葛仙米藻蓝蛋白的一级结构、构象及抗氧化活性研究
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摘要
葛仙米以其资源稀少、营养价值丰富、独特的生物活性和广泛的应用价值而引起人们地关注。葛仙米作为一种食药同源的传统食品已有几千年的历史,但对其主要活性成分的研究很少。为探讨葛仙米中的生物活性成分,本文以野生葛仙米为研究对象,充分利用生物大分子研究的最新技术和现代分离、分析手段,首次系统地研究了葛仙米蛋白质的提取、分离和优化,并对藻蓝蛋白的纯化和藻蓝蛋白的一级结构、空间结构进行了研究,且分析了藻蓝蛋白抗氧化活性。其主要结果如下:
1葛仙米的生物学特性与生化组成研究
以湖北省鹤峰县走马镇野生葛仙米为研究对象,分析了生态条件及分布规律。葛仙米主要分布于亚热带二高山地区,属亚热带大陆性季风湿润气候;土壤含Fe、Mn相对较高;年最高温度36℃,最低温度0.7℃,年均降雨量1836.4mm,年均日照1342h。葛仙米营养丰富,蛋白质、多糖含量高,达54%;富含维生素,V_(B1) 1.2mg/100g,V_(B2) 11.8mg/100g,Vc 550mg/100g,V_E 7.0mg/100g,β-胡萝卜素114mg/100g,高于一般食物;脂肪含量为5.50%,以中碳链为主;含大量矿质元素和微量元素。
2葛仙米蛋白的提取、分离和优化及藻蓝蛋白的纯化和鉴定
试验选取pH值、温度和提取时间这三个影响葛仙米蛋白得率的最重要的因素,采用三因素二次旋转正交回归组合实验,优化出葛仙米蛋白提取的最佳工艺条件为,缓冲液pH为7.3、浸提时间4.3h、盐浓度0.21mol/L,葛仙米蛋白得率达7.13%。采用反相分段梯度盐析法,即先用20%(NH_4)_2SO_4饱和度沉淀除去杂质,60%(NH_4)_2SO_4沉淀PC,沉淀溶解以后第2次和第3次盐析时逐渐变窄沉淀范围,提高了藻蓝蛋白的纯度,保证了较高的得率。葛仙米蛋白提取工艺为:原料—复水—反复冻融—超声波破壁—磷酸缓冲液浸提(4℃,4h/次,3次,pH值为7.0的0.05M磷酸钾缓冲液+0.2M NaCl)—高速冷冻离心(14000r/min,4℃,45min)—反相硫酸铵分步盐析法—透析—冷冻干燥得粗葛仙米蛋白。
利用DEAE-Cellulose 52离子交换层析,采用步进式洗脱模式成功地将葛仙米蛋白分离出葛仙米藻蓝蛋白。采用羟基磷灰石(HA)柱层析、DEAE-Sepharose FF,进一步纯化后得到均一的级分。经柱层析法、分光光度法、荧光光谱法和电泳法鉴定其为具有色谱纯和电泳纯的样品。SDS-PAGE凝胶电泳法测定了葛仙米藻蓝蛋白相对分子质量,即为38.245K,是为两条不同分子质量(即19.852K和18.383K)的肽链通过二硫键连接而成。
3葛仙米藻蓝蛋白一级结构的表征
采用MALDI-TOF-MS测定NSPC的分子质量,获得了NSPC精确分子质量为37715。根据氨基酸自动分析仪测定的氨基酸组成和精确分子质量计算出NSPC分子总共有331个氨基酸残基,分别是由40个Asp、22个Thr、18个Ser、22个Glu、1个Gly、31个Ala、27个Cys、17个Val、13个Ile、22个Leu、5个Tyr、7个Phe、7个Lys、24个His、51个Arg、14个Pro、1个Met和9个Trp组成。胰蛋白水解酶分别酶解NSPC-1和NSPC-2后,分别采用MALDI-TOF-MS分析,其肽指纹谱图显示胰蛋白酶可将NSPC-1和NSPC-2水解成大小不等的多条肽段,质量数在800以上的NSPC-2有11段,即水解的肽质量分别为899.54、1454.77、1544.9、1683.87、1803.93、1811.91、1987.92、2003.90、2536.26、2915.42和3492.72。NSPC-2的氨基酸序列为:
1 MKTPLTEAVS IADSQGRFLS STEIQVAFGR FRQAKAGLEAAKALTSKADS
51 LISGAAQAVY NKFPYTTQMQ GPNYAADQRG KDKCARDIGY YLRMVTYCLI
101 AGGTGPMDEY LIAGIDEINR TFELSPSWYI EALKYIKANH GLSGDAAVEA
151 NSYLDYAINA LS
肽质量指纹图谱和肽序列标签结合用于蛋白质数据库搜索,证明NSPC-2为极太螺旋藻α链,而NSPC-1未从数据库中检索到与此匹配的蛋白。
4葛仙米藻蓝蛋白分子构象的表征
采用FTIR、CD、AFM、SEM、X-衍射、DSC和FR等分析技术,测定了NSPC的空间结构及变性温度。FTIR和CD分析结果显示NSPC主要以α-螺旋结构为主,β-折叠或卷曲结构含量较少。荧光光谱显示,在水溶液中NSPC分子中的Trp残基两种类型都存在,既有暴露于分子外部的Trp残基,也有处于疏水内部的Trp残基。其溶液构象在pH7时最稳定,但酸碱度对其构象影响较小,在pH<7时NSPC构象相对变化略大于在碱性环境。有机溶剂对其构象变化影响较大。
通过AFM观察,在中性环境下,NSPC分子呈链状形式存在:DSC结果表明,NSPC变性温度为41.6℃。
通过扫描电镜观察,NSPC聚集念主要以片层、针状和蜂窝状形式。X-射线衍射分析结果表明经冻干得到的NSPC粉术结晶度高,且结晶区分子的规整性较高。
5葛仙米蛋白稳定性研究研究了温度、pH、光强、乙醇浓度、中性盐浓度、饱和度的硫酸铵溶液和不同蔗糖浓度等因子对其稳定性的影响。结果表明,葛仙米蛋白在自然光照下,温度低于40℃,pH5~8,乙醇浓度小于40°,低浓度中性盐和低浓度蔗糖溶液中能保持较好地稳定性,60%饱和度的硫酸铵溶液有利于其稳定性。
6葛仙米藻蓝蛋白的抗氧化活性
非脂质体系抗氧化实验、体外抗氧化实验等结果表明葛仙米蛋白粗提物具有良好的抗氧化性能作用。清除氧自由基的能力为:粗提物>藻红蛋白>藻蓝蛋白;这可能是由于粗提物中还含有多糖和酚类物质等共同作用的结果,葛仙米藻蓝蛋白对清除O_2~-、·OH自由基和H_2O_2具有较好的量效关系。在体外反应体系中,NSPC能显著地降低MDA生成和血和肝中过氧化物的含量,起到保护细胞膜和红血球的作用。
The significant biological and apply value of Nostoc Sphaeroids kutz with abound nutrition and infrequent distribution had been paid people's much attention. Although NSK as a kind of food and medicine function had been used for several thousand years, the main active component of activity and function is little investigated. In recent years, it was by a few people that its partial physiology and primary biochemistry composition was reported. In order to ascertain the active component of NSK, the phycocyanin was used as material, taking advantage of modern separation technology and biomacromolecules analysis method, first systemically studies on preparation and purification of NSPP, and its primary structure and high structure were also investigated. The main results were shown as follows:1 The biological trait of NSK and its biochemisty componentOn the basis of the biological trait of NSK having been investigated, in order to determine its biochemistry components, such as ecological condition and its contribution, Reproduction mechanism, water, protein, fat, polysaccharide, carotene and chlorophyll as well as mineral element, wild NSK, Zouma town, Hefeng county, Hubei province, was used as crude material.2 Extraction, separation, purification and identification of phycocyaninDefatted NSK as material, albumin, globin and salt-soluble protein were separated from NSK by salting-in and salting-out methods for the first time and the the optimal extraction technology were studied. The results were as follows: pH 7.0, salt concentration 0.2 mol/L and extracted time was 4 h, and the output of phycobiliproteins was 7.13 percent. DEAE-Cellulose ion-exchange chromatography was used to separation NSPP. It was successful to obtain five fractions, by the step gradient. NSPP was further purified by DEAE-Separose FF and HA chromatography. Some methods such as spectrophotometer and chromatography and electrophoresis were applied to identify the purity of phycocyanin, and it was identified to be chromatography and electrophoresis grade pure.
3 Primary structure characterization of phycocyanin
The primary structure of phycocyanin was studied with matrix-assisted laser desorption ionization time-of-flight mass spectrometry (MALDI-TOF-MS) and sodium dodecyl sulfate ployacrylamide gel electrophoresis (SDS-PAGE), its molecular weight and their peptide mass fingerprinting were analysed. The results demonstrated that the measured molecular weight of phycocyanin was 37.715Kd, and consisted of two peptides which were similar with their molecular weight and amino acid sequences.
4 The comformation of phycocyanin
Phycocyanin high structure was investigated, as the result of circular dichroism (CD) spectrum and Fourier transformation infared (FTIR) spectrum shown, the secondary structure of NSPC was mainlyα-helix structure and the content ofβ-shee or coil was very small. While NSPC's agglutination form was observed by force atom microscope (AFM) and scan electron microscope (SEM) there existed mainly catenulate distribution. Meanwhile, they denatured temperature was also studied by differential scan calorimeter (DSC), the results showed that the temperatute of NSPC 41.6℃.
It was shown by fluorescence spectrum that there were both the Trp residues which lie outside the molecular and the Trp residues which lie in the inside hydrophilic structure in NSPC.
5 The stability of protions in NSP
The effect of temperature, pH, light intensity, alcohol concentration, difffrent concentration of neutral salt, different saturation ammonium sulfate solution and sucrose concentration on the stability of protions in NSP was investigated. The results showed that, protions in NSP kept still stability under the appropriate circumstance: under natural sunlight, below 40℃, pH 5-8, alcohol concentration<40°, and 60% aturation ammonium sulfate solution was beneficial to stability.
6 Antioxidation activity of phycocyanin
Experiments about the anti-oxidation effect in non-lipidosome and in vitro mice all indicated anti-oxidation activity of NSPP was significantly. The results showed that scavenge capability was orderly, H_2O_2 radical,·OH radical. O_2~- radical with chemiluminescence, respectively. Through the experiment in vitro, Phycocyanin could reduce the content of MAD and LOP in blood and liver.
