Membrane Glycoproteins (pharmacology) < Membrane Glycoproteins (physiology) < Membrane Glycoproteins (therapeutic use)

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List of bibliographic references indexed by Membrane Glycoproteins (physiology)

Number of relevant bibliographic references: 61.
[0-20] [0 - 20][0 - 50][20-40]

Ident.	Authors (with country if any)	Title
000E56 (2017)	Jibin Sadasivan [Inde] ; Manmeet Singh ; Jayasri Das Sarma	Cytoplasmic tail of coronavirus spike protein has intracellular targeting signals.
002431 (2010)	Shiori Haga [Japon] ; Noriyo Nagata ; Tadashi Okamura ; Norio Yamamoto ; Tetsutaro Sata ; Naoki Yamamoto ; Takehiko Sasazuki ; Yukihito Ishizaka	TACE antagonists blocking ACE2 shedding caused by the spike protein of SARS-CoV are candidate antiviral compounds.
002535 (2010)	Julian L. Leibowitz [États-Unis] ; Rajiv Srinivasa ; Shawn T. Williamson ; Ming Ming Chua ; Mingfeng Liu ; Samantha Wu ; Hyojeung Kang ; Xue-Zhong Ma ; Jianhua Zhang ; Itay Shalev ; Robert Smith ; Melville J. Phillips ; Gary A. Levy ; Susan R. Weiss	Genetic determinants of mouse hepatitis virus strain 1 pneumovirulence.
002588 (2010)	Corrin E. Mcbride [États-Unis] ; Carolyn E. Machamer	A single tyrosine in the severe acute respiratory syndrome coronavirus membrane protein cytoplasmic tail is important for efficient interaction with spike protein.
002972 (2009)	Fumihiro Taguchi [Japon] ; Shutoku Matsuyama	[Cell entry mechanisms of coronaviruses].
002993 (2009)	Lanying Du [États-Unis] ; Yuxian He [États-Unis] ; Yusen Zhou [République populaire de Chine] ; Shuwen Liu [République populaire de Chine] ; Bo-Jian Zheng [République populaire de Chine] ; Shibo Jiang [États-Unis]	The spike protein of SARS-CoV — a target for vaccine and therapeutic development
002A33 (2009)	Ana Shulla [États-Unis] ; Tom Gallagher	Role of spike protein endodomains in regulating coronavirus entry.
002A39 (2009)	Rachel L. Graham ; Ralph S. Baric	Recombination, Reservoirs, and the Modular Spike: Mechanisms of Coronavirus Cross-Species Transmission▿
002B90 (2009)	Sandrine Belouzard [États-Unis] ; Victor C. Chu ; Gary R. Whittaker	Activation of the SARS coronavirus spike protein via sequential proteolytic cleavage at two distinct sites.
002B91 (2009)	Yoshiyuki Yamada [Singapour] ; Xiao Bo Liu ; Shou Guo Fang ; Felicia P L. Tay ; Ding Xiang Liu	Acquisition of cell-cell fusion activity by amino acid substitutions in spike protein determines the infectivity of a coronavirus in cultured cells.
002F42 (2009)	Ikenna G. Madu [États-Unis] ; Shoshannah L. Roth [États-Unis] ; Sandrine Belouzard [États-Unis] ; Gary R. Whittaker [États-Unis]	Characterization of a Highly Conserved Domain within the Severe Acute Respiratory Syndrome Coronavirus Spike Protein S2 Domain with Characteristics of a Viral Fusion Peptide
003116 (2008)	Rie Watanabe [Japon] ; Shutoku Matsuyama ; Kazuya Shirato ; Masami Maejima ; Shuetsu Fukushi ; Shigeru Morikawa ; Fumihiro Taguchi	Entry from the cell surface of severe acute respiratory syndrome coronavirus with cleaved S protein as revealed by pseudotype virus bearing cleaved S protein.
003140 (2008)	Han Xiao [Singapour] ; Ling Hui Xu ; Yoshiyuki Yamada ; Ding Xiang Liu	Coronavirus spike protein inhibits host cell translation by interaction with eIF3f.
003160 (2008)	Megan W. Howard [États-Unis] ; Emily A. Travanty ; Scott A. Jeffers ; M K Smith ; Sonia T. Wennier ; Larissa B. Thackray ; Kathryn V. Holmes	Aromatic amino acids in the juxtamembrane domain of severe acute respiratory syndrome coronavirus spike glycoprotein are important for receptor-dependent virus entry and cell-cell fusion.
003590 (2007)	Mo Liu [République populaire de Chine] ; Yongbo Yang ; Chunfang Gu ; Yinpu Yue ; Kenneth K. Wu ; Jianguo Wu ; Ying Zhu	Spike protein of SARS-CoV stimulates cyclooxygenase-2 expression via both calcium-dependent and calcium-independent protein kinase C pathways.
003B16 (2007)	Corrin E. Mcbride [États-Unis] ; JIE LI [États-Unis] ; Carolyn E. Machamer [États-Unis]	The cytoplasmic tail of the severe acute respiratory syndrome coronavirus spike protein contains a novel endoplasmic reticulum retrieval signal that binds COPI and promotes interaction with membrane protein
003B17 (2007)	Gijs A. Versteeg [Pays-Bas] ; Paula S. Van De Nes [Pays-Bas] ; Peter J. Bredenbeek [Pays-Bas] ; Willy J. M. Spaan [Pays-Bas]	The coronavirus spike protein induces endoplasmic reticulum stress and upregulation of intracellular chemokine mRNA concentrations
003C25 (2006)	Fumihiro Taguchi [Japon]	[Cell entry mechanism of coronaviruses: implication in their pathogenesis].
003C87 (2006)	Lisa A. Lopez [États-Unis] ; Ariel Jones ; William D. Arndt ; Brenda G. Hogue	Subcellular localization of SARS-CoV structural proteins.
003D25 (2006)	I-Chueh Huang [États-Unis] ; Berend Jan Bosch ; Wenhui Li ; Michael Farzan ; Peter M. Rottier ; Hyeryun Choe	SARS-CoV, but not HCoV-NL63, utilizes cathepsins to infect cells: viral entry.
003D49 (2006)	M H Verheije [Pays-Bas] ; T. Würdinger ; V W Van Beusechem ; C A M. De Haan ; W R Gerritsen ; P J M. Rottier	Redirecting coronavirus to a nonnative receptor through a virus-encoded targeting adapter.

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