基于电子舌技术的氨基酸与密码子关系的初步研究

doi:10.6023/A21070334

化学学报 ›› 2021, Vol. 79 ›› Issue (11): 1372-1375.DOI: 10.6023/A21070334 上一篇下一篇

研究通讯

基于电子舌技术的氨基酸与密码子关系的初步研究

赵钊^a, 程时文^b, 毛岳忠^b, 应见喜^c, 田师一^b^,^*(), 赵玉芬^a^,^c^,^*()

a 厦门大学化学化工学院福建省化学生物学重点实验室厦门 361005
b 浙江工商大学食品与生物工程学院杭州 310018
c 宁波大学新药技术研究院宁波 315211

投稿日期:2021-07-16 发布日期:2021-09-15
通讯作者: 田师一, 赵玉芬
基金资助:
项目受中国科学院空间科学与应用总体部(YYWT-0901-EXP-16)

Primary Research of the Relationship between Genetic Codons and Amino Acids Based on the Technology of Electronic Tongue

Zhao Zhao^a, Shiwen Cheng^b, Yuezhong Mao^b, Jianxi Ying^c, Shiyi Tian^b(), Yufen Zhao^a^,^c()

a College of Chemistry and Chemical Engineering, and the Key Laboratory for Chemical Biology of Fujian Province, Xiamen University, Xiamen 361005, China
b School of Food Science and Biotechnology, Zhejiang Gongshang University, Hangzhou 310018, China
c Institute of Drug Discovery Technology, Ningbo University, Ningbo 315211, China

Received:2021-07-16 Published:2021-09-15
Contact: Shiyi Tian, Yufen Zhao
Supported by:
Technology and Engineering Center for Space Utilization, Chinese Academy of Sciences(YYWT-0901-EXP-16)

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摘要/Abstract

自从首个遗传密码子被破译以来, 密码子与所表达的氨基酸之间的关系一直吸引了许多关注. 本研究从氨基酸、核苷和三偏磷酸钠的反应体系出发, 用电子舌检测反应前后体系变化, 考察核苷对氨基酸成肽反应的影响, 试图找到氨基酸与密码子的联系. 结果表明, 大部分氨基酸的密码子或反密码子中间位核苷对反应的促进作用最大, 这种结果可能是因为核苷的碱基与氨基酸的侧链基团之间的某种弱相互作用导致的. 相应地, 亮氨酸和异亮氨酸之间的结果差异更加佐证了上述假设. 这种弱相互作用有望成为研究密码子识别氨基酸的关键突破, 为生命起源的研究提供新方法.

关键词: 密码子, 氨基酸, 电子舌, 核苷, 生命起源

The relationship between genetic codons and amino acids has attracted much attentions since the discovery of first genetic codon. Although we have known that relationship of codons and amino acids clearly, even some rare amino acids also have their codons in certain creatures, we do not know the real principle that how a codon detertmine an amino acid. In fact, the codon is a little far from amino acid in a tRNA. With many efforts, we have not detect the secret of codon. Before we used nuclear magnetic resonance (NMR) and high resolution mass spectrum (HRMS) to detect the product of reaction of amino acids, nucleosides and sodium trimetaphosphate to find out the relationship between amino acid and nucleoside. But the productivity was too low to determine. Electronic tongue is a machine used to determine the whole variant of a solution, especially in food industry, it could determine very subtle variant. So we use it to determine the whole variant of our system. In this work, we reported the reactions between amino acids, nucleosides and sodium trimetaphosphate. Each ingredient was 0.0008 mol/L and pH was adjusted to 11 by NaOH, then reacted at 50 ℃for 48 h. The reacted mixture was cooled down to room temperature and detected by electronic tongue. Also, the samples that were freshly prepared were detected by electronic tongue to be original data. The overall changes of the reaction mixtures were characterized by the average of Euclidean Distance. The results show that the nucleosides in middle of codon or anticodon displayed the greatest effect on the reactions. The results also indicate that there are significant interrelations between amino acids and nucleosides, which was also proved by the difference between the results of leucine and isoleucine. In summary, the results may open a new avenue to the study of the relationship between genetic codens and amino acids and origin of life.

Key words: codon, amino acid, electronic tongue, nucleoside, origin of life

引用此文

赵钊, 程时文, 毛岳忠, 应见喜, 田师一, 赵玉芬. 基于电子舌技术的氨基酸与密码子关系的初步研究[J]. 化学学报, 2021, 79(11): 1372-1375.

