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文题释义:
蛋白质组:其概念最先由Marc Wilkins提出,指由一个基因组(Genome),或一个细胞、组织表达的所有蛋白质。蛋白质组的概念与基因组的概念有许多差别,它随着组织、甚至环境状态的不同而改变。 在转录时,一个基因可以多种mRNA形式剪接,一个蛋白质组不是一个基因组的直接产物,蛋白质组中蛋白质的数目有时可以超过基因组的数目。蛋白质组学(Proteomics)处于早期“发育”状态,这个领域的专家否认它是单纯的方法学,就像基因组学一样,不是一个封闭的、概念化的稳定的知识体系,而是一个领域。
质谱:又叫质谱法,是一种与光谱并列的谱学方法,通常意义上是指广泛应用于各个学科领域中通过制备、分离、检测气相离子来鉴定化合物的一种专门技术。质谱法在一次分析中可提供丰富的结构信息,将分离技术与质谱法相结合是分离科学方法中的一项突破性进展。在众多的分析测试方法中,质谱学方法被认为是一种同时具备高特异性和高灵敏度且得到了广泛应用的普适性方法。质谱仪器一般由样品导入系统、离子源、质量分析器、检测器、数据处理系统等部分组成。
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.jpg)
文题释义:
蛋白质组:其概念最先由Marc Wilkins提出,指由一个基因组(Genome),或一个细胞、组织表达的所有蛋白质。蛋白质组的概念与基因组的概念有许多差别,它随着组织、甚至环境状态的不同而改变。 在转录时,一个基因可以多种mRNA形式剪接,一个蛋白质组不是一个基因组的直接产物,蛋白质组中蛋白质的数目有时可以超过基因组的数目。蛋白质组学(Proteomics)处于早期“发育”状态,这个领域的专家否认它是单纯的方法学,就像基因组学一样,不是一个封闭的、概念化的稳定的知识体系,而是一个领域。
质谱:又叫质谱法,是一种与光谱并列的谱学方法,通常意义上是指广泛应用于各个学科领域中通过制备、分离、检测气相离子来鉴定化合物的一种专门技术。质谱法在一次分析中可提供丰富的结构信息,将分离技术与质谱法相结合是分离科学方法中的一项突破性进展。在众多的分析测试方法中,质谱学方法被认为是一种同时具备高特异性和高灵敏度且得到了广泛应用的普适性方法。质谱仪器一般由样品导入系统、离子源、质量分析器、检测器、数据处理系统等部分组成。