绣球染色体制片技术优化及rDNA物理定位

doi:10.11707/j.1001-7488.20211106

摘要/Abstract

摘要：

目的: 建立染色体形态良好、分裂相内染色体分散且无细胞质背景的绣球根尖高质量染色体制片技术，完善中期染色体45S rDNA和5S rDNA荧光原位杂交（FISH）技术体系，为深入开展绣球属植物分子细胞遗传学研究奠定基础。方法: 以绣球‘无尽夏’当年生半木质化枝条水培长出的幼嫩根尖为材料，分别采用1 MPa一氧化二氮（N₂O）、0.7 mmol·L^-1环己酰胺、2 mmol·L^-1 8-羟基喹啉对根尖进行不同时间预处理。预处理后的根尖分生组织在4%纤维素酶和2%果胶酶混合酶液中酶解后进行染色体制片。以45S rDNA和5S rDNA为探针，对中期染色体进行原位杂交。结果: 1）1 MPa一氧化二氮预处理的材料中，预处理0.5 h，大部分中期分裂相染色体较长，浓缩不充分；预处理1 h，染色体浓缩适当，大部分染色体的着丝粒位置可辨；预处理2 h，染色体浓缩过度，呈点状。0.7 mmol·L^-1环己酰胺预处理的材料中，预处理1 h和3 h，染色体偏长，浓缩不充分；预处理5 h，染色体浓缩适当，但着丝粒位置显示不明显。2 mmol·L^-1 8-羟基喹啉预处理的材料中，2、4、6 h 3个时间梯度均可得到染色体浓缩适当的材料，各处理时间之间对染色体形态的影响差异并不明显，但着丝粒位置不可辨。综合考虑后认为，绣球根尖预处理的最适条件为1 MPa一氧化二氮预处理1 h。2）3个酶解时间梯度中，酶解0.5 h的染色体制片，中期分裂相和细胞核周围存在明显的细胞质残留；酶解1 h的染色体制片，中期分裂相背景干净、染色体分散程度好；酶解2 h的染色体制片，观察到很多不完整分裂相，分裂相间无法区分，染色体容易丢失。因此，绣球根尖分生组织在4%纤维素酶和2%果胶酶混合酶液中37℃酶解1 h比较合适。3）绣球‘无尽夏’是二倍体，染色体数目为36（2n=2x=36）。45S rDNA长、短探针的FISH效果相似，均产生很强的杂交信号，位点位于1对近端着丝粒染色体的短臂末端；5S rDNA长、短探针的FISH信号均较弱，长探针的检出率高于短探针，杂交信号位于1对端着丝粒染色体的长臂末端。结论: 成功建立绣球‘无尽夏’根尖高质量中期染色体制备及rDNA物理定位技术体系，该体系可高效确定绣球属植物的染色体数目及rDNA分布，为绣球属资源鉴定、杂交育种的亲本选配提供参考，从而指导绣球属植物的杂交育种实践。

关键词: 绣球, 染色体制片, rDNA, 荧光原位杂交(FISH)

Abstract:

