Jong Seog AHN 79 Jun-Pil JANG 79 ----------- K ------------ Kenneth Bruno 48 Kieu Pham Thi Minh 37 Kin Chan 71 ----------- N ------------ Nuo Li 74 ----------- O ------------ Özgür Bayram 53 Özlem Sarikaya Bayram 53 ----------- P ------------ Pei HAN 57 Philip Wong 72 ----------- Q ------------ Quoc Bao Nguyen 37 ----------- S ------------ Scott Baker 48 ----------- Y ------------ Yunchen Gong 72 ----------- ------------
70, 74 5, 87
43
41 39, 41, 44, 46,
47, 61, 67 74, 77, 78a,78b,
89 62
65 32, 66 61 81
81, 85 75, 77, 78a, 78b,
89 34
46 ----------- ------------
14, 40, 41, 68
29,37, 55 81
48 65 42, 71, 82, 84,
86, 88 41
30 66
56 73
85 33, 62 34 75 69 34, 42 45
46, 47 29, 55
37 71, 88 38 30, 35, 44, 52,
77, 80 89
----------- ------------ 44 65 67
43 48 44 85 29, 55
----------- ------------
64
32, 40 ----------- ------------
47 49
82 57
81 33, 60 63
35 38
52, 59 45
68 64
31, 33, 60, 70 41 18
62, 63 46
43 21
34 64 76a, 76b, 79a,
79b 52, 59
35, 44 46
----------- ------------
43 83 68
45 53 67
79 79 59, 60, 69
85 52, 59 69 29, 55 70, 73a, 73b, 74 79, 81 58 81
34 54
44 30, 77, 79 41, 47 55 71, 74
83
88 73 29, 56
87 74
38 ----------- -------