Zhao Zhao, Shiwen Cheng, Yuezhong Mao, Jianxi Ying, Shiyi Tian, Yufen Zhao. Primary Research of the Relationship between Genetic Codons and Amino Acids Based on the Technology of Electronic Tongue[J]. Acta Chimica Sinica, 2021, 79(11): 1372-1375.

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参考文献 16

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	U	C	A	G
U	Phe	Ser	Tyr	Cys	U
	Phe	Ser	Tyr	Cys	C
	Leu	Ser	STOP	STOP	A
	Leu	Ser	STOP	Trp	G
C	Leu	Pro	His	Arg	U
	Leu	Pro	His	Arg	C
	Leu	Pro	Gln	Arg	A
	Leu	Pro	Gln	Arg	G
A	Ile	Thr	Asn	Ser	U
	Ile	Thr	Asn	Ser	C
	Ile	Thr	Lys	Arg	A
	Met	Thr	Lys	Arg	G
G	Val	Ala	Asp	Gly	U
	Val	Ala	Asp	Gly	C
	Val	Ala	Glu	Gly	A
	Val	Ala	Glu	Gly	G

	U	C	A	G
U	Phe	Ser	Tyr	Cys	U
	Phe	Ser	Tyr	Cys	C
	Leu	Ser	STOP	STOP	A
	Leu	Ser	STOP	Trp	G
C	Leu	Pro	His	Arg	U
	Leu	Pro	His	Arg	C
	Leu	Pro	Gln	Arg	A
	Leu	Pro	Gln	Arg	G
A	Ile	Thr	Asn	Ser	U
	Ile	Thr	Asn	Ser	C
	Ile	Thr	Lys	Arg	A
	Met	Thr	Lys	Arg	G
G	Val	Ala	Asp	Gly	U
	Val	Ala	Asp	Gly	C
	Val	Ala	Glu	Gly	A
	Val	Ala	Glu	Gly	G

	密码子	差别度结果	计算数值^a
Ala	GCA/U/G/C	G>U>C>A	A:24.14(0.78)/C:26.12(0.16) G:27.04(0.08)/U:26.34 (0.11)
Arg	CGA/U/G/C,AGA/G	C>G>A>U	A:26.33(0.13)/C:27.39(0.07) G:26.68(0.14)/U:26.00(0.29)
Asn	AAU/C	C>A>U>G	A:27.53(0.23)/C:28.08(0.07) G:24.35(0.25)/U:27.02(0.18)
Asp	GAU/C	U>G>A>C	A:27.25(0.44)/C:27.00(0.42) G:27.53(0.42)/U:28.26(0.16)
Cys	UGC/U	A>G>U>C	A:26.37(0.16)/C:22.76(0.78) G:24.81(0.86)/U:23.90(0.31)
Gln	CAA/G	U>A>C>G	A:27.73(0.33)/C:27.61(0.12) G:27.54(0.26)/U:27.94(0.17)
Glu	GAA/G	A>C>G>U	A:27.71(0.28)/C:27.52(0.12) G:27.09(0.23)/U:26.17(0.22)
Gly	GGA/U/G/C	A>G>C>U	A:26.73(0.60)/C:25.98(0.34) G:26.07(0.37)/U:25.66(0.10)
His	CAU/C	A>C>U>G	A:27.33(0.48)/C:27.24(0.41) G:24.19(0.60)/U:26.32(0.59)
Ile	AUA/U/C	A>C>G>U	A:28.18(0.07)/C:27.92(0.28) G:27.28(0.30)/U:26.62(0.36)
Leu	CUA/U/G/C	G>U>A>C	A:26.67(0.23)/C:26.02(0.65) G:27.93(0.10)/U:26.97(0.37)
Lys	AAA/G	U>A>C>G	A:26.63(0.54)/C:26.25(0.09) G:21.47(0.11)/U:26.97(0.34)
Met	AUG	U>C>A>G	A:25.19(0.31)/C:25.44(0.98) G:24.96(0.30)/U:26.69(0.27)
Phe	UUA/U/G/C	U>G>C>A	A:23.58(0.55)/C:24.28(0.49) G:26.00(0.20)/U:26.16(0.79)
Pro	CCA/U/G/C	G>A>C>U	A:26.85(0.79)/C:26.60(0.38) G:27.12(0.12)/U:26.53(0.79)
Ser	UCA/U/G/C,AGU/C	G>A>C>U	A:28.77(0.03)/C:28.66(0.49) G:29.23(0.12)/U:28.59(0.34)
Thr	ACA/U/G/C	G>A>U>C	A:28.32(0.17)/C:28.16(0.02) G:28.34(0.21)/U:28.17(0.11)
Trp	UGG	G>A>C>U	A:27.46(0.54)/C:27.14(0.24) G:27.48(0.62)/U:27.01(0.28)
Tyr	UAU/C	A>C>G>U	A:28.44(0.36)/C:27.76(0.06) G:27.63(0.30)/U:27.51(0.14)
Val	GUA/U/G/C	C>U>G>A	A:27.32(0.25)/C:28.13(0.55) G:27.69(0.57)/U:28.04(0.18)

