2024年
Yoshida J*, Tajika Y, Uchida K, Kuwahara M, Sano K, Suzuki T, Hondo E, Iida A*.
Membrane molecule, bouncer regulates sperm binding activity in immature oocytes in a viviparous teleost species Poecilia reticulata (guppy).
Development, Growth & Differentiation in press
(胎生真骨魚グッピーにおける膜分子バウンサーを介した未熟卵と精子の結合活性の調節)
Hondo E*, Katta T, Sato A, Kadofusa N, Ishibashi T, Shimoda H, Katoh H, Iida A. (2024)
Antiviral effects of micafungin against pteropine orthoreovirus, an emerging zoonotic virus carried by bats.
Virus Research 339:199248
(コウモリが媒介するコウモリオルソレオウイルスに対するミカファンギンの抗ウイルス効果)
2023年
Sakaki S, Ito R, Abe H, Kinoshita M, Hondo E, Iida A*. (2023)
Electric organ discharge from electric eel facilitates DNA transformation into teleost larvae in laboratory conditions.
PeerJ 11:e16596
(デンキウナギの発電器官からの放電による、実験室条件での硬骨魚類の幼魚への DNA導入の促進)
Iida A*, Tsuda N, Yoshida J, Nomura J, Ratanayotha A, Kawai T, Hondo E. (2023)
Glucose absorption activity and gene expression of sugar transporters in the trophotaenia of the viviparous teleost Xenotoca eiseni
Biochimica et Biophysica Acta – General Subjects 1867: 130464.
(胎生硬骨魚 Xenotoca eiseni の栄養リボンにおけるグルコース吸収活性と糖トランスポーターの遺伝子発現)
Mitparian T, Kettratad J, Kangwanrangsan N, Ampawong S, Kaneko G, Iida A, Senarat S, Charoenphon N *. (2023)
Brain structure and ultrastructure of the gonadotropic cell in the female grunting toadfish, Allenbatrachus grunniens (Linnaeus 1758)
Agriculture and Natural Resources 57, 281-288.
(ガマアンコウ目Allenbatrachus grunniensメス個体の脳構造およびゴナドトロピン分泌細胞の微細構造)
Kongthong K, Charoenphon N, Thaochan N, Boonyoung P, Iida A, Jeamah A, Imsonpang S, Wongkhamhaeng K, Senarat S*. (2023)
A modified histological method for marine invertebrates.
Veterinary Integrative Sciences 21, 251-263.
(海産無脊椎動物の組織学的手法の改良)
Nomura J, Yokoi H, Hondo E, Iida A*. (2023)
Vitellogenin uptake activity in the intestinal ducts of intraovarian embryos in a viviparous teleost Xenotoca eiseni.
Biochemical and Biophysical Research Communications 644, 79-84
(胎生真骨魚Xenotoca eiseniの卵巣内胚の消化管におけるビテロジェニン吸収能)
2022年
Kimprasit T*, Kumla S, Sirilaophaisan S, Hondo E, Iida A, Kaewpila C. (2022)
Prevalence and Characteristic of Extended Spectrum Beta-lactamase producing Escherichia coli Isolated from Flies in Rural Sakon Nakhon, Thailand.
Agriculture and Natural Resources 056:1069-1076
(タイのサコンナコン農村部のハエから分離された基質拡張型β-ラクタマーゼ産生大腸菌の有病率と特徴)
Iida A*, Nomura J, Yoshida J, Suzuki T, Yokoi H, Hondo E. (2022)
Endocytosis-mediated vitellogenin absorption and lipid metabolism in the hindgut- derived placenta of the viviparous teleost Xenotoca eiseni
Biochimica et Biophysica Acta - Molecular and Cell Biology of Lipids 1867, 159183
(胎生真骨魚Xenotoca eiseniの栄養リボンにおけるエンドサイトーシス依存的なビテロジェニンの吸収と脂質代謝)
Hayashi S, Tsukiyama T, Iida A, Kinoshita M, Koga A*. (2022)
The medaka fish Tol2 transposable element is in an early stage of decay: identification of a nonautonomous copy
Genome 65, 183-187
(メダカのTol2トランスポゾンは崩壊の初期段階にある:非自律的コピーの同定)
2021年
Iida A*, Nakai R, Yoshida J, Sano K, Hondo E. (2021)
Expression and antimicrobial activity of liver-expressed antimicrobial peptides in the ovaries of the viviparous teleost Xenotoca eiseni.