Objective: The purpose of this study is to develop a technique for high quality chromosome preparation of root tips, in order to improve the fluorescence in situ hybridization(FISH) system for 45S rDNA and 5S rDNA of Hydrangea macrophylla 'Endless Summer' with dispersed and good morphology chromosomes in the cell division phase, which would provide a basis for improving the molecular cytogenetic study of Hydrangea. Method: Root tips taken from semi-lignified branches of H. macrophylla 'Endless Summer' through hydroponic culture were pre-treated with 1 MPa nitrous oxide, 0.7 mmol·L^-1 cycloheximide and 2 mmol·L^-1 8-hydroxyquinoline respectively. Chromosome was prepared after meristem enzymolysis of the pre-treated root tips with a mixture of 4% cellulase and 2% pectinase, and the metaphase chromosome was hybridized in situ with 45S rDNA and 5S rDNA probes. Result: 1) Materials pre-treated with 1 MPa nitrous oxide for 0.5 h, their chromosomes were still insufficiently condensed and too long for analysis; those pre-treated for 1 h, the chromosomes condensation were appropriate, and the centromeres of most chromosomes could be identified; pre-treatment for 2 h, the chromosomes were over-condensed and punctate. Materials pre-treated with 0.7 mmol·L^-1 cycloheximide for 1 h and 3 h, their chromosomes were insufficiently condensed; pre-treatment for 5 h, the chromosomes were properly condensed, but the centromere positions of most chromosomes were not discernible. All materials pre-treated with 2 mmol·L^-1 8-hydroxyquinoline for 2 h, 4 h or 6 h, their chromosomes condensation were all appropriate, but the chromosome centromeres could not be identified. So 1 h treatment with 1 MPa nitrous oxide is the most suitable pre-treatment condition for H. macrophylla 'Endless Summer' root tips. 2) Three enzymatic treatment time gradients were used. Chromosomes digested for 0.5 h, their cytoplasm could be observed obviously around the metaphase and the nucleus; chromosomes digested for 1 h, their background were clean and the chromosomes well dispersed; when digestion time expanded to 2 h, the chromosomes were easily lost and many incomplete mitotic phases were observed. Therefore, the most suitable treatment for H. macrophylla 'Endless Summer' root tip was digested in the mixture of 4% cellulase and 2% pectinase at 37℃ for 1 h. 3) H. macrophylla 'Endless Summer' is diploid with 36 chromosomes (2n=2x=36). The FISH of 45S rDNA long and short probes showed similar effects, both produced strong hybridization signals which located at the end of the short arm of a pair of acrocentric chromosomes. Both the long and the short 5S rDNA probes only revealed weak FISH signals, but the detection rate of the long probes was higher than that of the short probes. The 5S rDNA located at the long arm ends of one pair of telocentric chromosomes. Conclusion: This study successfully established a high quality metaphase chromosome preparation and rDNA physical localization technical system for H. macrophylla. This system can efficiently analyze and determine the chromosome number and rDNA distribution in Hydrangea plants. This can be used in Hydrangea resources identification and provide a basis and guidance for Hydrangea hybrid breeding.

Key words: Hydrangea macrophylla, chromosome preparation, rDNA, fluorescence in situ hybridization(FISH)

中图分类号:

S718.46

郭瑞红,邱帅,刘光欣,高凯,魏建芬,席梦利. 绣球染色体制片技术优化及rDNA物理定位[J]. 林业科学, 2021, 57(11): 59-67.

Ruihong Guo,Shuai Qiu,Guangxin Liu,Kai Gao,Jianfen Wei,Mengli Xi. Optimization of Chromosome Preparation and rDNA Physical Localization of Hydrangea macrophylla[J]. Scientia Silvae Sinicae, 2021, 57(11): 59-67.

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预处理试剂 Pretreatment reagent	处理时间 Processing time/h	形态良好的中期分裂相占比 Proportion of metaphase chromosomes in good shape (%)			平均值±标准偏差 Mean ± standard deviation (%)
预处理试剂 Pretreatment reagent	处理时间 Processing time/h	制片1 Repeat 1	制片2 Repeat 2	制片3 Repeat 3	平均值±标准偏差 Mean ± standard deviation (%)
N₂O (1 MPa)	0.5	40.00	50.00	50.00	46.67±5.77
	1	54.17	72.22	50.00	58.80±11.81
	2	75.00	37.50	37.50	50.00±21.65
环己酰胺 Cycloheximide(0.7 mmol·L^-1)	1	27.00	35.71	30.77	31.25±4.24
	3	53.85	50.00	53.33	52.39±2.09
	5	33.33	20.79	25.00	26.37±6.38
8-羟基喹啉 8-hydroxyquinoline(2 mmol·L^-1)	2	37.50	26.67	33.33	32.50±5.46
	4	50.00	42.86	42.86	45.24±4.12
	6	33.33	42.86	28.57	34.92±7.28

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