1葛仙米的生物学特性与生化组成研究
以湖北省鹤峰县走马镇野生葛仙米为研究对象,分析了生态条件及分布规律。葛仙米主要分布于亚热带二高山地区,属亚热带大陆性季风湿润气候;土壤含Fe、Mn相对较高;年最高温度36℃,最低温度0.7℃,年均降雨量1836.4mm,年均日照1342h。葛仙米营养丰富,蛋白质、多糖含量高,达54%;富含维生素,V_(B1) 1.2mg/100g,V_(B2) 11.8mg/100g,Vc 550mg/100g,V_E 7.0mg/100g,β-胡萝卜素114mg/100g,高于一般食物;脂肪含量为5.50%,以中碳链为主;含大量矿质元素和微量元素。
2葛仙米蛋白的提取、分离和优化及藻蓝蛋白的纯化和鉴定
试验选取pH值、温度和提取时间这三个影响葛仙米蛋白得率的最重要的因素,采用三因素二次旋转正交回归组合实验,优化出葛仙米蛋白提取的最佳工艺条件为,缓冲液pH为7.3、浸提时间4.3h、盐浓度0.21mol/L,葛仙米蛋白得率达7.13%。采用反相分段梯度盐析法,即先用20%(NH_4)_2SO_4饱和度沉淀除去杂质,60%(NH_4)_2SO_4沉淀PC,沉淀溶解以后第2次和第3次盐析时逐渐变窄沉淀范围,提高了藻蓝蛋白的纯度,保证了较高的得率。葛仙米蛋白提取工艺为:原料—复水—反复冻融—超声波破壁—磷酸缓冲液浸提(4℃,4h/次,3次,pH值为7.0的0.05M磷酸钾缓冲液+0.2M NaCl)—高速冷冻离心(14000r/min,4℃,45min)—反相硫酸铵分步盐析法—透析—冷冻干燥得粗葛仙米蛋白。
利用DEAE-Cellulose 52离子交换层析,采用步进式洗脱模式成功地将葛仙米蛋白分离出葛仙米藻蓝蛋白。采用羟基磷灰石(HA)柱层析、DEAE-Sepharose FF,进一步纯化后得到均一的级分。经柱层析法、分光光度法、荧光光谱法和电泳法鉴定其为具有色谱纯和电泳纯的样品。SDS-PAGE凝胶电泳法测定了葛仙米藻蓝蛋白相对分子质量,即为38.245K,是为两条不同分子质量(即19.852K和18.383K)的肽链通过二硫键连接而成。
3葛仙米藻蓝蛋白一级结构的表征
采用MALDI-TOF-MS测定NSPC的分子质量,获得了NSPC精确分子质量为37715。根据氨基酸自动分析仪测定的氨基酸组成和精确分子质量计算出NSPC分子总共有331个氨基酸残基,分别是由40个Asp、22个Thr、18个Ser、22个Glu、1个Gly、31个Ala、27个Cys、17个Val、13个Ile、22个Leu、5个Tyr、7个Phe、7个Lys、24个His、51个Arg、14个Pro、1个Met和9个Trp组成。胰蛋白水解酶分别酶解NSPC-1和NSPC-2后,分别采用MALDI-TOF-MS分析,其肽指纹谱图显示胰蛋白酶可将NSPC-1和NSPC-2水解成大小不等的多条肽段,质量数在800以上的NSPC-2有11段,即水解的肽质量分别为899.54、1454.77、1544.9、1683.87、1803.93、1811.91、1987.92、2003.90、2536.26、2915.42和3492.72。NSPC-2的氨基酸序列为:
1 MKTPLTEAVS IADSQGRFLS STEIQVAFGR FRQAKAGLEAAKALTSKADS
51 LISGAAQAVY NKFPYTTQMQ GPNYAADQRG KDKCARDIGY YLRMVTYCLI
101 AGGTGPMDEY LIAGIDEINR TFELSPSWYI EALKYIKANH GLSGDAAVEA
151 NSYLDYAINA LS
肽质量指纹图谱和肽序列标签结合用于蛋白质数据库搜索,证明NSPC-2为极太螺旋藻α链,而NSPC-1未从数据库中检索到与此匹配的蛋白。
4葛仙米藻蓝蛋白分子构象的表征
采用FTIR、CD、AFM、SEM、X-衍射、DSC和FR等分析技术,测定了NSPC的空间结构及变性温度。FTIR和CD分析结果显示NSPC主要以α-螺旋结构为主,β-折叠或卷曲结构含量较少。荧光光谱显示,在水溶液中NSPC分子中的Trp残基两种类型都存在,既有暴露于分子外部的Trp残基,也有处于疏水内部的Trp残基。其溶液构象在pH7时最稳定,但酸碱度对其构象影响较小,在pH<7时NSPC构象相对变化略大于在碱性环境。有机溶剂对其构象变化影响较大。
通过AFM观察,在中性环境下,NSPC分子呈链状形式存在:DSC结果表明,NSPC变性温度为41.6℃。
通过扫描电镜观察,NSPC聚集念主要以片层、针状和蜂窝状形式。X-射线衍射分析结果表明经冻干得到的NSPC粉术结晶度高,且结晶区分子的规整性较高。
5葛仙米蛋白稳定性研究研究了温度、pH、光强、乙醇浓度、中性盐浓度、饱和度的硫酸铵溶液和不同蔗糖浓度等因子对其稳定性的影响。结果表明,葛仙米蛋白在自然光照下,温度低于40℃,pH5~8,乙醇浓度小于40°,低浓度中性盐和低浓度蔗糖溶液中能保持较好地稳定性,60%饱和度的硫酸铵溶液有利于其稳定性。
6葛仙米藻蓝蛋白的抗氧化活性
非脂质体系抗氧化实验、体外抗氧化实验等结果表明葛仙米蛋白粗提物具有良好的抗氧化性能作用。清除氧自由基的能力为:粗提物>藻红蛋白>藻蓝蛋白;这可能是由于粗提物中还含有多糖和酚类物质等共同作用的结果,葛仙米藻蓝蛋白对清除O_2~-、·OH自由基和H_2O_2具有较好的量效关系。在体外反应体系中,NSPC能显著地降低MDA生成和血和肝中过氧化物的含量,起到保护细胞膜和红血球的作用。
The significant biological and apply value of Nostoc Sphaeroids kutz with abound nutrition and infrequent distribution had been paid people's much attention. Although NSK as a kind of food and medicine function had been used for several thousand years, the main active component of activity and function is little investigated. In recent years, it was by a few people that its partial physiology and primary biochemistry composition was reported. In order to ascertain the active component of NSK, the phycocyanin was used as material, taking advantage of modern separation technology and biomacromolecules analysis method, first systemically studies on preparation and purification of NSPP, and its primary structure and high structure were also investigated. The main results were shown as follows:1 The biological trait of NSK and its biochemisty componentOn the basis of the biological trait of NSK having been investigated, in order to determine its biochemistry components, such as ecological condition and its contribution, Reproduction mechanism, water, protein, fat, polysaccharide, carotene and chlorophyll as well as mineral element, wild NSK, Zouma town, Hefeng county, Hubei province, was used as crude material.2 Extraction, separation, purification and identification of phycocyaninDefatted NSK as material, albumin, globin and salt-soluble protein were separated from NSK by salting-in and salting-out methods for the first time and the the optimal extraction technology were studied. The results were as follows: pH 7.0, salt concentration 0.2 mol/L and extracted time was 4 h, and the output of phycobiliproteins was 7.13 percent. DEAE-Cellulose ion-exchange chromatography was used to separation NSPP. It was successful to obtain five fractions, by the step gradient. NSPP was further purified by DEAE-Separose FF and HA chromatography. Some methods such as spectrophotometer and chromatography and electrophoresis were applied to identify the purity of phycocyanin, and it was identified to be chromatography and electrophoresis grade pure.
3 Primary structure characterization of phycocyanin
The primary structure of phycocyanin was studied with matrix-assisted laser desorption ionization time-of-flight mass spectrometry (MALDI-TOF-MS) and sodium dodecyl sulfate ployacrylamide gel electrophoresis (SDS-PAGE), its molecular weight and their peptide mass fingerprinting were analysed. The results demonstrated that the measured molecular weight of phycocyanin was 37.715Kd, and consisted of two peptides which were similar with their molecular weight and amino acid sequences.
4 The comformation of phycocyanin
Phycocyanin high structure was investigated, as the result of circular dichroism (CD) spectrum and Fourier transformation infared (FTIR) spectrum shown, the secondary structure of NSPC was mainlyα-helix structure and the content ofβ-shee or coil was very small. While NSPC's agglutination form was observed by force atom microscope (AFM) and scan electron microscope (SEM) there existed mainly catenulate distribution. Meanwhile, they denatured temperature was also studied by differential scan calorimeter (DSC), the results showed that the temperatute of NSPC 41.6℃.
It was shown by fluorescence spectrum that there were both the Trp residues which lie outside the molecular and the Trp residues which lie in the inside hydrophilic structure in NSPC.
5 The stability of protions in NSP
The effect of temperature, pH, light intensity, alcohol concentration, difffrent concentration of neutral salt, different saturation ammonium sulfate solution and sucrose concentration on the stability of protions in NSP was investigated. The results showed that, protions in NSP kept still stability under the appropriate circumstance: under natural sunlight, below 40℃, pH 5-8, alcohol concentration<40°, and 60% aturation ammonium sulfate solution was beneficial to stability.
6 Antioxidation activity of phycocyanin
Experiments about the anti-oxidation effect in non-lipidosome and in vitro mice all indicated anti-oxidation activity of NSPP was significantly. The results showed that scavenge capability was orderly, H_2O_2 radical,·OH radical. O_2~- radical with chemiluminescence, respectively. Through the experiment in vitro, Phycocyanin could reduce the content of MAD and LOP in blood and liver.
引文
1.丁广奇,王学文.植物学名解释.北京:科学出版社,1986,452-463
2.陈德文,潘思轶,汪兴平.葛仙米的研究现状及应用前景.食品科学,2003,24(1):153-156
3.湖北省鹤峰县史志编纂委员会.鹤峰县志.武汉:武汉人民出版社,1990,476-498
4.刘金龙,葛仙米营养成分分析.中草药,31(11):2001,862-863
5.莫开菊,谢笔均,汪兴平.葛仙米多糖的提取、分离与纯化技术研究.食品科学,2004,24(10):103-108
6.彭卫民,商树田.螺旋藻藻胆蛋白研究进展(综述).农业生物技术学报,1998,6(2):173-177
7.全国中草药汇编.北京:人民卫生出版社,1983
8.谭学儒.葛仙米.土特产,20003:30-30
9.尤崇杓等编.生物固氮.北京:科学出版社,1987,159-192
10.王广策,邓田,曾呈奎.藻胆蛋白的研究概况(Ⅰ)——藻胆蛋白的种类与组成.海洋科学,2000a,24(2):22-25
11.王广策,邓田,曾呈奎.藻胆蛋白的研究概况(Ⅱ)——藻胆蛋白的结构及其光谱特性.海洋科学,2000b,24(3):9-22
12.夏建荣,高坤山.念珠藻葛仙米营养成分分析.武汉植物研究,2002,20(3):223-224
13.杨春澍主编.药用植物学.上海:上海科技出版社,2001,130-131
14.杨世杰等编.植物生物学.北京:科学出版社,2000,294-296
15.朱浩然主编.中国淡水藻志(第二卷).北京:科学出版社,1991,1-10
16. http://www.hbhf-ca.com, 2003
17. http://www.singtaonet.com/singtaonet/head_sp/t20051010_10802.html
18. Huang Z B, Liu Y D, Paulsen B S. Studies on polysaccharides from three edible species of Nostoc (Cyanobacteria)with different colony morphologies: comparison of monosaccharides composition and viscosities of polysaccharides from field colonies and suspension cultures. Phycology, 1998,34(7):962-968
19. Johan A, Hellebust, J. S. Craigie. Handbook of phycological methods—Physiological and biochemical methods. Cambridge University press, 1978:48-76
20. Li D H, Liu Y D, Song L R, Hormogonia mass differentiation from Nostoc sphaeroides Kutz. (cyanobacterium)and comparison of structural charatedstics between hormogonia and vegetative filaments. Phycological Research, 2001,49(2): 81-8
21. Siegelman H W, Kycia J H. Handbook of phycological methods. Cambridge University Press, 1978:72-145
1.湖北省鹤峰县史志编纂委员会.鹤峰县志.武汉:武汉人民出版社.1990:476-498
2.全国中草药汇编编写组.全国中草药汇编.北京:人民卫生出版社,,1978,704
3.王莹,辛士刚.ICP-AES法测定豆类食品中的微量元素光谱学与光谱分析,2004,24(2):226-228.
4.杨春澍主编.药用植物学.上海:上海科技出版社.2001;130~131.
5.杨世杰等编.植物生物学.北京:科学出版社.2000;294~296.
6.张威,朱劲华,王敏.极大螺旋藻胞内多糖分离纯化及其结构的初步分析.天然产物研究与开发,2004,16(6):548-551.
7.朱浩然主编.中国淡水藻志(第二卷).北京:科学出版社,1991,1-10.
8.鞠兴荣,袁建.食品中限量元素分析样品的预处理技术进展.食品科学,2004,25(2):199-203
9. Huang Z B, liu Y D, Paulsen B S. Studies on polysaceharides from three edible species of Nostoc (Cyanobacteria) with different colony morphologies: comparison of monosaccharides composition and viscosities of polysaccharides from field colonies and suspension cultures. J.Phycology, 1998, 34:9629-68
10. Lazaroff N, Vishniac W. The effect of light on the developmental cycle of Nostocmuscorum, a filamen blue-green algae. J.gen.Microbiol, 1961a, 25:365-374
11. Lazaroff N, Vishniac W. The effect of light on the developmental cycle of Nostocmuscorum, a filamen blue-green algae. J.gen.Microbiol, 1961b, 28:203-210
12. Li D H, Liu Y D, Song L R. Hormogonia mass differentiation from Nostoc Sphaeroides Kutz(cyanobacterium) and comparison of structural charateristics between hormogonia and vegetative filaments.Phycological Research, 2001, 49(2): 81-87
13. Poeggler B, Reiter RJ, Tan DX, et al. Melatonin, hydruxyl radical-medixted oxidative clarnage, and aging: Ahypothesis. J Pineal Res, 1993, 14 (2): 151-168
14. www.hbhf-ca.com, 2003
1.陈曾兰.12种氨基酸混合物的生理功能研究.杭州食品科技,2001,(2):11-14
2.苟大明,余志豪.L-精氨酸对体外循环中红细胞保护作用的研究.2001,25(9):771-773
3.韩雅珊主编.食品化学实验指导.北京:北京农业出版社,1992,4
4.何照范,张迪清.保健食品化学及其检测技术.中国轻工业出版社,1999
5.黄耀凌,邹思湘.谷氨酰胺的抗疲劳生化机制研究.南京农业大学学报,2001,24(2):87-89
6.胡朝辉,刘志礼.极大螺旋藻中-胡萝卜素的分离的纯化及定量测定.色谱,2001(11):85-87
7.李敦海,刘永定,宋立荣,盐胁迫对葛仙米生理生化特性的影响,水生生物学报,1999(5):414-418
8.李合生主编,植物生理生化实验原理和技术.高等教育出版社,2000
9.青胜兰,陈玉祥.精氨酸在大肠癌的应用.大肠肛门病外科杂志,1999,5(4):24-25
10.全国中草药汇编,人民卫生出版社,1983
11.谭学儒,葛仙米简介,中国食物与营养,1998(5):45
12.王莹,辛士刚.ICP-AES法测定豆类食品中的微量元素.光谱学与光谱分析,2004,24(2):226-228
13.王大志,彭光跃.海水小球藻脂肪酸组成研究.海洋科学.1999(4):68-70
14.孟庆勇,刘志辉,徐美奕.半叶马尾藻多糖的提取和分析.光谱学与光谱分析,2004,24(12):1560-1562
15.吴烈钧.气相色谱检测方法.化学工业出版社,2001
16.无锡轻工业学院,天津轻工业学院合编,食品分析,北京:中国轻工业出版社,1994:209,223
17.于世林编著.高效液相色谱方法及应用.北京:化学工业出版社,2001:35-36
18.张意静.食品分析.北京:轻工业出版社,1999:143-190
19.鞠兴荣,袁建.食品中限量元素分析样品的预处理技术进展.食品科学,2004, 25(2):199-203
20.周亚魁,刘权焰.不平衡氨基酸对肿瘤生长的影响.中国临床营养杂志,2001,9(2):103-105
21. Poeggler B., Reiter R J., Tan D X., et al. Melatonin, hydruxyl radical-medixted oxidative clamage, andaging: Ahypothesis. J Pineal Res, 1993, 14 (2): 151-168
1.华家柽等编译.使用蛋白质化学技术.上海:上海科学出版社,1982:40-245
2.黄岩,秦利,朱晋昌.红毛菜中两中不同分子量的R-藻红蛋白的性质比较.生物物理与生物化学.1993,25(7):434-440
3.纪明侯.海藻化学.北京:科学出版社,1997 485-506
4.李邵蓉,林惠民.Rhodosorusmarinus中藻红蛋白的纯化及其性质的研究.水生生物学报.1996,20(9):257-264
5.陶慰孙等编著.蛋白质分子基础.北京:人民出版社,1981:45-64
6.王广策,邓田,曾呈奎.藻胆蛋白的研究概况(Ⅰ)-藻胆蛋白的种类与组成.海洋科学.2000,24(2):22-25
7.王盛,吴祖建,林奇英.珊瑚藻藻红蛋白分离纯化及光谱学特性.福建农林大学学报(自然科学版),2002,31(4):495-499
8.余家林编著.农业试验多元统计.北京:北京农业大学出版社,1993:91-141
9.赵永芳.生物化学技术原理及应用(第二版).湖北:武汉大学出版社,1994,25-42
10. Canaani O D, Elisabeth Gantt. Circulardichroism and polarized fluorescence characteristics of blue-green alga allophycocyanins. Biochem, 1980, 19: 2,950-2,956.
