目的:制备抗激活素受体相互作用蛋白1(ARIP1)抗体并探讨其应用。
Objective To prepare anti-activin receptor-interacting protein 1 (ARIP1) polyclonal antibody.
但他坚持认为这样的蛋白质数目可能会很多,因为在皮质醇受体的进化过程中,导致不可改变性的突变之间复杂的相互作用的形式比比皆是。
But he argues that the number is likely to be large because the type of complex interactions between mutations that caused irreversibility in the evolution of the cortisol receptor are common.
G -蛋白偶联受体分布于细胞膜,与行使细胞通讯的分子(如神经递质和激素)发生相互作用。
Found in the cell membrane, GPCRs interact with molecules responsible for cellular communication such as neurotransmitters and hormones.
层粘连蛋白是基底膜的重要成分之一,通过与其受体间的相互作用而具有广泛的生物学功能。
Laminin is an important component of basement membrane, it has extensive biological functions through the interaction with its receptors.
结果该质粒有正确的阅读框,其表达蛋白不具有自主转录激活作用,与已知核受体辅活化子PNRC有明显的相互作用。
Results The protein expressed by the plasmid which had a correct reading frame, had no transcriptional activation and could interact with a known coactivator PNRC.
提示层粘连蛋白受体和配体的相互作用可影响胃癌的生长方式。
Suggesting that the interaction between the laminin receptor and its ligand may influence the mode of growth in GC.
目的:探寻与G_CSF受体胞内区相互作用的下游蛋白因子,揭示G_CSF受体信号转导通路的可能机制。
Objective: to explore the protein factors that may interact with G_CSF receptor in the signal transduction pathways.
生长调节剂对生物体的调控作用是通过调节剂与生物体细胞内的受体蛋白相互作用来实现的。
The regulation effect of growth regulator is realized by the interaction between receptive proteins in organism.
植物与病原菌相互作用的过程中涉及了许多信号分子的识别与传导,对病原菌而言,这些信号分子很有可能就是与植物受体蛋白起作用的激发子和其它致病因子。
The interaction involves a complex process of signal recognition and transduction, at which the signal molecules from plant fungal pathogens may be recognized as elicitors or virulence factors.
植物与病原菌相互作用的过程中涉及了许多信号分子的识别与传导,对病原菌而言,这些信号分子很有可能就是与植物受体蛋白起作用的激发子和其它致病因子。
The interaction involves a complex process of signal recognition and transduction, at which the signal molecules from plant fungal pathogens may be recognized as elicitors or virulence factors.
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