Fish and Shellfish Immunology 118, 405-410.
(胎生真骨魚Xenotoca eiseniの卵巣におけるLEAP抗菌ペプチドの発現と抗菌活性)
Tarigan R, Katta T, Takemae H, Shimoda H, Maeda K, Iida A, Hondo E*. (2021)
Distinct interferon response in bat and other mammalian cell lines infected with pteropine orthoreovirus
Virus Genes, in press
(コウモリオルソレオウイルスに感染したコウモリ細胞および他の哺乳類細胞におけるインターフェロン応答)
Iida A*, Sano K, Inokuchi M, Suzuki T, Kuriki M, Sogabe M, Susaki D, Tonosaki K, Kinoshita T, Hondo E. (2021)
Cubam receptor-mediated endocytosis in hindgut-derived pseudoplacenta of a viviparous teleost Xenotoca eiseni
Journal of Experimental Biology 224, jeb242613.
(胎生魚Xenotoca eiseniの栄養リボンでのCubam受容体を介したエンドサイトーシス)
Iida A, Takemae H, Tarigan R, Kobayashi R, Kato H, Shimoda H, Omatsu T, Supratikno, Basri C, Mayasari NLPI, Agungpriyono S, Maeda K, Mizutani T, Hondo E*. (2021)
Viral-derived DNA invasion and variation in Indonesian population of large flying fox Pteropus vampyrus.
Journal of Veterinary Medical Science 83, 1068-1074.
(ジャワオオコウモリPteropus vampyrusへのウイルス由来DNAの侵入とその多様性)
Iida A*, Nakai R†, Nomura J†, Tanaka R, Mizuno N, Kurobe M, Hondo E. (2021)
Sharply angled lateral curvature modification in anal fin of a viviparous fish, Xenotoca variata (Cyprinodontiformes: Goodeidae)
Zoological Science 38, 67-71.
(胎生魚Xenotoca variataのオスで見られる尻ビレの側方湾曲)
Iida A*, Nomura J, Hondo E. (2021)
Histological observation of the reproductive system in a viviparous teleost Xenotoca eiseni Rutter 1896 (Cyprinodontiformes: Goodeidae).
Anatomia, Histologia, Embryologia 50, 161-168.
(胎生魚Xenotoca eiseniの生殖系の組織学的観察)
Kimprasit T†, Nunome M†, Iida K, Murakami Y, Wong ML, Wu CH, Kobayashi R, Hengjan Y, Takemae H, Yonemitsu K, Kuwata R, Shimoda H, Si L, Sohn JH, Asakawa S, Ichiyanagi K, Maeda K, Oh HS, Mizutani T, Kimura J, Iida A, Hondo E*. (2021)
Dispersal history of Miniopterus fuliginosus bats and their associated viruses in east Asia.
PLOS ONE 16, e0244006.
(東アジアにおけるユビナガコウモリMiniopterus fuliginosusおよび関連するウイルスの分散過程)
2020年
Tarigan R, Shimoda H, Doysabas KCC, Maeda K, Iida A, Hondo E*. (2020)
Role of Pattern Recognition Receptors and Interferon-beta in protecting bat cell lines from Encephalomyocarditis virus and Japanese encephalitis virus infection.
Biochemical and Biophysical Research Communications 527, 1-7.
(コウモリ細胞へのウイルス感染防御におけるパターン認識受容体とインターフェロンβの役割)
Aoyama A, Doysabas KCC, Iida A, Hondo E*. (2020)
Innervation of the wing membrane in the bent-winged bat Miniopterus fuliginosus.