11. Jean-Claude Thomas, Chantal Passaquet. Characterization ofa phycoerythrin without α-Subunites from a unicellular red alga. J Biol Chem. 1999, 274(4): 2472-2482
12. MacColl R, Eisele E, Williams C, et al. The discovery of a novel R-phycoerythrin from a matarctic red alga. J Biol Chem. 1996,271(29): 17,157-17,160
10. O'Carra P, O'hEocha C. Algal biliproteins and phycobilins. Chemistry and Biochemistry of plant Pigments. NewYork:Academic Press, 1976, 328-376
1.鲍时翔.姚汝华.蛋白质分离纯化与层析技术进展.华南理工大学学报(自然科学版),1996,14(12):98-103
2.胡一兵,胡鸿钧,李夜光.从一种富含藻胆蛋白的螺旋藻中大量提取和纯化藻蓝蛋白的研究.武汉植物学研究,2002,20(4):299-302
3.王勇,钱凯先,董强.高纯度藻蓝蛋白分离纯化及光谱特性研究.生物化学与生物物理进展,1999,26(5):457-460
4.汪家政,范明主编.蛋白质技术手册.北京:科学出版,2000,77-89
5.夏其昌.蛋白质化学研究技术与进展.科学出版,1997,21-35
6.曾庆冰,许家瑞,符若文.蛋白质分离色谱填料及其特性.功能高分子学报,2000,13(3):343-348
7.张建平,张景民,赵井泉.R-藻蓝蛋白的分离及其结构表征.生物物理学报,1997,13(2):173-178
8.张养军,蔡耘,王京兰.蛋白质组学研究中的色谱分离技术.色谱,2003,21(1):20-26
9.赵开弘.层理鞭枝藻的藻蓝蛋白和藻红蓝蛋白α-亚基及其色素肽的光化学与光谱性质.武汉大学学报(自然科学版),1998,44(6):757-760
10.赵永芳.生物化学技术原理及其应用.武汉:武汉大学出版社,1994,298-299
11.郑江,高亚辉,王文星.红毛藻中多组分藻胆蛋白及其亚基的分离.中国水产科学,2003,10(4):277-281
12.周志刚,尹长松.富硒极大螺旋藻整细胞、藻胆体及藻蓝蛋白的光谱特性.上海水产大学学报,2002,11(3):208-214
13. Jean-Claude Thomas, Chantal Passaquet. Characterization of a phycoerythrin without α-subunits from a unicellular red alga. J Biol Chem, 1999, 274 (4): 2472-2482.
14. Johan A, Hellebust J. S. Cralgie, Handbook ofphycological methods Physiological and biochemical methods. Cambridge University press, 1978, 72-80
15. MacColl, Eisele E, Williams C, et al. The discovery of a novel R -phycoerythrin from an Antarctic red alga. J Biol Chem, 1996, 271 (29): 17157-17160.
16. O'carra P, O'H Eocha. Algal biliproteins and phycobilina. Chemistry and Biochemistry of Plant Pigments. New York: Academic Press, 1976, 328-376.
17. Siegelman H. W, Kycia J. H. Handbook of phycological methods. Cambridge University Press, 1978: 72-145
1.阿伯特·莱特.蛋白质的结构与功能.北京,高等教育出版社,1982:163-165
2.卞则梁.质谱与蛋白质(肽)的序列结构测定.现代科学仪器,1997,3:15-18
3.陈惠黎,李茂深.生物大分子的结构和功能.上海,复旦大学出版社,上海医科大学出版社:4-9
4.郭寅龙,刘晗青等.液相色谱/电喷雾质谱(LC/ESI/MS)在蛋白质分析鉴定中的应用.分析测试技术与仪器,2001,7(3)129-133
5.何照范.保健食品化学及其检测技术.北京,中国轻工业出版社,1998:151
5.陶慰孙.蛋白质分子基础.北京,人民教育出版社 1981:98
6.王京兰,万晶宏.蛋白质组研究中肽质量指纹谱鉴定方法的建立及应用.生物化学与生物物理学报 2000,32(4):373-378
7.张惟杰.糖复合物生化研究技术.浙江,浙江大学出版社,1999,第二版:129
8.周国华,罗国安.基体辅助激光解吸质谱法在生物大分子质量研究中的应用.药学学报,1998,33(4):290-295.
9. Brown RS. Lermon J J. Anal. Chem. ,1995, 67:3990-3999
10. Chait B T. Wang R, Veavis R C, Kent S B H. Science. 1993,262:89-9223
11. Fenn JB, Mann M, Meng CK, Wong SF, Whitehouse CM. Electrospray ionization for mass spectrometry of large bimolecular. Science, 1989, 246:64-71
12. F. Hillenkamp. M. Karas. R. C. Bcavis. B. T. Chait, Anal. Chem. 1991, 63. 1193A
13. Jungblut Peter, et al. Protein identification from 2-DE gels by MALDI mass spectrometry. Mass Spectrum. Rev. , 1997,16(3): 145-162
14. Kaufmann R, Kirsch D, Spengler B. Int, J. Mass Spectrum. Ion Processes. 1994, 131:355-385
15. Rohin Mhatre, James Woodard, Chenhui zeng. Strategies for locating disulfide bonds in a monoclonal antibody via mass spectrometry. Rapid Commun. Mass Spectrum. , 1999,13(24):2502-2510
16. Simon Elstrcem. et al. Integrated micro analytical technology enabling rapid and automated protein identification. Anal. Chem. ,2000,72(2):286-293
17. Spengler B,Lutzenkirchen F, Kaufmann R. Org. Mass Spectrom., 1993,28:1482-1490
13. Stults J T. Matrix-assisted laser desorption/ionization mass spectrometry (MALDI-MS). Curent Opinion in Structural Biology,1995,5(5):691-698
18. Thomas P Conrads, Gordon A Anderson, Timothy D Veenstra, Ljiljana Pass Tolic, Richard Smith. Utility of accurate mass tags for proteome wide protein identification. Anal. Chem. ,2000,72(14):3349-3354
19. Wang J L, Cai Y, Wang J, Daong F T, Qian XH. Preliminary application ofpeptide mass fingerprinting technique in proteomere search. Bull Acad Mil Med Sci,1999,23(1):71-72
20. Wilkins MR, Gooley AA. In: Wilkins MR, Williams KL, Appel RD, Hochstrasser Dfeds, Proteome Research: New frontiers in functional gene mice, Berlin: Springer Vedag, 1997,35-61
21. Wise MJ, Littlejohn TG, Humphery Smith I. Peptide mass fingerprinting and the ideal coving set for protein characterization electrophoresis, 1997,18(8):1399-1409
22. Whitehouse CM, Dryer RN, Yamashita M, Feun JB. Electrospray interface for liquid chromatographs and mass spectrometers. Anal. Chem. , 1985,57:675-679
23. Wu J, Gage D A, Watson J T. Anal. Biochem., 1996, 235:161-174
24. Yiping Sun, Mark D Bauer, Weiping Lu. Identification of the active site serine of penicillin-biding 2a from methicillin-resistent staphylococcus aurous by electresprar mass spectrometry . J. Mass Spectron. ,1998,33(10):1009-1016
1.陈真龙,丁兰等.皖南尖吻蝮蛇蛇毒出血毒素Ⅲ的荧光淬灭研究.淮海工学院学报,1998,7(3):32-36
2.高体玉,李俊等.乳腺癌组织中蛋白质二级结构的Fourier变换红外光谱研究.分析科学学报,2000,16(5):353-357
3.黄文.白果活性蛋白的分离、纯化、结构及其生物活性研究.[华中农业大学博士毕业论文],2000,112
4.林青松,颜思旭.中华猕猴桃蛋白酶在甲醇溶液中的构象与活力变化研究.厦门大学学报(自然科学版),1994,33(1):100-104
5.林波海.蛋白质二级结构的真空紫外圆二色性研究.生物化学与生物物理进展,1994,21(1):67-69
6.刘清亮,吴双顶等.皖南尖吻蛇毒糖坩水解酶的荧光光谱研究.无机化学学报,1998,14(1):53-57
7.鲁子贤,崔涛,施庆洛.园二色性和旋光色散在分子生物学中的应用.北京:科学出版社,1987:82—133
8.沈漪,方文汉.蛋白质一级结构测定的新进展.中国医药工业杂志,2002, 33(10):514-518
9.陶慰孙等编著.蛋白质分子基础.北京:人民出版社,1981,42-54
10.王广策,邓田,曾呈奎.藻胆蛋白的研究概况(Ⅱ)—藻胆蛋白的结构及其光谱特性.海洋科学,2000,24(3):19-22
11.王槐春.蛋白质与核酸序列分析基础。北京:人民军医出版社,1994
12.王守业,徐小龙.荧光光谱在蛋白质分子构象研究中的应用.化学进展,2001,7(4):257-260
13.赵辅昆,徐松琴等.蛇肌果糖1,6-二磷酸脂酶的R态和T态的构象.生物化学与生物物理学报,1994,26(5):525-533
14.周瑞明,沈永嘉.蛋白质二级结构的红外光谱.华东理工大学学报,1997,23(4):422-425
15.祝大昌,陈剑宏等.分子发光分析法。上海:复旦大学出版社,1985
16.阎隆飞等编著.蛋白质分子结构.北京:清华大学出版社,1999.123-146
17.颜思旭,刘红兵.缢蛏碱性磷酸酶胍溶液中分子折叠与活力变化研究.生物化学杂志,1994,10(3):402-406
18.杨家祥,张玉慧等.荧光光谱在蛋白质分子构象研究中的应用.淮海工学院学报,1999,8(4)
19. Compton L A. Johnson W C. Anal Biochem, 1986, 155-156
20. Canaoni O D, Elisabeth G. Circular dichroism and polarized fluorescence characteristic of blue-green algal allophycocyanins. J. Biochem, 1980, 19:2950-2956
21. Compton.L A, Johnson W C. Anal Biochem,1986:155-156.
22. Eftink M R, Ghiron C A. Biochemistry, 1976, 15 (3): 672-680
23. Johan A, Hellebust J. S. Craigie, Handbook of phycological methods Physiological and biochemical methods. Cambridge University press, 1978, 72-80
24. Johnson M S, Srinivassn N, Sowdhamini R et al. CRC Crit Rev Biochem Ml Biol. ,1994,29:1
25. Lakowics J R, Principles of fluorescence spectroscopy. New York: Plenum Press, 1983, 281
26. Parker F S. Application of Infrarel, Raman and Reaomance Raman Spectroscopy in Biochemistry New York: Plenum Press. 1983:83-102
27 . Prestrelski S J, Arakawa T, Carpenter J F. Acrd. Biochem Biophys, 1993, 303: 46
1.隋正红,张学成.藻红蛋白研究进展.海洋科学,1998,24(4):24-27
2.刘鲁宁,黄芳,黄业立.螺旋藻酒中藻蓝蛋白稳定性影响因素的研究.酿酒,2004,31(3):43-44
3.刘旭川,李琦华.螺旋藻藻蓝蛋白提取及稳定性试验.云南大学学报(自然科学版),1999,21(3):230-232
4.余九九,李宽钰,吴庆余.螺旋藻的藻胆蛋白提取及稳定性研究.海洋通报,1997,16(4):26-285
5.吕彩真,欧光南.红毛菜藻红蛋白的提取及稳定性研究.集美大学学报(自然科学版),2002,7(1):15-196
6.张玉忠,周百成,曾呈奎.钝顶螺旋藻藻胆体的简易制备及褐藻酸钠对其稳定性的保护作用.海洋科学,1997,6:39-42
7.张熙颖,刘鲁宁,陈秀兰.钝顶螺旋藻藻胆体的稳定性研究.海洋科学.2004,28(8):38-46
8.杨忠慧,王淑芝,路荣昭.藻胆体稳定性的研究—pH对藻胆体稳定性的影响.首都师范大学学报(自然科学版),1994,15(4):65-69
9. Katoh T. Phycobilisome Stability. Meth in Enzymol, 1988, 167:313-318
10. Richard J R. Algal diversity and commercial algal products. Bio. Science, 1996,46(4): 263-270
11. Siegelman H.W, Kycia.J.H, Handbook of phycological method. Cambridge university Press. 1978.72-114
1.陈美珍,张永雨,余杰.龙须菜藻胆蛋白的分离及其清除自由基作用的初步研究.食品科学,2004,25(3):159-162
2.凌关庭.天然抗氧化剂及其清除氧自由基的进展.食品工业,2000,(3):19-22
3.罗广华,王爱国,柯德森.海藻中清除氧自由基的物质.热带亚热带植物学报,1998,6(1):15-18
4.胡春,丁霄霖.用化学发光法研究黄酮化合物对O_2和OH的清除.无锡轻工大学学报,1996,15(3):194-198
5.唐玫,王曼,郭宝江.富硒藻蓝蛋白对小鼠免疫功能及抗氧化活性的影响.营养学报,2001,3(3):275-278
6.田云,卢向阳,易克.天然抗氧化剂清除氧自由基的能力.湖南农业大学学报(自然科学版),2004,30(3):209-211
7.赵保路.氧自由基与天然抗氧化剂.北京:科学出版社,2001
8.邹国林,桂兴芬,钟晓凌.一种SOD的测定方法——邻苯三酚自氧化法的改进.生物化学与生物物理进展,1986,13(4):71-73.
