<mods:mods version="3.3" xsi:schemaLocation="http://www.loc.gov/mods/v3 http://www.loc.gov/standards/mods/v3/mods-3-3.xsd" xmlns:mods="http://www.loc.gov/mods/v3" xmlns:xsi="http://www.w3.org/2001/XMLSchema-instance"><mods:titleInfo><mods:title>Interpreting genotype × environment interaction in tropical maize using linked molecular markers and environmental covariables</mods:title></mods:titleInfo><mods:name type="personal"><mods:namePart type="given">J</mods:namePart><mods:namePart type="family">Crossa</mods:namePart><mods:role><mods:roleTerm type="text">author</mods:roleTerm></mods:role></mods:name><mods:name type="personal"><mods:namePart type="given">M</mods:namePart><mods:namePart type="family">Vargas</mods:namePart><mods:role><mods:roleTerm type="text">author</mods:roleTerm></mods:role></mods:name><mods:name type="personal"><mods:namePart type="given">F A van</mods:namePart><mods:namePart type="family">Eeuwijk</mods:namePart><mods:role><mods:roleTerm type="text">author</mods:roleTerm></mods:role></mods:name><mods:name type="personal"><mods:namePart type="given">C</mods:namePart><mods:namePart type="family">Jiang</mods:namePart><mods:role><mods:roleTerm type="text">author</mods:roleTerm></mods:role></mods:name><mods:name type="personal"><mods:namePart type="given">G O</mods:namePart><mods:namePart type="family">Edmeades</mods:namePart><mods:role><mods:roleTerm type="text">author</mods:roleTerm></mods:role></mods:name><mods:name type="personal"><mods:namePart type="given">D A</mods:namePart><mods:namePart type="family">Hoisington</mods:namePart><mods:role><mods:roleTerm type="text">author</mods:roleTerm></mods:role></mods:name><mods:abstract>An understanding of the genetic and environmental&#13;
basis of genotype´environment interaction (GEI)&#13;
is of fundamental importance in plant breeding. In mapping&#13;
quantitative trait loci (QTLs), suitable genetic populations&#13;
are grown in different environments causing&#13;
QTLs´environment interaction (QEI). The main objective&#13;
of the present study is to show how Partial Least&#13;
Squares (PLS) regression and Factorial Regression (FR)&#13;
models using genetic markers and environmental covariables&#13;
can be used for studying QEI related to GEI. Biomass&#13;
data were analyzed from a multi-environment trial&#13;
consisting of 161 lines from a F3:4 maize segregating&#13;
population originally created with the purpose of mapping&#13;
QTLs loci and investigating adaptation differences&#13;
between highland and lowland tropical maize. PLS and&#13;
FR methods detected 30 genetic markers (out of 86) that&#13;
explained a sizeable proportion of the interaction of&#13;
maize lines over four contrasting environments involving&#13;
two low-altitude sites, one intermediate-altitude site, and&#13;
one high-altitude site for biomass production. Based on a&#13;
previous study, most of the 30 markers were associated&#13;
with QTLs for biomass and exhibited significant QEI. It&#13;
was found that marker loci in lines with positive GEI for&#13;
the highland environments contained more highland alleles,&#13;
whereas marker loci in lines with positive GEI for&#13;
intermediate and lowland environments contained more&#13;
lowland alleles. In addition, PLS and FR models identified maximum temperature as the most-important environmental&#13;
covariable for GEI. Using a stepwise variable&#13;
selection procedure, a FR model was constructed for&#13;
GEI and QEI that exclusively included cross products&#13;
between genetic markers and environmental covariables.&#13;
Higher maximum temperature in low- and intermediatealtitude&#13;
sites affected the expression of some QTLs,&#13;
while minimum temperature affected the expression of&#13;
other QTLs.</mods:abstract><mods:classification authority="lcc">Genetics and Genomics</mods:classification><mods:originInfo><mods:dateIssued encoding="iso8061">1999</mods:dateIssued></mods:originInfo><mods:originInfo><mods:publisher>Springer Verlag</mods:publisher></mods:originInfo><mods:genre>Article</mods:genre></mods:mods>