000			02164nab a22003857a 4500
001			G94547
003			MX-TxCIM
005			20230728231731.0
008			211110s2010 xxu|||p|op||| 00| 0 eng d
022			_a1435-0653 (Online)
022			_a0011-183X
024	8		_ahttps://doi.org/10.2135/cropsci2009.11.0651
040			_aMX-TxCIM
041			_aeng
090			_aCIS-6120
100	1		_aNarro, L. _gGlobal Maize Program _gIntegrated Development Program _8INT2062 _91730
245	1	0	_aGenetics of aluminum-induced callose formation in maize roots, a selection trait for aluminum resistance
260			_aUSA : _bCSSA : _bWiley, _c2010.
500			_aPeer-review: Yes - Open Access: Yes|http://science.thomsonreuters.com/cgi-bin/jrnlst/jlresults.cgi?PC=MASTER&ISSN=0011-183X
500			_aPeer review
520			_aAcid soils and associated aluminum toxicity could limit maize (Zea mays L.) production on more than 3950 million hectares worldwide. Callose formation in root tips is a reliable indicator of Al-induced cell damage. We studied the modes of gene action determining callose formation in root tips using two diallel mating experiments involving a total of 33 maize inbred lines grown in 25 ìM Al nutrient solution. Highly significant differences were found among parents, crosses, general combining ability (GCA), specific combining ability (SCA) effects, and for the contrast of parents vs. crosses in both diallel experiments. These results indicate that additive and nonadditive gene effects were important in the expression of callose content.
536			_aGlobal Maize Program
546			_aText in English
591			_aCrop Science Society of America (CSSA)
594			_aINT2062
650		7	_2AGROVOC _91173 _aMaize
650		7	_2AGROVOC _915626 _aAluminium
650		7	_2AGROVOC _91755 _aRoots
650		7	_2AGROVOC _94688 _aAcid soils
650		7	_2AGROVOC _92367 _aCombining ability
700	1		_92582 _aArcos, A.L.
773	0		_tCrop Science _gv. 50, no. 5, p. 1848-1853 _dUSA : CSSA : Wiley, 2010. _wG444244 _x1435-0653
856	4		_yAccess only for CIMMYT Staff _uhttps://hdl.handle.net/20.500.12665/925
942			_cJA _2ddc _n0
999			_c28288 _d28288