9.钟进义,王传现,王建华.化学发光法测定葡萄多酚对超氧阴离子自由基的清除.中华预防医学杂志,2001,35(3):350
10.王少敏.李萍.赵明强.生物化学发光法测定酸仁的抗氧化活性.中草药,2003,34(5):417-419
11.魏玉西,徐祖洪.褐藻中高相对分子质量褐藻多酚的抗氧化活性研究.中草药,2003,34(4):317-319
12.夏其乐,陈健初,吴丹.杨梅叶提取物抗氧化活性的研究.食品科学,2004,25(8):80-83
13.严建刚,张名位,杨公明.芹菜提取物清除自由基作用研究.食品科学,2004,25(8):39-42
14. Larrauri J A, Sanchex-Moreno C, Saura-Calixto F. Effects of temperature on the free radical scavenging capacity of extracts from red and white grape pomace peels. J Agric Food Chem, 1998, 46 (7): 2694-2697.
15. Scartezzini P, Speroni E. Review on some plants of Indian traditional medicine with antioxidant activity. J. Ethnopharmacol, 2000, 71 (12): 23-43.
16. Yokozawa T, Dong E, Natagawa T, et al. Invitro and invivo studies on the radical-scavenging activity of tea. J. Agric Food Chem, 1998, 46 (6): 2143-2150.
17. Yu G l,Lu Z H , Wang S G , et al. Antioxidative activity of alga (Sagassum kjllmaniaman) extracts to unsaturatelipids. J Ocean Univ Qingdao(青岛海洋大学学报), 2000, 30(1): 75-80
1.鲍时翔,姚汝华.蛋白质分离纯化与层析技术进展,华南理工大学学报(自然科学版),1996,24(12):98-103
2.曹书霞,赵玉芬.分子吸收光谱在生物大分子研究中的应用,2004,24(10)1197-1200
3.成海平,钱小红.蛋白质组研究的技术体系及其进展.生物化学与生物物理进展,2000,27:584-588.
4.陈绍农,潘远江,陈耀祖.多肽及蛋白质质谱分析新进展.质谱学报,1995,16(3):15-21
5.陈晶,付华,陈益.质谱在肽和蛋白质序列分析中的应用.有机化学,2002,22(2):81-90
6.徐友宣,彭师奇.蛋白质及多肽的液相色谱.电喷雾离子化质谱研究进展.药学学报,1997,32(10):792—799
7.[德]坎普,[希腊]乔里-帕帕多普洛编著;施蕴渝译蛋白质结构分析:制备、鉴定与微量测序.北京:科学出版社,2000:197-210
8.邓慧敏,赖志辉,黎军.延迟引出基体辅助激光解吸/电离质谱(DE—MALDI—MS)法高分辨率测定混合碱基DNA的研究.质谱学报,2000,21(1):1-5
9.顾宁琰,刘宇峰.紫球藻生物活性物质及其应用.中国海洋药物,2001,84(6):43-48
10.方晔,王霆.白春礼等,银胶中三螺旋RNA poly(rU).poly(rA).poly(rU)的付立叶表面增强拉曼光谱研究.生物物理学报,1995,11(2):149-155
11.傅晓红,林其谁.胆碱脱氢酶光谱性质的研究,生物化学与生物物理学报,1997,29(2):213-218
12.高宏,周群,郁鉴源.生物物理学报,1999.15(3):445-450
13.郭尧君.荧光实验技术及其在分子生物学中的应用.北京:科学出版社,1979:136-137
14.郭云昌,蔡颖谦,中岛秀郎.原子力显微镜在DNA研究中的应用.现代科学仪器.2005(3):71-72
15.龚海霞,陈荣华,郭锡熔.蛋白质组技术及其在临床医学领域的运用.国外医学儿科学分册,2001;28(6):287-289
16.韩俊,杨仲元,盛龙生等.电喷雾离子化质谱法及其在药物与生物大分子分析中的应用.药物分析杂志,2001,21(3):212-217
17.何靳安,蒋丽金,江龙.藻胆蛋白的langmuir-Blodgett膜——R-藻红蛋白单分子膜及蛋白构象变化的研究.中国科学B辑,1996,26(2):111-116
18.何美玉,王光辉,熊少祥.现代生物质谱及其应用.现代仪器,2001(1):6—8
19.黄珍玉,于雁灵,方彩云.质谱鉴定磷酸化蛋白研究进展.质谱学报,2003;24(4):494-500
20.李冠武,王广策.多管藻R-藻红蛋白的激光光敏作用对体外培养的肿瘤细胞生仔的影响.激光生物学报,1997,6(3):11-19
21.李蓉,梁恒.生物质谱-蛋白质组研究的关键技术.化学通报,2002,11:748-752 28
22.李永民.生物质普.分析测试技术与仪器,2002,8(2):131—135
23.粱栋材,常文瑞,江涛.R—藻红蛋白三维结构研究,生命科学,1998,10(5):207-209
24.凌晓锋,李维红,宋苑苑 等.光谱学与光谱分析,2000,20(5):692-693
25.代连花,戴国亮.激光扫描共聚焦显微镜在蛋白质晶体生长研究中的应用.激光生物学报 2004,13(3):210-213
26.刘东升,王金凤.结构基因组学研究与核磁共振.生物化学与生物物理进展,2001,28(6):827-831
27.刘慧敏,赖志辉,黎军.碎片结构分析在MALDIT-OF-MS法测定多肽序列中的应用.生物化学与生物物理学报,2000,32:179-182
28.刘锦玉,张季平.万柱礼等.条斑紫菜变藻蓝蛋白立方晶系的初步晶体学研究.科 学通报,1997,42(12):1321-132
29.路荣昭,李凤平,顾天青.嗜热蓝藻层理鞭枝藻(MastigoCladus laminosus)藻胆体在解离过程中荧光发射光谱和光能传递的研究.生物物理报,1996,12(3):494-498
30.鲁子贤,崔涛.园二色性和旋光色散在分子生物学中的应用,北京:科学出版社,1987
31.吕茂民,章金刚.生物质谱技术及其应用.生物技术通报,2001(4):38—41
32.吕正检,王建华,徐世荣.原子力显微镜在医药学研究中的应用.中国医药杂志.2006,41(7):490-492
33.马聪,周明,张富铁等.藻红蓝蛋白裂合异构酶E基因突变体的构建、表达与酶活性检测.水生生物学报,2003,27(6):614-618
34.彭卫民,商树田,刘国琴等.螺旋藻藻胆蛋白研究进展(综述).农业生物技术学报,1998,6(2):173-177
35.钱小红.蛋白质组与生物质谱技术.质谱学报,1998,19(3):48—55
36.邱冠英,彭银祥.生物物理学.武汉:武汉大学出版社,2000
37.盛树斌,张富铁,邓明刚等.层理鞭枝藻藻红蓝蛋白E基因片段的克隆和表达.水尘生物学报,2001,25(4):427-430
38.宋波,朱菁萍,周明等.藻蓝蛋白和藻红蓝蛋白β-亚基半胱氨酸的定点突变及体外重组研究.水生生物学报,2004,28(4):344-348
39.司英健.蛋白质组学研究的内容、方法及意义.国外医学临床生物化学与检验学分册,2003;24(3):167-168
40.沈漪,方文仅.蛋白质一级结构测定的新进展.中国医药工业杂志.2002,33(10):514-518
41.沈星灿,梁宏,何锡文等.园二色光谱分析蛋白质构象的方法及研究进展,分析化学.2004,32(3):388-394
42.许克新,王云川.双向电泳及质谱分析与蛋白组研究.第四军医大学学报,2002;23(22):2017-2022
43.许崇峰,杨原,岳贵花.基于质谱的DNA序列测定进展.化学通报,2000,63(2): 20—24
44.谭君.祝连彩,拉曼光谱在结构生物学中的应用.重庆教育学院学学报,2004,17(3):49-52
45.童义平.李伟,林燕文.傅里叶红外光谱研究血清白蛋白构象,光谱学与光谱分析,1999,19(5):704-706
46.王征,阮幼冰,官阳.肝细胞癌患者血清蛋白质组成分的双向凝胶电泳.飞行时间质谱分析.中华病理学杂志,2003;32(4):333-336
47.王斌,王靖,余江.FT-Raman光谱研究溶菌酶在氘代甲醇溶液中的构象变化.光谱学与光谱分析,1999,19(4):674-676
48.王广策,周百成,曾呈奎.B-藻红蛋白和R-藻红蛋白γ亚基的分离、特性及其在分子中的空间位置分析.中国科学(C辑),1998,28(1):36-41
49.王广策,邓田,曾呈奎.藻胆蛋白的研究概况(Ⅱ)—藻胆蛋白的结构及其光谱特性.海洋科学,2000,24(3):19-22
50.王杰芳,杨柳,李富广.质粒pUC18DNA的傅立叶变换拉曼光谱研究.激光杂志,200122(1):44-45
51.王长海,李叙风.紫球藻及其应用研究.海洋通报,1998,17(3):79-82
52.王长海,温少红,欧阳藩.紫球藻的生物活性物制裁.海洋通报,1999,18(3):25
53.王高兰.蛋白质组研究中肽质量指纹谱鉴定方法的建立及应用.生物化学与生物物理学报,2000,32(4):373-378
54.王慧,赵井泉,张建平.螺旋藻藻胆体核心复合物结构与功能的研究——四种变藻蓝蛋白复合物的分离及光谱特性的研究.生物物理学报,1996,12(3):394-400
55.王慧,赵井泉,蒋丽金.多变鱼腥藻胆体模型复合物结构与功能的研究.科学通报,1998,43(6):596-600
56.汪河洲,赵福利,郑锡光.藻红蛋白的微晶激子光谱.科学通报,1995,40(7):650-652
57.汪尔康.21世纪的分析化学.科学出版社,2001:112—120
58.朱菁萍,周明,赵开弘等.藻红蓝蛋白裂合异构酶对几种脱辅基藻胆蛋白的催化作用.生物工程学报,2002,18(6):703-708
59.张景民.赵福利.郑锡光.蓝藻(A.variabilis)藻胆体核结构与功能的研究Ⅱ.变 藻蓝蛋白六聚体内能量传递过程的物理机制.生物物理学报,1999,15(2):393-399
60.张学成,张锦东,隋正红.江蓠属藻胆蛋白的研究——诱变、突变体筛选及藻胆蛋白的光谱特性.青岛海洋大学学报(自然科学版),1996,26(3):318-326
61.张景民,谢洁,张建平.蓝藻(Cyanobacteria)藻胆体内核结构与功能的研究Ⅰ.变藻蓝蛋白六聚体(αβ)_6分离及其表征.生物物理学报,1997,13(3):362-368
62.张建平,张景民,赵井泉.R-藻蓝蛋白的分离及其结构表征.生物物理学报,1997,13(2):173-178
63.张景民,郑锡光,赵福利.C-藻蓝蛋白六聚体内能量传递途径及其机制.中国科学(B辑),1998,28(5):445-452
64.张玉忠,周百成,曾呈奎等.海洋红藻R-藻胆蛋白的扫描隧道显微镜研究.生物物理学报,1997,16(6):723-725
65.张景民,赵井泉,蒋丽金.多变鱼腥藻中藻红蓝蛋白三聚体内能量传递的机制(Ⅱ).中国科学(C辑),1998,28(4):308-312
66.赵福利,郑锡光,汪河洲等.四种别藻蓝蛋白三聚体的时间分辨荧光光谱研究.中国激光,1998,25(4):318-322
67.赵南明,周海梦.生物物理学.北京:中国高等教育出版社,2000
68.郑永红,杨松成.生物质谱技术在蛋白质结构鉴定中的应用进展,中国生化药物杂志,2003,24(6):305-308
69.郑敏,答亮,邓明刚等.层理鞭枝藻藻红蓝蛋白F基因片段的克隆和表达.水生生物学报,2002,26(2):168-174
70.郑伟民,蔡继业.原子力显微镜在DNA领域中研究应用.现代仪器.2006(1):9-12
71.周国华.基质辅助激光解吸质谱法在生物大分子质量研究中的应用.药学学报,1998,33(4):290-295
72.周毅峰 吴永尧 唐巧玉,生物质谱在生命科学中的应用,湖北民族学院学报(自然科学版),2004,22(2):11-16
73.周瑞明,沈永嘉.蛋白质二级结构的红外光谱,华东理工大学学报,1997,23(4):422-425
74.邹国林.周祥,郑忠亮.蛋白质结构研究技术的发展,信阳农业高等专科学校学报,2003,13(4):1-3
75.吴世容,李志良.李根容.生物质谱的研究及其应用.重庆大学学报,2004,27(1):123-127
76.解建勋,蒲小平.李玉珍.蛋白质组分析技术进展.生物物理学报,2001,17:19-26
77.魏开华,杨松成,王红霞.转印到膜上的蛋白质的质谱分析.质谱学报,2000;20(3,4):89-90
78.邬江,朱家恺,许扬滨.细胞源神经营养蛋白的质谱分析.中华显微外科杂志,2002,25(4):271-273
79.向洋,激光生物学.长沙:湖南科学技术出版社,1995 80.
