高粱种子萌发过程中超微弱光子辐射的特征

doi:10.3724/SP.J.1006.2018.00783

Abstract

Abstract:

Ultra-weak photon radiation from germinated seed includes spontaneous photon emission of germinated seeds in the dark and delayed photon radiation induced by external light. In order to study dynamical feature and biological significance of ultra-weak photon radiation from sorghum during germination, 50 μg mL^-1 protein synthesis transcription inhibitor actinomycin D (AMD), 100 μg mL^-1protein synthesis translation inhibitor cycloheximide (CHM) and 650 μg mL^-1 respiration inhibitor were adopted to treat germinated sorghum seeds separately. There was a positive correlation (correlation coefficient was 0.93121) between the spontaneous photon emission intensity of germinated sorghum and seed fresh mass. AMD and CHM partially inhibited while NaN₃ almost completely inhibited the increase of fresh mass of sorghum seeds in germination process. It indicated that the spontaneous photon emission intensity from germinated sorghum seed can be taken as a signal of germination status from which RNA/DNA synthesis reaction is one of the sources and respiratory metabolism is the main source. The characteristic of delayed photon emission from germinated sorghum seeds can be expressed quantitatively by dynamical parameters such as initial photon number, coherence time and the integrated intensity of delayed photon emission. The cell metabolism and its changes in germination process of sorghum seeds can be understand and evaluated through a real-time, sensitive and non-destructive analysis of the integrated intensity of delayed photon emission from germinated sorghum seeds.

Key words: sorghum, germination, ultra-weak photon radiation, protein synthesis inhibitor, respiratory metabolic inhibitor, non-destructive test

Yan-Yan ZHAO, Gang XI. Characteristics of Ultra-weak Photon Emission from Sorghum Seeds during Germination[J].Acta Agronomica Sinica, 2018, 44(05): 783-789.

Figures/Tables 7

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萌发时间Germination time (d)	自发光子辐射Spontaneous photon emission, I_SL(counts s^-1)	初始光子数 Initial photon number, I₀ (counts s^-1)	相干时间 Coherence time, τ (s)	衰减常量Attenuation coefficient, β	拟合优度Determination coefficient, R²
0	7.64	237.28	0.26	0.84	0.993
1	8.57	256.05	0.27	0.87	0.992
2	9.51	298.72	0.30	0.95	0.996
3	10.38	333.00	0.32	0.96	0.992
4	10.39	337.77	0.35	0.97	0.995
5	10.17	323.95	0.32	0.96	0.991
6	10.41	344.55	0.34	0.97	0.995
7	10.27	331.29	0.33	0.96	0.996
8	10.42	353.76	0.38	0.97	0.996

萌发时间 Germination time (d)	自发光子辐射Spontaneous photon emission, I_SL (counts s^-1)	初始光子数 Initial photon number, I₀ (counts s^-1)	相干时间 Coherence time, τ (s)	衰减常量 Attenuation coefficient, β	拟合优度 Determination coefficient, R²
0	7.64	234.28	0.25	0.83	0.992
1	7.78	245.65	0.26	0.84	0.996
2	7.96	269.56	0.27	0.86	0.993
3	8.02	278.51	0.28	0.87	0.991
4	7.56	233.87	0.23	0.81	0.991
5	7.16	228.73	0.22	0.78	0.991
6	7.27	229.76	0.23	0.80	0.994
7	7.16	223.19	0.21	0.80	0.993
8	7.18	226.09	0.22	0.78	0.996

萌发时间Germination time (d)	自发光子辐射Spontaneous photon emission, I_SL (counts s^-1)	初始光子数 Initial photon number, I₀ (counts s^-1)	相干时间 Coherence time, τ (s)	衰减常量Attenuation coefficient, β	拟合优度Determination coefficient, R²
0	7.64	235.44	0.26	0.84	0.994
1	8.17	252.95	0.26	0.86	0.994
2	8.67	290.64	0.29	0.93	0.996
3	9.13	318.03	0.32	0.95	0.992
4	9.15	322.93	0.32	0.95	0.994
5	8.98	305.41	0.32	0.95	0.995
6	9.11	317.80	0.33	0.95	0.994
7	9.06	309.35	0.32	0.94	0.992
8	9.19	324.50	0.34	0.94	0.992

萌发时间Germination time (d)	自发光子辐射Spontaneous photon emission, I_SL(counts s^-1)	初始光子数 Initial photon number, I₀ (counts s^-1)	相干时间Coherence time, τ (s)	衰减常量Attenuation coefficient, β	拟合优度Determination coefficient, R²
0	7.64	235.07	0.26	0.83	0.993
1	7.93	249.44	0.26	0.85	0.990
2	8.31	281.77	0.29	0.92	0.994
3	8.64	311.75	0.30	0.92	0.993
4	8.73	314.14	0.31	0.93	0.991
5	8.56	307.29	0.31	0.93	0.996
6	8.70	312.99	0.31	0.94	0.992
7	8.61	299.47	0.31	0.93	0.993
8	8.67	318.98	0.32	0.93	0.995

Characteristics of Ultra-weak Photon Emission from Sorghum Seeds during Germination

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