中文摘要：

【目的】研究栽培稻品种耐铝性及高州普通野生稻耐铝性的特点，明确供试品种中的耐铝品种和铝敏感品种，以及野生稻中的耐铝材料，为定位来自高州普通野生稻的耐铝基因奠定材料基础。【方法】以Al^3＋浓度为25、50和100μmol．L^-1的简单钙溶液处理1d后的苗期种子根或野生稻离蘖茎新生根相对根伸长量（relativeroot elongation，RRE）的大小评价材料的绝对耐铝性，以各材料的RRE与耐铝性对照品种日本晴的RRE之比作为相对根伸长比衡量材料的相对耐铝性。【结果】供试品种间、不同Al^3＋浓度、不同处理时间对水稻种子根相对根伸长量RRE的影响均存在显著差异（P〈0．0001）；综合来看，日本晴、L202、辽粳944和88B等为耐铝品种；以Al^3＋浓度为50μmol．L^-1的简单钙溶液处理1d后的RRE为指标衡量不同基因型材料的耐铝性是可靠的。广东高州普通野生稻种子根在Al^3＋浓度为50μmol．L。简单钙溶液处理1d后RRE值表明，材料之间的耐铝性存在极显著差异（P〈0．0001）。有55个编号材料的RRE≥0．50，为耐铝性材料。与栽培稻耐铝对照品种日本睛相比较，以50μmol-L^-1Al^3＋浓度的简单钙溶液处理1d后RRE值大于日本睛（RRE=0．6198）的供试野生稻有37个编号（GZW020的RRE最大，为1．8730）。对高州普通野生稻离蘖茎新生根以Al^3＋浓度为50μmol．L。溶液处理1d后RRE的比较，发现RRE〉0．50的耐铝性材料有13个。相关性分析表明，相同编号的野生稻其种子根RRE和离蘖茎新生根的RRE之间具有极显著的相关性（R=0．76012，P=0．0041）。认为高州普通野生稻材料蕴藏有耐铝的基因，随后在以栽培稻铝敏感品种华粳籼74为受体、耐铝野生稻GZW087为供体的BC3F2世代19个株系的耐铝性检测中发现2个株系具有耐铝性，表明来自野生稻亲本的耐铝性传递到了回交后代。【结论】水稻品种间

英文摘要：

[Objective] The tolerance of some rice varieties and O.rufipogon in Gaozhou to aluminum was studied. The experimental varieties of Al-tolerant and Al-sensitive ones were distinguished and Al-tolerant accessions of O.rufipogon in Gaozhou were also screened out. The materials for mapping the genes related to Al-tolerance of O.rufipogon in Gaozhou were tested. [Method] In this study, seedling roots of varieties and O.rufipogon accessions or regenerative roots from tillerings of O.rufipogon were treated in 0.5 mmol.L^-1 CaCl2 solution with 25, 50, and 100 μmol.L^-1 Al^3＋ for 1 d, the relative root elongation （RRE） was used as a parameter to evaluate the aluminum tolerance. [Result] Relative root elongation （RRE） of experimental rice varieties were significantly affected by genotypes, Al^3＋ contents and treatment time （P〈0.0001）. Nipponbare, L202, Liaojing944, and 88B wereAl-tolerant varieties. It is the reliable method to evaluate Al-tolerances of different genotypes in rice with the parameter RRE of seedlings which growing in 0.5 mmol.L1 CaCl2 solution with 50μmol.L^-1 Al^3＋ for 1 d. Besides, RRE values of 69 accessions of O.rufipogon in Gaozhou were significantly different （P〈0.0001）, 55 accessions were Al-tolerant with RRE≥0.50. Compared with Nipponbare, an Al-tolerant control variety, RRE values of 37 accessions were larger than that of Nipponbare （RRE=0.6198） and the largest RRE was 1.8730 of GZW020. Analyzing RRE values of regenerative roots from tillerings of 17 accessions of O.rufipogon in Gaozhou, it showed that 13 accessions were Al-tolerant with RRE≥0.50. Meanwhile, the correlation between RRE value of seedlings and RRE value of tillerings of the same accession was significant （R= 0.76012, P=0.0041）. It is considered that some accessions of O.rufipogon in Gaozhou contain Al-tolerant genes. Furthermore, Al-tolerance was detected in 2 lines in BC3F2 generation between Huajingxian 74, an Al-sensitive variety, and GZW087, one of the Al-tolerant accessions of O.rufipogon