中国马铃薯
中國馬鈴藷
중국마령서
CHINESE POTATO
2013年
2期
96-99
,共4页
李颖%李广存%李灿辉%屈冬玉*%黄三文
李穎%李廣存%李燦輝%屈鼕玉*%黃三文
리영%리엄존%리찬휘%굴동옥*%황삼문
马铃薯%二倍体自交系%F1杂种%自交不亲和%自交衰退
馬鈴藷%二倍體自交繫%F1雜種%自交不親和%自交衰退
마령서%이배체자교계%F1잡충%자교불친화%자교쇠퇴
potato%diploid inbreeding%F1 hybrid%self-incompatibility%inbreeding depression
马铃薯育种进程缓慢主要是由马铃薯四倍体遗传特性决定的.高度杂合的四倍体马铃薯中隐性基因表现频率低,使得很多有害的等位基因被隐藏在四倍体中,而有利等位基因很难重组到一个四倍体品种中,这是造成马铃薯杂交育种周期长的一个重要原因.马铃薯无性繁殖有利于保持原品种的优良性,生育期短;但储运成本高、容易退化.实生籽利用的优点是储运简便、基本不传播病虫害,且有利于知识产权保护.与四倍体实生种相比,二倍体F1育种可以通过不断自交将有害基因剔除掉,从而获得优良自交系用于F1实生籽生产.随着马铃薯研究的不断发展和马铃薯全基因组测序的基本完成,近几年二倍体F1实生籽育种成为了国际马铃薯研究的热点.然而,要实现二倍体实生籽生产,自交不亲和及其自交衰退是培育自交系的绊脚石.我们正在克隆自交不亲和抑制基因Sli,并且通过杂交将该基因整合到优良栽培品种中,为下一步培育出优良二倍体自交系奠定基础.同时我们也正在全基因组水平上挖掘马铃薯自交衰退相关基因区域,希望能进一步了解自交衰退的遗传机理,探索一条快速克服自交衰退的分子育种路径.这些工作将有助于建立马铃薯二倍体F1育种体系,带动马铃薯产业进入新的“绿色革命”.
馬鈴藷育種進程緩慢主要是由馬鈴藷四倍體遺傳特性決定的.高度雜閤的四倍體馬鈴藷中隱性基因錶現頻率低,使得很多有害的等位基因被隱藏在四倍體中,而有利等位基因很難重組到一箇四倍體品種中,這是造成馬鈴藷雜交育種週期長的一箇重要原因.馬鈴藷無性繁殖有利于保持原品種的優良性,生育期短;但儲運成本高、容易退化.實生籽利用的優點是儲運簡便、基本不傳播病蟲害,且有利于知識產權保護.與四倍體實生種相比,二倍體F1育種可以通過不斷自交將有害基因剔除掉,從而穫得優良自交繫用于F1實生籽生產.隨著馬鈴藷研究的不斷髮展和馬鈴藷全基因組測序的基本完成,近幾年二倍體F1實生籽育種成為瞭國際馬鈴藷研究的熱點.然而,要實現二倍體實生籽生產,自交不親和及其自交衰退是培育自交繫的絆腳石.我們正在剋隆自交不親和抑製基因Sli,併且通過雜交將該基因整閤到優良栽培品種中,為下一步培育齣優良二倍體自交繫奠定基礎.同時我們也正在全基因組水平上挖掘馬鈴藷自交衰退相關基因區域,希望能進一步瞭解自交衰退的遺傳機理,探索一條快速剋服自交衰退的分子育種路徑.這些工作將有助于建立馬鈴藷二倍體F1育種體繫,帶動馬鈴藷產業進入新的“綠色革命”.
마령서육충진정완만주요시유마령서사배체유전특성결정적.고도잡합적사배체마령서중은성기인표현빈솔저,사득흔다유해적등위기인피은장재사배체중,이유리등위기인흔난중조도일개사배체품충중,저시조성마령서잡교육충주기장적일개중요원인.마령서무성번식유리우보지원품충적우량성,생육기단;단저운성본고、용역퇴화.실생자이용적우점시저운간편、기본불전파병충해,차유리우지식산권보호.여사배체실생충상비,이배체F1육충가이통과불단자교장유해기인척제도,종이획득우량자교계용우F1실생자생산.수착마령서연구적불단발전화마령서전기인조측서적기본완성,근궤년이배체F1실생자육충성위료국제마령서연구적열점.연이,요실현이배체실생자생산,자교불친화급기자교쇠퇴시배육자교계적반각석.아문정재극륭자교불친화억제기인Sli,병차통과잡교장해기인정합도우량재배품충중,위하일보배육출우량이배체자교계전정기출.동시아문야정재전기인조수평상알굴마령서자교쇠퇴상관기인구역,희망능진일보료해자교쇠퇴적유전궤리,탐색일조쾌속극복자교쇠퇴적분자육충로경.저사공작장유조우건립마령서이배체F1육충체계,대동마령서산업진입신적“록색혁명”.
@@@@Potato breeding process is slow, mainly due to its tetraploid genetic characteristics. It takes large selection programmes on progeny plants derived from crosses between tetraploid potato cultivars to select a clone that has the right balance between unfavourable al eles and compensating al eles at the same or at other loci. The clonal propagation of potato offers important agronomic and genetic advantages. However, clonal propagation has more drawbacks, where true potato seed production can make up for these deficiencies. In order to achieve continuous progress in potato breeding, an alternative system should be developed that is based on the structural removal of unfavourable al eles. Diploid breeding can"purge"the detrimental al eles by constantly selfing to elite inbred lines for F1 seed production. The availability of genome sequence and re-sequencing leads diploid F1 breeding to be the hot topic. However, the hurdle in the development of diploid potato inbred lines is self-incompatibility and inbreeding depression. We are working on fine-mapping of an S locus inhibitor gene, and transferring the gene to elite cultivars. In addition, we focus on dissecting the inbreeding depression by re-sequencing doubled haploid popualtion, which would be essential for further genetic study of inbreeding loads in potato. The research wil facilitate the setup of the diploid F1 breeding system in potato that wil give birth to the Green Revolution of the potato industry.