Anatomia, Histologia, Embryologia 49, 681-685.
(ユビナガコウモリMiniopterus fuliginosusの皮膜の神経支配)
Iida A*†, Wang Z†, Hondo E, Sehara-Fujisawa A. (2020)
Generation and evaluation of a transgenic zebrafish for tissue-specific expression of a dominant-negative Rho-associated protein kinase-2.
Biochemical and Biophysical Research Communications 525, 8-13.
(標的組織特異的にROCK2のドミナントネガティブを発現可能な遺伝子組み換えゼブラフィッシュの樹立と評価)
Doysabas KCC, Oba M, Ishibashi T, Shibata H, Takemae H, Shimoda H, Tarigan R, Mizutani T, Iida A, Hondo E*. (2020)
ATeam technology for detecting early signs of viral cytopathic effect.
Journal of Veterinary Medical Science 82, 387-393.
(ウイルス感染による細胞変性効果の早期検出のためのATeamテクノロジーの検討)
2019年
Iida A*, Arai HN, Someya Y, Inokuchi M, Onuma TA, Yokoi H, Suzuki T, Hondo E, Sano K. (2019)
Mother-to-embryo vitellogenin transport in a viviparous teleost Xenotoca eiseni.
Proceedings of the National Academy of Sciences of the United States of America 116, 22359-22365.
(胎生魚Xenotoca eiseniにおけるビテロジェニンの母仔間輸送)
Iida A*, Wang Z, Sehara-Fujisawa A. (2019)
A disruption of integrin α4 in zebrafish that leads to cephalic hemorrhage during development.
Genes & Genetic Systems 94, 117-119.
(ゼブラフィッシュにおけるインテグリンα4の欠損は発生期の頭部出血を招く)
Tanaka S, Senda N, Iida A, Sehara-Fujisawa A, Ishii T, Sato F, Toi M, Itou J*. (2019)
In silico analysis-based identification of the target residue of integrin α6 for metastasis inhibition of basal-like breast cancer.
Genes to Cells 24, 596-607.
(乳癌細胞の転移抑制に効果的なインテグリンα6標的配列のin silico解析に基づいた同定)
Rho SS, Kobayashi I, Oguri-Nakamura E, Ando K, Fujiwara M, Kamimura N, Hirata H, Iida A, Iwai Y, Mochizuki M, Fukuhara S*. (2019)
Rap1b promotes notch signal-mediated hematopoietic stem cell development by enhancing integrin-mediated cell adhesion.
Developmental Cell 49, 1-16.
(Rap1bはインテグリンによる細胞接着を増強することでNotchシグナルを介した造血幹細胞発生を促進する)
Iida A*. (2019)
Male-specific asymmetric curvature of anal fin in a viviparous teleost, Xenotoca eiseni.
Zoology 134, 1-7.
(胎生魚Xenotoca eiseniで見られるオス特異的な尻ビレの左右非対称構造)
Gunawan F, Gentile A, Fukuda R, Tsedeke AT, Jimenez-Amilburu V, Ramadass R, Iida A, Sehara-Fujisawa A, Stainier D*. (2019)
Focal adhesions are essential to drive zebrafish heart valve morphogenesis.
The Journal of Cell Biology 218, 1039-1054.
(ゼブラフィッシュの心臓弁形成では接着斑が重要な役割を担う)
2018年
Iida A*, Wang Z, Hirata H, Sehara-Fujisawa A. (2018)
Integrin β1 activity is required for cardiovascular formation in zebrafish.
Genes to Cells 23, 938-951.
(ゼブラフィッシュの心血管系の構築にはインテグリンβ1の活性が必要である)
2017年
Itou J*, Tanaka S, Li W, Iida A, Sehara-Fujisawa A, Sato F, Toi M. (2017)
The Sal-like 4 - integrin α6β1 network promotes cell migration for metastasis via activation of focal adhesion dynamics in basal-like breast cancer cells.