80.应万涛,钱小红.生物质谱应用技术及进展.军事医学科学院院刊,2000,24(2):146-150
81.阎隆飞,孙之荣.蛋白质分子结构.北京:清华大学出版社,1999
82.杨频,高飞.生物无机化学原理,北京:科学出版社,2002
83.杨铭,结构生物学概论,北京:北京医科大学出版社,2002
84.余多慰.柯惟中,纤维与水溶液状态下DNA空间构象的激光拉曼光谱分析,光散射学报,1995,7(1):24-29
85.袁湘林,邹汉法.基质辅助激光吸电离飞行时间及其在高分子量物质测定中的应用.分析化学,1998,26(2):234—238
86.庄华梅,何德.核磁共振技术及其在生命科学中的应用,生物磁学,2005,5(4)
87. Andrew N. Round, Alistair J. MacDougall, Stephen G. Ring,Victor J. Morris. Carbohydrate Research, 2001, 331:337-342
88. Aritake M,Noriko F, Mitsuhiko A et al. Changes of Secondary Structure Detected by Raman Spectroscopy in Model Peptide of αAcrystalline Due to Substitution of D-Aspartyl Residues for L-Aspartyl Residues. Jpn. J. Ophthalmol. 2000,44:354-359
89. Barber M. Bordoli R S. ,Sedgwick R D., Tyler A N. Fast atom bombardment of Solids(F. A. B.): A New Ion Source for Mass Spectrometry. J. Chem. Soc. Commum, 1981,325-327
90. Bennitt A. Properties of subunits and aggregates of blue-green algal biliproteins. J. Biochenmistry, 1971,10: 3625-3634
91. Bidan G, Billon M Galasso K, et al. Electropoly merization as a versatile route for immobilizing biological species onto surfaces. Application to Dnabiochips. Appl Biochem Biotechnol, 2000, 89(2-3): 183-93
92. Chen R, Cheng X, Mitchell D W et al. Trapping, detection, and mass determination of coliphage T4 DNA ions of 10**8 Da by electrospray ionization fourier transform ion cyclotron resonance mass spectrometry. Anal. Chem. ,1995, 67(7): 1159-1163
93. Chen X G,Li P S,Holtz J S W et al. Resonance Raman examination of the Electronic Excited States of Glycylglycine and other Dipertides Observation of a Carboxylate Amide Charge Transfer Transition. J. Am. Chem. Soc. ,1996,118:9705-9715
94. Chen X G,Reinhard S S,Mirkin R et al. N-Methylacetamide and Its Hydrogen-Bonded Water Molecules Are Vibrationally Coupled. J. Am. Chem. Soc. ,1994,116:11141-11142
95. Chen X G, Reinhard S S , Mirkin R et al. UV Raman Determination of theπ-π* Excited State Geometry of N-Methylacet acide: Vivrational Enhancement Pattern. J. Am. Chem. Soc. ,1995,117:2884-2895
96. Cheung C L ,Hafner J h ,Lieber C M ,Carbin nanotube force microscopy tips:direct growth by chemical vapor deposition and application to high-resolution imaging. Procnatl Acad Sci USA ,2000,97(8):3809
97. Debreczeny M P, Sauer K, Zhou J and Bryant DA. Comprison of calculation and experimentally resolved rate constants for excitation energy transfer in C-PC. J. Phys. Chem. ,1995,99:8420-8431
98. Drake B, Prater C B, Weisenhorn A L, et al. Imaging crystals polymers and processes in water with the atomic force microscope. Science, 1989,243:1586
99. Epand R F , Yip C M ,Chernomordik L V ,et al. Self-assembly of influenza hemagglutinin:study of ectodomain aggregation by in situ atomic force microscopy. Biochem BiophysActa, 2001, 1513(2):167
100. Edman P, Begg G. A p ro tein sequenator. Eur J Biochem. 1967, 1(1): 80291
101. Griffin T J, Gygi S P, Rist B et al. Collaborative exercise on the use of FISH chromosome painting for retrospective biodosimetry of Mayak nuclear-industrial personnel[J]. Anal. Chem. ,2001, 73 (5): 978-986
102. G Bining, CF Quate, C Gerber. Atomic force microscope. Phys Rev Leit,1986,56:930-933
103. Glazer A N, et al. Charaterization of R-phycocyanin, Chomophore cotent of R-phycocyanins and C-phycoerythin. Biol. Chem, 1975, 256(14):5487-5495
104. Harourt R D, Scholes G D, Ghoggino. R ate expressions for excitation transfer II,Electronic considerations of direct and through configuration excite on resonance interactions. J. Chem. Phys, 1994, 101(12): 10521-10525
105. HarveyDJ. Identification of protein-bound carbohydrates by masss pectrometry. Proteomi c, 2001; 1(2):311-328
106. Karasm,Hillenkampf. Laser desorption ionization of proteins with molecular masses exceeding 10000 daltons. Anal. Chem, 1988, 60:2299-2301
107. Karoly C, Robert M. Exciton interaction in alloph ycocyanin. Biochemistry,1984,23:6466-6470
108. Kurian E, Prendergast F G, Tomlinson A J ,et al. Photoacoustic analy sis of proteins:volumetric signals and fluorescence quantum yields. Mass Spectrom, 1997, 8 (1):8-14
109. Kuznetsov Y G, Malkin A J, McPherson A. Sself-repair of biological fibers catalyzed by the surface of a virus crystal. Proteins, 2001,44(3):392-396
110. Kuznetsov Y C ,Malkin A J ,Lucas R W ,et al. Imaging of viruses by atomic force microscopy. J Cen Virol ,2001,82:2025
111. Lakowicz J R. Principles of fluorescence spectroscopy. New York:Plenum Press. 1983: 257-295
112. Lay. MALDI-TOF mass spectrometry of bacteria. MassSpectromRev, 2001; 20(4): 172-194
113. Lazer A N. Formation of hybrid protein from the aand Psubunit of phycocya-nins of unicellular and filamentous, blue-green algal. Biol. Chem, 1973,248:663-671
114. Macfarlane R D. , Torgerson D f. ,Californium-252 Peroration Mass Spectroscopy. Science, 1976,191:920-925
115. March RE J. Observation of apigenin anionic clusters in the gas phase. Mass Spectrom, 1996,32: 315
116. Medzihradszky K F, Cempbell J M, Baldwin M A et al. Copper binding to octarepeat peptides of the prion protein monitored by mass spectrometry. Anal. Chem. ,2000,72(3): 552-558
117. Paige M F ,Rainey J K. A study of fibrous long spacing collagen ultrastructure and assembly by atomic force microscopy. Micron,2001,32(3):341-353
118. Rebolloso Fuentes M M, Acien Fernandez G G. Biomass nutrient profiles of the microalga Pcruentum. Food Chemistry, 2000, 70(3): 345
119. Pilot T J, Fox J L. Cloning and sequencing on the genesencoding the aand Psubunits of C-phycocyanin from the Cyanobacterium Agmenilum qadruplicatum. Proc Natl Acad Sci USA, 1984, 81: 6983-6987
120. Sandstrom A, Gillbro T, Sundstrom V. Picosecond study of energy transfer within 18-Sparticles of AN112(amutant of Synechococcus 6301) Pphycobilisomes. Biochem,Biophys. Acta, 1998, 933: 54-64
121. Scholes G D, Ghoggino. Rate expressions for excitation transfer, Radiation less transition theory perspective. J Chem Phys, 1994, 101(2): 1251-1261
122. Shapiro L. ,Scherer P E. The crystal structure of a complement-1q family protein suggests an evolutionary link to tumor necrosis factor. Curr Biol. ,1998,8(6):335-338
123. Shevchenko A, Loboda A, Ens W et al. LC/MS Analysis of NAD Biosynthesis Using Stable Isotope Pyridine Precursors. Anal. Chem. , 2000, 72 (9): 2132—2141
124. Song S H, Asher S A. UV Resonance Raman Studies of Peptide Conformation in Poly(L-lysine), Poly(L-glutamic acid),and Model Complexes: the Basis for Protein Secondary Structure Determinations. J. Am. Chem. Soc. ,1989.111:4295-4305
125. Stolz M. Stoffler D. Aebi U, et al. Monitoring biomolecular interactions by time-lapse atomic force microscopy. J Struct Biol, 2000,131(3): 171-180
126. Wilm M. Shevchenko A, Ole Vorm et al. Linking genome and proteome by mass spectrometry: Large-scale identification of yeast proteins from two dimensional gels. Nature 1996: 379, 466
127. Wise M J. Littlejohn T G. Measurement of shallow arsenic impurity profiles in semiconductor silicon using time-of-flight secondary ion mass spectrometry and total reflection x-ray fluorescence spectrometry. Electrophoresis, 1997, 144(11): 1399-1409
128. Yau S T, Vekilov P G. Direct observation of nucleus structure and nucleation pathways in apoferritin crystallization. J. Am Chem Soc,2001,123(6): 1080-1089
2.陈德文,潘思轶,汪兴平.葛仙米的研究现状及应用前景.食品科学,2003,24(1):153-156
3.湖北省鹤峰县史志编纂委员会.鹤峰县志.武汉:武汉人民出版社,1990,476-498
4.刘金龙,葛仙米营养成分分析.中草药,31(11):2001,862-863
5.莫开菊,谢笔均,汪兴平.葛仙米多糖的提取、分离与纯化技术研究.食品科学,2004,24(10):103-108
6.彭卫民,商树田.螺旋藻藻胆蛋白研究进展(综述).农业生物技术学报,1998,6(2):173-177
7.全国中草药汇编.北京:人民卫生出版社,1983
8.谭学儒.葛仙米.土特产,20003:30-30
9.尤崇杓等编.生物固氮.北京:科学出版社,1987,159-192
10.王广策,邓田,曾呈奎.藻胆蛋白的研究概况(Ⅰ)——藻胆蛋白的种类与组成.海洋科学,2000a,24(2):22-25
11.王广策,邓田,曾呈奎.藻胆蛋白的研究概况(Ⅱ)——藻胆蛋白的结构及其光谱特性.海洋科学,2000b,24(3):9-22
12.夏建荣,高坤山.念珠藻葛仙米营养成分分析.武汉植物研究,2002,20(3):223-224
13.杨春澍主编.药用植物学.上海:上海科技出版社,2001,130-131
14.杨世杰等编.植物生物学.北京:科学出版社,2000,294-296
15.朱浩然主编.中国淡水藻志(第二卷).北京:科学出版社,1991,1-10
16. http://www.hbhf-ca.com, 2003
17. http://www.singtaonet.com/singtaonet/head_sp/t20051010_10802.html
18. Huang Z B, Liu Y D, Paulsen B S. Studies on polysaccharides from three edible species of Nostoc (Cyanobacteria)with different colony morphologies: comparison of monosaccharides composition and viscosities of polysaccharides from field colonies and suspension cultures. Phycology, 1998,34(7):962-968
19. Johan A, Hellebust, J. S. Craigie. Handbook of phycological methods—Physiological and biochemical methods. Cambridge University press, 1978:48-76
20. Li D H, Liu Y D, Song L R, Hormogonia mass differentiation from Nostoc sphaeroides Kutz. (cyanobacterium)and comparison of structural charatedstics between hormogonia and vegetative filaments. Phycological Research, 2001,49(2): 81-8
21. Siegelman H W, Kycia J H. Handbook of phycological methods. Cambridge University Press, 1978:72-145
1.湖北省鹤峰县史志编纂委员会.鹤峰县志.武汉:武汉人民出版社.1990:476-498
2.全国中草药汇编编写组.全国中草药汇编.北京:人民卫生出版社,,1978,704
3.王莹,辛士刚.ICP-AES法测定豆类食品中的微量元素光谱学与光谱分析,2004,24(2):226-228.
4.杨春澍主编.药用植物学.上海:上海科技出版社.2001;130~131.
5.杨世杰等编.植物生物学.北京:科学出版社.2000;294~296.
6.张威,朱劲华,王敏.极大螺旋藻胞内多糖分离纯化及其结构的初步分析.天然产物研究与开发,2004,16(6):548-551.
7.朱浩然主编.中国淡水藻志(第二卷).北京:科学出版社,1991,1-10.