	密码子	差别度结果	计算数值^a
Ala	GCA/U/G/C	G>U>C>A	A:24.14(0.78)/C:26.12(0.16) G:27.04(0.08)/U:26.34 (0.11)
Arg	CGA/U/G/C,AGA/G	C>G>A>U	A:26.33(0.13)/C:27.39(0.07) G:26.68(0.14)/U:26.00(0.29)
Asn	AAU/C	C>A>U>G	A:27.53(0.23)/C:28.08(0.07) G:24.35(0.25)/U:27.02(0.18)
Asp	GAU/C	U>G>A>C	A:27.25(0.44)/C:27.00(0.42) G:27.53(0.42)/U:28.26(0.16)
Cys	UGC/U	A>G>U>C	A:26.37(0.16)/C:22.76(0.78) G:24.81(0.86)/U:23.90(0.31)
Gln	CAA/G	U>A>C>G	A:27.73(0.33)/C:27.61(0.12) G:27.54(0.26)/U:27.94(0.17)
Glu	GAA/G	A>C>G>U	A:27.71(0.28)/C:27.52(0.12) G:27.09(0.23)/U:26.17(0.22)
Gly	GGA/U/G/C	A>G>C>U	A:26.73(0.60)/C:25.98(0.34) G:26.07(0.37)/U:25.66(0.10)
His	CAU/C	A>C>U>G	A:27.33(0.48)/C:27.24(0.41) G:24.19(0.60)/U:26.32(0.59)
Ile	AUA/U/C	A>C>G>U	A:28.18(0.07)/C:27.92(0.28) G:27.28(0.30)/U:26.62(0.36)
Leu	CUA/U/G/C	G>U>A>C	A:26.67(0.23)/C:26.02(0.65) G:27.93(0.10)/U:26.97(0.37)
Lys	AAA/G	U>A>C>G	A:26.63(0.54)/C:26.25(0.09) G:21.47(0.11)/U:26.97(0.34)
Met	AUG	U>C>A>G	A:25.19(0.31)/C:25.44(0.98) G:24.96(0.30)/U:26.69(0.27)
Phe	UUA/U/G/C	U>G>C>A	A:23.58(0.55)/C:24.28(0.49) G:26.00(0.20)/U:26.16(0.79)
Pro	CCA/U/G/C	G>A>C>U	A:26.85(0.79)/C:26.60(0.38) G:27.12(0.12)/U:26.53(0.79)
Ser	UCA/U/G/C,AGU/C	G>A>C>U	A:28.77(0.03)/C:28.66(0.49) G:29.23(0.12)/U:28.59(0.34)
Thr	ACA/U/G/C	G>A>U>C	A:28.32(0.17)/C:28.16(0.02) G:28.34(0.21)/U:28.17(0.11)
Trp	UGG	G>A>C>U	A:27.46(0.54)/C:27.14(0.24) G:27.48(0.62)/U:27.01(0.28)
Tyr	UAU/C	A>C>G>U	A:28.44(0.36)/C:27.76(0.06) G:27.63(0.30)/U:27.51(0.14)
Val	GUA/U/G/C	C>U>G>A	A:27.32(0.25)/C:28.13(0.55) G:27.69(0.57)/U:28.04(0.18)

基于电子舌技术的氨基酸与密码子关系的初步研究

Primary Research of the Relationship between Genetic Codons and Amino Acids Based on the Technology of Electronic Tongue

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