Biochimica et Biophysica Acta - Molecular Cell Research 1864, 76–88.
(SALL4-インテグリンα6β1経路は接着班の活性化を介して乳癌の転移能を制御する)
2016年
Inoue T†, Iida A†, Maegawa S, Sehara-Fujisawa A, Kinoshita M*. (2016)
Generation of a transgenic medaka (Oryzias latipes) strain for visualization of nuclear dynamics in early developmental stages.
Development, Growth & Differentiation 58, 679-687.
(受精卵の前核および細胞核の動態が観察可能な遺伝子組み換えメダカ系統の樹立)
Tokumasu Y†, Iida A†, Wang Z, Ansai S, Kinoshita M, Sehara-Fujisawa A*. (2016)
ADAM12-deficient zebrafish exhibit retardation in body growth at the juvenile stage without developmental defects.
Development, Growth & Differentiation 58, 409-421.
(膜型プロテアーゼADAM12欠損ゼブラフィッシュは稚魚期における成長に遅延が見られる)
2015年
Iida A*, Nishimaki T, Sehara-Fujisawa A. (2015)
Prenatal regression of the trophotaenial placenta in a viviparous fish, Xenotoca eiseni.
Scientific Reports 5, 7855.
(胎生魚ハイランドカープ胎仔の栄養リボンは出生前に退縮する)
2010年
Iida A, Sakaguchi K, Sato K, Sakurai H, Nishimura D, Iwaki A, Takeuchi M, Kobayashi M, Misaki K, Yonemura S, Kawahara A, Sehara-Fujisawa A*. (2010)
Metalloprotease-dependent onset of blood circulation in zebrafish.
Current Biology 20, 1110-1116.
(赤血球が循環に入るタイミングはメタロプロテアーゼによる制御を受ける)
2006年
Iida A, Shimada A, Shima A, Takamatsu N, Hori H, Takeuchi K, Koga A*. (2006)
Targeted reduction of the DNA methylation level with 5-azacytidine promotes excision of the medaka fish Tol2.
Genetical Research 87, 187-193.
(5-azacytidineによるDNAの脱メチル処理はTol2の切り出し頻度を上昇させる)
Koga A*, Iida A, Hori H, Shimada A, Shima A. (2006)
Vertebrate DNA transposon as a natural mutator: The medaka fish Tol2 element contributes to genetic variation without recognizable traces.
Molecular Biology and Evolution 23, 1414-1419.
(Tol2は脊椎動物における自然変異原となりゲノムの多様化に寄与する)
2005年
Iida A, Takamatsu N, Hori H, Wakamatsu Y, Shimada A, Shima A, Koga A*. (2005)
Reversion mutation of ib oculocutaneous albinism to wild-type pigmentation in medaka fish.
Pigment Cell Research 18, 382-384.
(メダカアルビノ変異体i b では体色の復帰突然変異が起こる)
2004年
Iida A, Inagaki H, Suzuki M, Wakamatsu Y, Hori H, Koga A*. (2004)
The tyrosinase gene of the ib albino mutant of the medaka fish carries a transposable element insertion in the promoter region.
Pigment Cell Research 17, 158-164.
(メダカアルビノ変異体i b はチロシナーゼ遺伝子にTol2の挿入を持つ)
Iida A, Tachibana A, Hamada S, Hori H, Koga A*. (2004)
Low transposition frequency of the medaka fish Tol2 transposable element may be due to extranuclear localization of its transposase.
Genes & Genetic Systems 79, 119-124.
(Tol2の転位頻度の低さは自身の転移酵素の核外局在に起因する)
2003年
Koga A*, Iida A, Kamiya M, Hayashi R, Hori H, Ishikawa Y, Tachibana A. (2003)
The medaka fish Tol2 transposable element can undergo excision in human and mouse cells.
Journal of Human Genetics 48, 231-235.
(メダカのトランスポゾンTol2は哺乳類培養細胞において切り出し反応が進行する)