8.鞠兴荣,袁建.食品中限量元素分析样品的预处理技术进展.食品科学,2004,25(2):199-203
9. Huang Z B, liu Y D, Paulsen B S. Studies on polysaceharides from three edible species of Nostoc (Cyanobacteria) with different colony morphologies: comparison of monosaccharides composition and viscosities of polysaccharides from field colonies and suspension cultures. J.Phycology, 1998, 34:9629-68
10. Lazaroff N, Vishniac W. The effect of light on the developmental cycle of Nostocmuscorum, a filamen blue-green algae. J.gen.Microbiol, 1961a, 25:365-374
11. Lazaroff N, Vishniac W. The effect of light on the developmental cycle of Nostocmuscorum, a filamen blue-green algae. J.gen.Microbiol, 1961b, 28:203-210
12. Li D H, Liu Y D, Song L R. Hormogonia mass differentiation from Nostoc Sphaeroides Kutz(cyanobacterium) and comparison of structural charateristics between hormogonia and vegetative filaments.Phycological Research, 2001, 49(2): 81-87
13. Poeggler B, Reiter RJ, Tan DX, et al. Melatonin, hydruxyl radical-medixted oxidative clarnage, and aging: Ahypothesis. J Pineal Res, 1993, 14 (2): 151-168
14. www.hbhf-ca.com, 2003
1.陈曾兰.12种氨基酸混合物的生理功能研究.杭州食品科技,2001,(2):11-14
2.苟大明,余志豪.L-精氨酸对体外循环中红细胞保护作用的研究.2001,25(9):771-773
3.韩雅珊主编.食品化学实验指导.北京:北京农业出版社,1992,4
4.何照范,张迪清.保健食品化学及其检测技术.中国轻工业出版社,1999
5.黄耀凌,邹思湘.谷氨酰胺的抗疲劳生化机制研究.南京农业大学学报,2001,24(2):87-89
6.胡朝辉,刘志礼.极大螺旋藻中-胡萝卜素的分离的纯化及定量测定.色谱,2001(11):85-87
7.李敦海,刘永定,宋立荣,盐胁迫对葛仙米生理生化特性的影响,水生生物学报,1999(5):414-418
8.李合生主编,植物生理生化实验原理和技术.高等教育出版社,2000
9.青胜兰,陈玉祥.精氨酸在大肠癌的应用.大肠肛门病外科杂志,1999,5(4):24-25
10.全国中草药汇编,人民卫生出版社,1983
11.谭学儒,葛仙米简介,中国食物与营养,1998(5):45
12.王莹,辛士刚.ICP-AES法测定豆类食品中的微量元素.光谱学与光谱分析,2004,24(2):226-228
13.王大志,彭光跃.海水小球藻脂肪酸组成研究.海洋科学.1999(4):68-70
14.孟庆勇,刘志辉,徐美奕.半叶马尾藻多糖的提取和分析.光谱学与光谱分析,2004,24(12):1560-1562
15.吴烈钧.气相色谱检测方法.化学工业出版社,2001
16.无锡轻工业学院,天津轻工业学院合编,食品分析,北京:中国轻工业出版社,1994:209,223
17.于世林编著.高效液相色谱方法及应用.北京:化学工业出版社,2001:35-36
18.张意静.食品分析.北京:轻工业出版社,1999:143-190
19.鞠兴荣,袁建.食品中限量元素分析样品的预处理技术进展.食品科学,2004, 25(2):199-203
20.周亚魁,刘权焰.不平衡氨基酸对肿瘤生长的影响.中国临床营养杂志,2001,9(2):103-105
21. Poeggler B., Reiter R J., Tan D X., et al. Melatonin, hydruxyl radical-medixted oxidative clamage, andaging: Ahypothesis. J Pineal Res, 1993, 14 (2): 151-168
1.华家柽等编译.使用蛋白质化学技术.上海:上海科学出版社,1982:40-245
2.黄岩,秦利,朱晋昌.红毛菜中两中不同分子量的R-藻红蛋白的性质比较.生物物理与生物化学.1993,25(7):434-440
3.纪明侯.海藻化学.北京:科学出版社,1997 485-506
4.李邵蓉,林惠民.Rhodosorusmarinus中藻红蛋白的纯化及其性质的研究.水生生物学报.1996,20(9):257-264
5.陶慰孙等编著.蛋白质分子基础.北京:人民出版社,1981:45-64
6.王广策,邓田,曾呈奎.藻胆蛋白的研究概况(Ⅰ)-藻胆蛋白的种类与组成.海洋科学.2000,24(2):22-25
7.王盛,吴祖建,林奇英.珊瑚藻藻红蛋白分离纯化及光谱学特性.福建农林大学学报(自然科学版),2002,31(4):495-499
8.余家林编著.农业试验多元统计.北京:北京农业大学出版社,1993:91-141
9.赵永芳.生物化学技术原理及应用(第二版).湖北:武汉大学出版社,1994,25-42
10. Canaani O D, Elisabeth Gantt. Circulardichroism and polarized fluorescence characteristics of blue-green alga allophycocyanins. Biochem, 1980, 19: 2,950-2,956.
11. Jean-Claude Thomas, Chantal Passaquet. Characterization ofa phycoerythrin without α-Subunites from a unicellular red alga. J Biol Chem. 1999, 274(4): 2472-2482
12. MacColl R, Eisele E, Williams C, et al. The discovery of a novel R-phycoerythrin from a matarctic red alga. J Biol Chem. 1996,271(29): 17,157-17,160
10. O'Carra P, O'hEocha C. Algal biliproteins and phycobilins. Chemistry and Biochemistry of plant Pigments. NewYork:Academic Press, 1976, 328-376
1.鲍时翔.姚汝华.蛋白质分离纯化与层析技术进展.华南理工大学学报(自然科学版),1996,14(12):98-103
2.胡一兵,胡鸿钧,李夜光.从一种富含藻胆蛋白的螺旋藻中大量提取和纯化藻蓝蛋白的研究.武汉植物学研究,2002,20(4):299-302
3.王勇,钱凯先,董强.高纯度藻蓝蛋白分离纯化及光谱特性研究.生物化学与生物物理进展,1999,26(5):457-460
4.汪家政,范明主编.蛋白质技术手册.北京:科学出版,2000,77-89
5.夏其昌.蛋白质化学研究技术与进展.科学出版,1997,21-35
6.曾庆冰,许家瑞,符若文.蛋白质分离色谱填料及其特性.功能高分子学报,2000,13(3):343-348
7.张建平,张景民,赵井泉.R-藻蓝蛋白的分离及其结构表征.生物物理学报,1997,13(2):173-178
8.张养军,蔡耘,王京兰.蛋白质组学研究中的色谱分离技术.色谱,2003,21(1):20-26
9.赵开弘.层理鞭枝藻的藻蓝蛋白和藻红蓝蛋白α-亚基及其色素肽的光化学与光谱性质.武汉大学学报(自然科学版),1998,44(6):757-760
10.赵永芳.生物化学技术原理及其应用.武汉:武汉大学出版社,1994,298-299
11.郑江,高亚辉,王文星.红毛藻中多组分藻胆蛋白及其亚基的分离.中国水产科学,2003,10(4):277-281
12.周志刚,尹长松.富硒极大螺旋藻整细胞、藻胆体及藻蓝蛋白的光谱特性.上海水产大学学报,2002,11(3):208-214
13. Jean-Claude Thomas, Chantal Passaquet. Characterization of a phycoerythrin without α-subunits from a unicellular red alga. J Biol Chem, 1999, 274 (4): 2472-2482.
14. Johan A, Hellebust J. S. Cralgie, Handbook ofphycological methods Physiological and biochemical methods. Cambridge University press, 1978, 72-80
15. MacColl, Eisele E, Williams C, et al. The discovery of a novel R -phycoerythrin from an Antarctic red alga. J Biol Chem, 1996, 271 (29): 17157-17160.
16. O'carra P, O'H Eocha. Algal biliproteins and phycobilina. Chemistry and Biochemistry of Plant Pigments. New York: Academic Press, 1976, 328-376.
17. Siegelman H. W, Kycia J. H. Handbook of phycological methods. Cambridge University Press, 1978: 72-145
1.阿伯特·莱特.蛋白质的结构与功能.北京,高等教育出版社,1982:163-165
2.卞则梁.质谱与蛋白质(肽)的序列结构测定.现代科学仪器,1997,3:15-18
3.陈惠黎,李茂深.生物大分子的结构和功能.上海,复旦大学出版社,上海医科大学出版社:4-9
4.郭寅龙,刘晗青等.液相色谱/电喷雾质谱(LC/ESI/MS)在蛋白质分析鉴定中的应用.分析测试技术与仪器,2001,7(3)129-133
5.何照范.保健食品化学及其检测技术.北京,中国轻工业出版社,1998:151
5.陶慰孙.蛋白质分子基础.北京,人民教育出版社 1981:98
6.王京兰,万晶宏.蛋白质组研究中肽质量指纹谱鉴定方法的建立及应用.生物化学与生物物理学报 2000,32(4):373-378
7.张惟杰.糖复合物生化研究技术.浙江,浙江大学出版社,1999,第二版:129
8.周国华,罗国安.基体辅助激光解吸质谱法在生物大分子质量研究中的应用.药学学报,1998,33(4):290-295.
9. Brown RS. Lermon J J. Anal. Chem. ,1995, 67:3990-3999
10. Chait B T. Wang R, Veavis R C, Kent S B H. Science. 1993,262:89-9223
11. Fenn JB, Mann M, Meng CK, Wong SF, Whitehouse CM. Electrospray ionization for mass spectrometry of large bimolecular. Science, 1989, 246:64-71
12. F. Hillenkamp. M. Karas. R. C. Bcavis. B. T. Chait, Anal. Chem. 1991, 63. 1193A
13. Jungblut Peter, et al. Protein identification from 2-DE gels by MALDI mass spectrometry. Mass Spectrum. Rev. , 1997,16(3): 145-162
14. Kaufmann R, Kirsch D, Spengler B. Int, J. Mass Spectrum. Ion Processes. 1994, 131:355-385
15. Rohin Mhatre, James Woodard, Chenhui zeng. Strategies for locating disulfide bonds in a monoclonal antibody via mass spectrometry. Rapid Commun. Mass Spectrum. , 1999,13(24):2502-2510
16. Simon Elstrcem. et al. Integrated micro analytical technology enabling rapid and automated protein identification. Anal. Chem. ,2000,72(2):286-293
17. Spengler B,Lutzenkirchen F, Kaufmann R. Org. Mass Spectrom., 1993,28:1482-1490
13. Stults J T. Matrix-assisted laser desorption/ionization mass spectrometry (MALDI-MS). Curent Opinion in Structural Biology,1995,5(5):691-698
18. Thomas P Conrads, Gordon A Anderson, Timothy D Veenstra, Ljiljana Pass Tolic, Richard Smith. Utility of accurate mass tags for proteome wide protein identification. Anal. Chem. ,2000,72(14):3349-3354
19. Wang J L, Cai Y, Wang J, Daong F T, Qian XH. Preliminary application ofpeptide mass fingerprinting technique in proteomere search. Bull Acad Mil Med Sci,1999,23(1):71-72
20. Wilkins MR, Gooley AA. In: Wilkins MR, Williams KL, Appel RD, Hochstrasser Dfeds, Proteome Research: New frontiers in functional gene mice, Berlin: Springer Vedag, 1997,35-61
21. Wise MJ, Littlejohn TG, Humphery Smith I. Peptide mass fingerprinting and the ideal coving set for protein characterization electrophoresis, 1997,18(8):1399-1409
22. Whitehouse CM, Dryer RN, Yamashita M, Feun JB. Electrospray interface for liquid chromatographs and mass spectrometers. Anal. Chem. , 1985,57:675-679
23. Wu J, Gage D A, Watson J T. Anal. Biochem., 1996, 235:161-174
24. Yiping Sun, Mark D Bauer, Weiping Lu. Identification of the active site serine of penicillin-biding 2a from methicillin-resistent staphylococcus aurous by electresprar mass spectrometry . J. Mass Spectron. ,1998,33(10):1009-1016
1.陈真龙,丁兰等.皖南尖吻蝮蛇蛇毒出血毒素Ⅲ的荧光淬灭研究.淮海工学院学报,1998,7(3):32-36
2.高体玉,李俊等.乳腺癌组织中蛋白质二级结构的Fourier变换红外光谱研究.分析科学学报,2000,16(5):353-357
3.黄文.白果活性蛋白的分离、纯化、结构及其生物活性研究.[华中农业大学博士毕业论文],2000,112
4.林青松,颜思旭.中华猕猴桃蛋白酶在甲醇溶液中的构象与活力变化研究.厦门大学学报(自然科学版),1994,33(1):100-104
5.林波海.蛋白质二级结构的真空紫外圆二色性研究.生物化学与生物物理进展,1994,21(1):67-69
6.刘清亮,吴双顶等.皖南尖吻蛇毒糖坩水解酶的荧光光谱研究.无机化学学报,1998,14(1):53-57
7.鲁子贤,崔涛,施庆洛.园二色性和旋光色散在分子生物学中的应用.北京:科学出版社,1987:82—133
8.沈漪,方文汉.蛋白质一级结构测定的新进展.中国医药工业杂志,2002, 33(10):514-518
9.陶慰孙等编著.蛋白质分子基础.北京:人民出版社,1981,42-54
10.王广策,邓田,曾呈奎.藻胆蛋白的研究概况(Ⅱ)—藻胆蛋白的结构及其光谱特性.海洋科学,2000,24(3):19-22
11.王槐春.蛋白质与核酸序列分析基础。北京:人民军医出版社,1994
12.王守业,徐小龙.荧光光谱在蛋白质分子构象研究中的应用.化学进展,2001,7(4):257-260
13.赵辅昆,徐松琴等.蛇肌果糖1,6-二磷酸脂酶的R态和T态的构象.生物化学与生物物理学报,1994,26(5):525-533
14.周瑞明,沈永嘉.蛋白质二级结构的红外光谱.华东理工大学学报,1997,23(4):422-425
15.祝大昌,陈剑宏等.分子发光分析法。上海:复旦大学出版社,1985
16.阎隆飞等编著.蛋白质分子结构.北京:清华大学出版社,1999.123-146
17.颜思旭,刘红兵.缢蛏碱性磷酸酶胍溶液中分子折叠与活力变化研究.生物化学杂志,1994,10(3):402-406
18.杨家祥,张玉慧等.荧光光谱在蛋白质分子构象研究中的应用.淮海工学院学报,1999,8(4)
19. Compton L A. Johnson W C. Anal Biochem, 1986, 155-156
20. Canaoni O D, Elisabeth G. Circular dichroism and polarized fluorescence characteristic of blue-green algal allophycocyanins. J. Biochem, 1980, 19:2950-2956
