A Bioinformatics Study on Key Enzymes Involved in Tyrosine Metabolism in Beet

doi:10.11924/j.issn.1000-6850.casb2023-0115

Abstract

Abstract:

To understand the characteristics and evolutionary relationships of key enzymes involved in the tyrosine metabolism pathway in sugar beets, taking plants such as sugar beet, spinach, and soybean as experimental materials, sequence information of five key enzymes in the tyrosine metabolism pathway (PPO, TAT, TYDC, HPPD, HPPR) was collected using the NCBI database. The physicochemical properties of the key enzymes were analyzed using ExPASy-ProtParam software and MEGA-7 software, their sequence similarities and evolutionary distances were compared, and a phylogenetic tree was constructed. The analysis of physicochemical properties showed that all five key enzymes in the tyrosine metabolism pathway of sugar beet were unstable hydrophilic proteins, and the number of amino acids in sugar beet PPO was the highest; the phylogenetic tree analysis results showed that there was high similarity in PPO and HPPD between sugar beet and spinach; beets had high similarity with TAT of soybeans, TYDC of potatoes, and HPPR of barley, respectively. This study provided a reference for other crops to explore the key enzyme function of sugar beet tyrosine metabolism pathway and laid a foundation for further research on sugar beet genomics.

Key words: beet, tyrosine, catalytic enzyme, metabolic pathway, bioinformatics analysis

YANG Jiaqi, HAN Guangyuan, LIU Naixin, ZHOU Qin. A Bioinformatics Study on Key Enzymes Involved in Tyrosine Metabolism in Beet[J]. Chinese Agricultural Science Bulletin, 2024, 40(9): 124-131.

Figures/Tables 10

References 32

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种类	序列号	氨基酸数/个	相对分子质量	等电点	稳定性	相对平均亲水性
甜菜	AQS22861.1	604	68496.02	6.79	不稳定	亲水性
烟草	AGK83468.1	590	159202.07	4.68	不稳定	亲水性
玉米	ACG28948.1	569	62715.09	5.88	不稳定	亲水性
水稻	ACS15334.1	576	63287.62	5.83	不稳定	亲水性
高粱	AHX26183.1	553	60769.89	5.62	不稳定	亲水性
马铃薯	AAA85121.1	597	66888.35	6.63	稳定	亲水性
花生	QHO39883.1	430	50188.02	6.17	不稳定	亲水性
小麦	AEM45931.1	557	61307.58	6.37	不稳定	亲水性
菠菜	CAA62377.1	638	73132.39	5.89	不稳定	亲水性
芝麻	AFJ42577.1	584	65307.02	7.20	稳定	亲水性

种类	序列号	氨基酸数/个	相对分子质量	等电点	稳定性	相对平均亲水性
甜菜	AQS22861.1	604	68496.02	6.79	不稳定	亲水性
烟草	AGK83468.1	590	159202.07	4.68	不稳定	亲水性
玉米	ACG28948.1	569	62715.09	5.88	不稳定	亲水性
水稻	ACS15334.1	576	63287.62	5.83	不稳定	亲水性
高粱	AHX26183.1	553	60769.89	5.62	不稳定	亲水性
马铃薯	AAA85121.1	597	66888.35	6.63	稳定	亲水性
花生	QHO39883.1	430	50188.02	6.17	不稳定	亲水性
小麦	AEM45931.1	557	61307.58	6.37	不稳定	亲水性
菠菜	CAA62377.1	638	73132.39	5.89	不稳定	亲水性
芝麻	AFJ42577.1	584	65307.02	7.20	稳定	亲水性

种类	序列号	氨基酸数/个	相对分子质/Mr	等电点/PI	稳定性	相对平均亲性
甜菜	XP_010666077.2	426	47612.97	5.78	不稳定	亲水性
拟南芥	BAB10727.1	414	45902.06	5.66	稳定	疏水性
玉米	AQK58770.1	430	46975.42	5.95	稳定	疏水性
大豆	NP_001238408.1	425	46747.92	5.41	稳定	疏水性
紫花苜蓿	AAY85183.1	410	45173.07	5.38	稳定	疏水性
彩叶草	CAD30341.1	411	45179.41	5.96	不稳定	疏水性
高粱	XP_021313205.1	428	46505.79	5.38	稳定	疏水性
辣椒	XP_016580779.1	421	46739.91	5.91	稳定	亲水性
欧洲油菜	XP_013676584.2	420	46515.60	5.19	不稳定	疏水性
荠菜	XP_006283808.1	419	46276.24	5.04	不稳定	疏水性

种类	序列号	氨基酸数/个	相对分子质/Mr	等电点/PI	稳定性	相对平均亲性
甜菜	XP_010666077.2	426	47612.97	5.78	不稳定	亲水性
拟南芥	BAB10727.1	414	45902.06	5.66	稳定	疏水性
玉米	AQK58770.1	430	46975.42	5.95	稳定	疏水性
大豆	NP_001238408.1	425	46747.92	5.41	稳定	疏水性
紫花苜蓿	AAY85183.1	410	45173.07	5.38	稳定	疏水性
彩叶草	CAD30341.1	411	45179.41	5.96	不稳定	疏水性
高粱	XP_021313205.1	428	46505.79	5.38	稳定	疏水性
辣椒	XP_016580779.1	421	46739.91	5.91	稳定	亲水性
欧洲油菜	XP_013676584.2	420	46515.60	5.19	不稳定	疏水性
荠菜	XP_006283808.1	419	46276.24	5.04	不稳定	疏水性

种类	序列号	氨基酸数/个	相对分子质量/Mr	等电点/PI	稳定性	相对平均亲水性
甜菜	XP_010666091.1	510	57172.63	6.04	不稳定	亲水性
拟南芥	CAB56038.1	489	54219.10	5.79	稳定	亲水性
玉米	XP_008651749.1	528	57435.50	5.91	不稳定	亲水性
高粱	XP_002459778.2	505	55718.57	5.81	不稳定	亲水性
马铃薯	AHI16967.1	510	57038.57	6.67	不稳定	疏水性
花生	QHO42829.1	131	13916.94	4.80	不稳定	疏水性
菠菜	XP_021838623.1	500	55500.84	6.04	不稳定	亲水性
大豆	XP_003535055.2	498	55076.80	7.56	稳定	疏水性
芝麻	XP_011080126.1	490	54122.84	5.72	不稳定	亲水性
荠菜	XP_006299702.2	490	54593.58	6.16	稳定	亲水性