21. Compton.L A, Johnson W C. Anal Biochem,1986:155-156.
22. Eftink M R, Ghiron C A. Biochemistry, 1976, 15 (3): 672-680
23. Johan A, Hellebust J. S. Craigie, Handbook of phycological methods Physiological and biochemical methods. Cambridge University press, 1978, 72-80
24. Johnson M S, Srinivassn N, Sowdhamini R et al. CRC Crit Rev Biochem Ml Biol. ,1994,29:1
25. Lakowics J R, Principles of fluorescence spectroscopy. New York: Plenum Press, 1983, 281
26. Parker F S. Application of Infrarel, Raman and Reaomance Raman Spectroscopy in Biochemistry New York: Plenum Press. 1983:83-102
27 . Prestrelski S J, Arakawa T, Carpenter J F. Acrd. Biochem Biophys, 1993, 303: 46
1.隋正红,张学成.藻红蛋白研究进展.海洋科学,1998,24(4):24-27
2.刘鲁宁,黄芳,黄业立.螺旋藻酒中藻蓝蛋白稳定性影响因素的研究.酿酒,2004,31(3):43-44
3.刘旭川,李琦华.螺旋藻藻蓝蛋白提取及稳定性试验.云南大学学报(自然科学版),1999,21(3):230-232
4.余九九,李宽钰,吴庆余.螺旋藻的藻胆蛋白提取及稳定性研究.海洋通报,1997,16(4):26-285
5.吕彩真,欧光南.红毛菜藻红蛋白的提取及稳定性研究.集美大学学报(自然科学版),2002,7(1):15-196
6.张玉忠,周百成,曾呈奎.钝顶螺旋藻藻胆体的简易制备及褐藻酸钠对其稳定性的保护作用.海洋科学,1997,6:39-42
7.张熙颖,刘鲁宁,陈秀兰.钝顶螺旋藻藻胆体的稳定性研究.海洋科学.2004,28(8):38-46
8.杨忠慧,王淑芝,路荣昭.藻胆体稳定性的研究—pH对藻胆体稳定性的影响.首都师范大学学报(自然科学版),1994,15(4):65-69
9. Katoh T. Phycobilisome Stability. Meth in Enzymol, 1988, 167:313-318
10. Richard J R. Algal diversity and commercial algal products. Bio. Science, 1996,46(4): 263-270
11. Siegelman H.W, Kycia.J.H, Handbook of phycological method. Cambridge university Press. 1978.72-114
1.陈美珍,张永雨,余杰.龙须菜藻胆蛋白的分离及其清除自由基作用的初步研究.食品科学,2004,25(3):159-162
2.凌关庭.天然抗氧化剂及其清除氧自由基的进展.食品工业,2000,(3):19-22
3.罗广华,王爱国,柯德森.海藻中清除氧自由基的物质.热带亚热带植物学报,1998,6(1):15-18
4.胡春,丁霄霖.用化学发光法研究黄酮化合物对O_2和OH的清除.无锡轻工大学学报,1996,15(3):194-198
5.唐玫,王曼,郭宝江.富硒藻蓝蛋白对小鼠免疫功能及抗氧化活性的影响.营养学报,2001,3(3):275-278
6.田云,卢向阳,易克.天然抗氧化剂清除氧自由基的能力.湖南农业大学学报(自然科学版),2004,30(3):209-211
7.赵保路.氧自由基与天然抗氧化剂.北京:科学出版社,2001
8.邹国林,桂兴芬,钟晓凌.一种SOD的测定方法——邻苯三酚自氧化法的改进.生物化学与生物物理进展,1986,13(4):71-73.
9.钟进义,王传现,王建华.化学发光法测定葡萄多酚对超氧阴离子自由基的清除.中华预防医学杂志,2001,35(3):350
10.王少敏.李萍.赵明强.生物化学发光法测定酸仁的抗氧化活性.中草药,2003,34(5):417-419
11.魏玉西,徐祖洪.褐藻中高相对分子质量褐藻多酚的抗氧化活性研究.中草药,2003,34(4):317-319
12.夏其乐,陈健初,吴丹.杨梅叶提取物抗氧化活性的研究.食品科学,2004,25(8):80-83
13.严建刚,张名位,杨公明.芹菜提取物清除自由基作用研究.食品科学,2004,25(8):39-42
14. Larrauri J A, Sanchex-Moreno C, Saura-Calixto F. Effects of temperature on the free radical scavenging capacity of extracts from red and white grape pomace peels. J Agric Food Chem, 1998, 46 (7): 2694-2697.
15. Scartezzini P, Speroni E. Review on some plants of Indian traditional medicine with antioxidant activity. J. Ethnopharmacol, 2000, 71 (12): 23-43.
16. Yokozawa T, Dong E, Natagawa T, et al. Invitro and invivo studies on the radical-scavenging activity of tea. J. Agric Food Chem, 1998, 46 (6): 2143-2150.
17. Yu G l,Lu Z H , Wang S G , et al. Antioxidative activity of alga (Sagassum kjllmaniaman) extracts to unsaturatelipids. J Ocean Univ Qingdao(青岛海洋大学学报), 2000, 30(1): 75-80
1.鲍时翔,姚汝华.蛋白质分离纯化与层析技术进展,华南理工大学学报(自然科学版),1996,24(12):98-103
2.曹书霞,赵玉芬.分子吸收光谱在生物大分子研究中的应用,2004,24(10)1197-1200
3.成海平,钱小红.蛋白质组研究的技术体系及其进展.生物化学与生物物理进展,2000,27:584-588.
4.陈绍农,潘远江,陈耀祖.多肽及蛋白质质谱分析新进展.质谱学报,1995,16(3):15-21
5.陈晶,付华,陈益.质谱在肽和蛋白质序列分析中的应用.有机化学,2002,22(2):81-90
6.徐友宣,彭师奇.蛋白质及多肽的液相色谱.电喷雾离子化质谱研究进展.药学学报,1997,32(10):792—799
7.[德]坎普,[希腊]乔里-帕帕多普洛编著;施蕴渝译蛋白质结构分析:制备、鉴定与微量测序.北京:科学出版社,2000:197-210
8.邓慧敏,赖志辉,黎军.延迟引出基体辅助激光解吸/电离质谱(DE—MALDI—MS)法高分辨率测定混合碱基DNA的研究.质谱学报,2000,21(1):1-5
9.顾宁琰,刘宇峰.紫球藻生物活性物质及其应用.中国海洋药物,2001,84(6):43-48
10.方晔,王霆.白春礼等,银胶中三螺旋RNA poly(rU).poly(rA).poly(rU)的付立叶表面增强拉曼光谱研究.生物物理学报,1995,11(2):149-155
11.傅晓红,林其谁.胆碱脱氢酶光谱性质的研究,生物化学与生物物理学报,1997,29(2):213-218
12.高宏,周群,郁鉴源.生物物理学报,1999.15(3):445-450
13.郭尧君.荧光实验技术及其在分子生物学中的应用.北京:科学出版社,1979:136-137
14.郭云昌,蔡颖谦,中岛秀郎.原子力显微镜在DNA研究中的应用.现代科学仪器.2005(3):71-72
15.龚海霞,陈荣华,郭锡熔.蛋白质组技术及其在临床医学领域的运用.国外医学儿科学分册,2001;28(6):287-289
16.韩俊,杨仲元,盛龙生等.电喷雾离子化质谱法及其在药物与生物大分子分析中的应用.药物分析杂志,2001,21(3):212-217
17.何靳安,蒋丽金,江龙.藻胆蛋白的langmuir-Blodgett膜——R-藻红蛋白单分子膜及蛋白构象变化的研究.中国科学B辑,1996,26(2):111-116
18.何美玉,王光辉,熊少祥.现代生物质谱及其应用.现代仪器,2001(1):6—8
19.黄珍玉,于雁灵,方彩云.质谱鉴定磷酸化蛋白研究进展.质谱学报,2003;24(4):494-500
20.李冠武,王广策.多管藻R-藻红蛋白的激光光敏作用对体外培养的肿瘤细胞生仔的影响.激光生物学报,1997,6(3):11-19
21.李蓉,梁恒.生物质谱-蛋白质组研究的关键技术.化学通报,2002,11:748-752 28
22.李永民.生物质普.分析测试技术与仪器,2002,8(2):131—135
23.粱栋材,常文瑞,江涛.R—藻红蛋白三维结构研究,生命科学,1998,10(5):207-209
24.凌晓锋,李维红,宋苑苑 等.光谱学与光谱分析,2000,20(5):692-693
25.代连花,戴国亮.激光扫描共聚焦显微镜在蛋白质晶体生长研究中的应用.激光生物学报 2004,13(3):210-213
26.刘东升,王金凤.结构基因组学研究与核磁共振.生物化学与生物物理进展,2001,28(6):827-831
27.刘慧敏,赖志辉,黎军.碎片结构分析在MALDIT-OF-MS法测定多肽序列中的应用.生物化学与生物物理学报,2000,32:179-182
28.刘锦玉,张季平.万柱礼等.条斑紫菜变藻蓝蛋白立方晶系的初步晶体学研究.科 学通报,1997,42(12):1321-132
29.路荣昭,李凤平,顾天青.嗜热蓝藻层理鞭枝藻(MastigoCladus laminosus)藻胆体在解离过程中荧光发射光谱和光能传递的研究.生物物理报,1996,12(3):494-498
30.鲁子贤,崔涛.园二色性和旋光色散在分子生物学中的应用,北京:科学出版社,1987
31.吕茂民,章金刚.生物质谱技术及其应用.生物技术通报,2001(4):38—41
32.吕正检,王建华,徐世荣.原子力显微镜在医药学研究中的应用.中国医药杂志.2006,41(7):490-492
33.马聪,周明,张富铁等.藻红蓝蛋白裂合异构酶E基因突变体的构建、表达与酶活性检测.水生生物学报,2003,27(6):614-618
34.彭卫民,商树田,刘国琴等.螺旋藻藻胆蛋白研究进展(综述).农业生物技术学报,1998,6(2):173-177
35.钱小红.蛋白质组与生物质谱技术.质谱学报,1998,19(3):48—55
36.邱冠英,彭银祥.生物物理学.武汉:武汉大学出版社,2000
37.盛树斌,张富铁,邓明刚等.层理鞭枝藻藻红蓝蛋白E基因片段的克隆和表达.水尘生物学报,2001,25(4):427-430
38.宋波,朱菁萍,周明等.藻蓝蛋白和藻红蓝蛋白β-亚基半胱氨酸的定点突变及体外重组研究.水生生物学报,2004,28(4):344-348
39.司英健.蛋白质组学研究的内容、方法及意义.国外医学临床生物化学与检验学分册,2003;24(3):167-168
40.沈漪,方文仅.蛋白质一级结构测定的新进展.中国医药工业杂志.2002,33(10):514-518
41.沈星灿,梁宏,何锡文等.园二色光谱分析蛋白质构象的方法及研究进展,分析化学.2004,32(3):388-394
42.许克新,王云川.双向电泳及质谱分析与蛋白组研究.第四军医大学学报,2002;23(22):2017-2022
43.许崇峰,杨原,岳贵花.基于质谱的DNA序列测定进展.化学通报,2000,63(2): 20—24
44.谭君.祝连彩,拉曼光谱在结构生物学中的应用.重庆教育学院学学报,2004,17(3):49-52
45.童义平.李伟,林燕文.傅里叶红外光谱研究血清白蛋白构象,光谱学与光谱分析,1999,19(5):704-706
46.王征,阮幼冰,官阳.肝细胞癌患者血清蛋白质组成分的双向凝胶电泳.飞行时间质谱分析.中华病理学杂志,2003;32(4):333-336
47.王斌,王靖,余江.FT-Raman光谱研究溶菌酶在氘代甲醇溶液中的构象变化.光谱学与光谱分析,1999,19(4):674-676
48.王广策,周百成,曾呈奎.B-藻红蛋白和R-藻红蛋白γ亚基的分离、特性及其在分子中的空间位置分析.中国科学(C辑),1998,28(1):36-41
49.王广策,邓田,曾呈奎.藻胆蛋白的研究概况(Ⅱ)—藻胆蛋白的结构及其光谱特性.海洋科学,2000,24(3):19-22
50.王杰芳,杨柳,李富广.质粒pUC18DNA的傅立叶变换拉曼光谱研究.激光杂志,200122(1):44-45
51.王长海,李叙风.紫球藻及其应用研究.海洋通报,1998,17(3):79-82
52.王长海,温少红,欧阳藩.紫球藻的生物活性物制裁.海洋通报,1999,18(3):25
53.王高兰.蛋白质组研究中肽质量指纹谱鉴定方法的建立及应用.生物化学与生物物理学报,2000,32(4):373-378
54.王慧,赵井泉,张建平.螺旋藻藻胆体核心复合物结构与功能的研究——四种变藻蓝蛋白复合物的分离及光谱特性的研究.生物物理学报,1996,12(3):394-400
55.王慧,赵井泉,蒋丽金.多变鱼腥藻胆体模型复合物结构与功能的研究.科学通报,1998,43(6):596-600
56.汪河洲,赵福利,郑锡光.藻红蛋白的微晶激子光谱.科学通报,1995,40(7):650-652
57.汪尔康.21世纪的分析化学.科学出版社,2001:112—120
58.朱菁萍,周明,赵开弘等.藻红蓝蛋白裂合异构酶对几种脱辅基藻胆蛋白的催化作用.生物工程学报,2002,18(6):703-708
59.张景民.赵福利.郑锡光.蓝藻(A.variabilis)藻胆体核结构与功能的研究Ⅱ.变 藻蓝蛋白六聚体内能量传递过程的物理机制.生物物理学报,1999,15(2):393-399
60.张学成,张锦东,隋正红.江蓠属藻胆蛋白的研究——诱变、突变体筛选及藻胆蛋白的光谱特性.青岛海洋大学学报(自然科学版),1996,26(3):318-326
61.张景民,谢洁,张建平.蓝藻(Cyanobacteria)藻胆体内核结构与功能的研究Ⅰ.变藻蓝蛋白六聚体(αβ)_6分离及其表征.生物物理学报,1997,13(3):362-368
62.张建平,张景民,赵井泉.R-藻蓝蛋白的分离及其结构表征.生物物理学报,1997,13(2):173-178
63.张景民,郑锡光,赵福利.C-藻蓝蛋白六聚体内能量传递途径及其机制.中国科学(B辑),1998,28(5):445-452
64.张玉忠,周百成,曾呈奎等.海洋红藻R-藻胆蛋白的扫描隧道显微镜研究.生物物理学报,1997,16(6):723-725
65.张景民,赵井泉,蒋丽金.多变鱼腥藻中藻红蓝蛋白三聚体内能量传递的机制(Ⅱ).中国科学(C辑),1998,28(4):308-312
66.赵福利,郑锡光,汪河洲等.四种别藻蓝蛋白三聚体的时间分辨荧光光谱研究.中国激光,1998,25(4):318-322
67.赵南明,周海梦.生物物理学.北京:中国高等教育出版社,2000
68.郑永红,杨松成.生物质谱技术在蛋白质结构鉴定中的应用进展,中国生化药物杂志,2003,24(6):305-308
69.郑敏,答亮,邓明刚等.层理鞭枝藻藻红蓝蛋白F基因片段的克隆和表达.水生生物学报,2002,26(2):168-174
70.郑伟民,蔡继业.原子力显微镜在DNA领域中研究应用.现代仪器.2006(1):9-12
71.周国华.基质辅助激光解吸质谱法在生物大分子质量研究中的应用.药学学报,1998,33(4):290-295
72.周毅峰 吴永尧 唐巧玉,生物质谱在生命科学中的应用,湖北民族学院学报(自然科学版),2004,22(2):11-16
73.周瑞明,沈永嘉.蛋白质二级结构的红外光谱,华东理工大学学报,1997,23(4):422-425
74.邹国林.周祥,郑忠亮.蛋白质结构研究技术的发展,信阳农业高等专科学校学报,2003,13(4):1-3
75.吴世容,李志良.李根容.生物质谱的研究及其应用.重庆大学学报,2004,27(1):123-127
76.解建勋,蒲小平.李玉珍.蛋白质组分析技术进展.生物物理学报,2001,17:19-26
77.魏开华,杨松成,王红霞.转印到膜上的蛋白质的质谱分析.质谱学报,2000;20(3,4):89-90
78.邬江,朱家恺,许扬滨.细胞源神经营养蛋白的质谱分析.中华显微外科杂志,2002,25(4):271-273
79.向洋,激光生物学.长沙:湖南科学技术出版社,1995 80.
80.应万涛,钱小红.生物质谱应用技术及进展.军事医学科学院院刊,2000,24(2):146-150
81.阎隆飞,孙之荣.蛋白质分子结构.北京:清华大学出版社,1999
82.杨频,高飞.生物无机化学原理,北京:科学出版社,2002
83.杨铭,结构生物学概论,北京:北京医科大学出版社,2002
84.余多慰.柯惟中,纤维与水溶液状态下DNA空间构象的激光拉曼光谱分析,光散射学报,1995,7(1):24-29
85.袁湘林,邹汉法.基质辅助激光吸电离飞行时间及其在高分子量物质测定中的应用.分析化学,1998,26(2):234—238
86.庄华梅,何德.核磁共振技术及其在生命科学中的应用,生物磁学,2005,5(4)
87. Andrew N. Round, Alistair J. MacDougall, Stephen G. Ring,Victor J. Morris. Carbohydrate Research, 2001, 331:337-342
88. Aritake M,Noriko F, Mitsuhiko A et al. Changes of Secondary Structure Detected by Raman Spectroscopy in Model Peptide of αAcrystalline Due to Substitution of D-Aspartyl Residues for L-Aspartyl Residues. Jpn. J. Ophthalmol. 2000,44:354-359
89. Barber M. Bordoli R S. ,Sedgwick R D., Tyler A N. Fast atom bombardment of Solids(F. A. B.): A New Ion Source for Mass Spectrometry. J. Chem. Soc. Commum, 1981,325-327
90. Bennitt A. Properties of subunits and aggregates of blue-green algal biliproteins. J. Biochenmistry, 1971,10: 3625-3634
91. Bidan G, Billon M Galasso K, et al. Electropoly merization as a versatile route for immobilizing biological species onto surfaces. Application to Dnabiochips. Appl Biochem Biotechnol, 2000, 89(2-3): 183-93
92. Chen R, Cheng X, Mitchell D W et al. Trapping, detection, and mass determination of coliphage T4 DNA ions of 10**8 Da by electrospray ionization fourier transform ion cyclotron resonance mass spectrometry. Anal. Chem. ,1995, 67(7): 1159-1163
93. Chen X G,Li P S,Holtz J S W et al. Resonance Raman examination of the Electronic Excited States of Glycylglycine and other Dipertides Observation of a Carboxylate Amide Charge Transfer Transition. J. Am. Chem. Soc. ,1996,118:9705-9715
94. Chen X G,Reinhard S S,Mirkin R et al. N-Methylacetamide and Its Hydrogen-Bonded Water Molecules Are Vibrationally Coupled. J. Am. Chem. Soc. ,1994,116:11141-11142
95. Chen X G, Reinhard S S , Mirkin R et al. UV Raman Determination of theπ-π* Excited State Geometry of N-Methylacet acide: Vivrational Enhancement Pattern. J. Am. Chem. Soc. ,1995,117:2884-2895
96. Cheung C L ,Hafner J h ,Lieber C M ,Carbin nanotube force microscopy tips:direct growth by chemical vapor deposition and application to high-resolution imaging. Procnatl Acad Sci USA ,2000,97(8):3809
97. Debreczeny M P, Sauer K, Zhou J and Bryant DA. Comprison of calculation and experimentally resolved rate constants for excitation energy transfer in C-PC. J. Phys. Chem. ,1995,99:8420-8431
98. Drake B, Prater C B, Weisenhorn A L, et al. Imaging crystals polymers and processes in water with the atomic force microscope. Science, 1989,243:1586
99. Epand R F , Yip C M ,Chernomordik L V ,et al. Self-assembly of influenza hemagglutinin:study of ectodomain aggregation by in situ atomic force microscopy. Biochem BiophysActa, 2001, 1513(2):167
100. Edman P, Begg G. A p ro tein sequenator. Eur J Biochem. 1967, 1(1): 80291
101. Griffin T J, Gygi S P, Rist B et al. Collaborative exercise on the use of FISH chromosome painting for retrospective biodosimetry of Mayak nuclear-industrial personnel[J]. Anal. Chem. ,2001, 73 (5): 978-986
102. G Bining, CF Quate, C Gerber. Atomic force microscope. Phys Rev Leit,1986,56:930-933
103. Glazer A N, et al. Charaterization of R-phycocyanin, Chomophore cotent of R-phycocyanins and C-phycoerythin. Biol. Chem, 1975, 256(14):5487-5495
104. Harourt R D, Scholes G D, Ghoggino. R ate expressions for excitation transfer II,Electronic considerations of direct and through configuration excite on resonance interactions. J. Chem. Phys, 1994, 101(12): 10521-10525
105. HarveyDJ. Identification of protein-bound carbohydrates by masss pectrometry. Proteomi c, 2001; 1(2):311-328
106. Karasm,Hillenkampf. Laser desorption ionization of proteins with molecular masses exceeding 10000 daltons. Anal. Chem, 1988, 60:2299-2301
107. Karoly C, Robert M. Exciton interaction in alloph ycocyanin. Biochemistry,1984,23:6466-6470
108. Kurian E, Prendergast F G, Tomlinson A J ,et al. Photoacoustic analy sis of proteins:volumetric signals and fluorescence quantum yields. Mass Spectrom, 1997, 8 (1):8-14
109. Kuznetsov Y G, Malkin A J, McPherson A. Sself-repair of biological fibers catalyzed by the surface of a virus crystal. Proteins, 2001,44(3):392-396
110. Kuznetsov Y C ,Malkin A J ,Lucas R W ,et al. Imaging of viruses by atomic force microscopy. J Cen Virol ,2001,82:2025
111. Lakowicz J R. Principles of fluorescence spectroscopy. New York:Plenum Press. 1983: 257-295
112. Lay. MALDI-TOF mass spectrometry of bacteria. MassSpectromRev, 2001; 20(4): 172-194
113. Lazer A N. Formation of hybrid protein from the aand Psubunit of phycocya-nins of unicellular and filamentous, blue-green algal. Biol. Chem, 1973,248:663-671
114. Macfarlane R D. , Torgerson D f. ,Californium-252 Peroration Mass Spectroscopy. Science, 1976,191:920-925
115. March RE J. Observation of apigenin anionic clusters in the gas phase. Mass Spectrom, 1996,32: 315
116. Medzihradszky K F, Cempbell J M, Baldwin M A et al. Copper binding to octarepeat peptides of the prion protein monitored by mass spectrometry. Anal. Chem. ,2000,72(3): 552-558
117. Paige M F ,Rainey J K. A study of fibrous long spacing collagen ultrastructure and assembly by atomic force microscopy. Micron,2001,32(3):341-353
118. Rebolloso Fuentes M M, Acien Fernandez G G. Biomass nutrient profiles of the microalga Pcruentum. Food Chemistry, 2000, 70(3): 345
119. Pilot T J, Fox J L. Cloning and sequencing on the genesencoding the aand Psubunits of C-phycocyanin from the Cyanobacterium Agmenilum qadruplicatum. Proc Natl Acad Sci USA, 1984, 81: 6983-6987
120. Sandstrom A, Gillbro T, Sundstrom V. Picosecond study of energy transfer within 18-Sparticles of AN112(amutant of Synechococcus 6301) Pphycobilisomes. Biochem,Biophys. Acta, 1998, 933: 54-64
121. Scholes G D, Ghoggino. Rate expressions for excitation transfer, Radiation less transition theory perspective. J Chem Phys, 1994, 101(2): 1251-1261
122. Shapiro L. ,Scherer P E. The crystal structure of a complement-1q family protein suggests an evolutionary link to tumor necrosis factor. Curr Biol. ,1998,8(6):335-338
123. Shevchenko A, Loboda A, Ens W et al. LC/MS Analysis of NAD Biosynthesis Using Stable Isotope Pyridine Precursors. Anal. Chem. , 2000, 72 (9): 2132—2141
124. Song S H, Asher S A. UV Resonance Raman Studies of Peptide Conformation in Poly(L-lysine), Poly(L-glutamic acid),and Model Complexes: the Basis for Protein Secondary Structure Determinations. J. Am. Chem. Soc. ,1989.111:4295-4305
125. Stolz M. Stoffler D. Aebi U, et al. Monitoring biomolecular interactions by time-lapse atomic force microscopy. J Struct Biol, 2000,131(3): 171-180
126. Wilm M. Shevchenko A, Ole Vorm et al. Linking genome and proteome by mass spectrometry: Large-scale identification of yeast proteins from two dimensional gels. Nature 1996: 379, 466
127. Wise M J. Littlejohn T G. Measurement of shallow arsenic impurity profiles in semiconductor silicon using time-of-flight secondary ion mass spectrometry and total reflection x-ray fluorescence spectrometry. Electrophoresis, 1997, 144(11): 1399-1409
128. Yau S T, Vekilov P G. Direct observation of nucleus structure and nucleation pathways in apoferritin crystallization. J. Am Chem Soc,2001,123(6): 1080-1089