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Deu M, Rattunde F, Chantereau J. 2006. A global view of
genetic diversity in cultivated sorghums using a core col-
lection.
Genome
49:168-180.
Diener AC, Gaxiola RA, Fink GR. 2001. Arabidopsis ALF5,
a multidrug efflux transporter gene family member, con-
fers resistance to toxins.
The Plant Cell
13:1625-1638.
Duncan RR, Clark RB, Furlani PR. 1983. Laboratory and
field evaluations of sorghum for response to aluminum
and acid soil.
Agronomy Journal
75:1023-1026.
Duncan RR. 1988. Sequential development of acid soil tol-
erant sorghum genotypes under field stress conditions.
Communications in Soil Science and Plant Analysis
19:1295-1305.
Durrett TP, Gassmann W, Rogers EE. 2007. The FRD3-
mediated efflux of citrate into the root vasculature is nec-
essary for efficient iron translocation.
Plant Physiology
144:197-205.
Elshire, RJ et al. 2011. A robust, simple genotyping-by-
sequencing .GBS. approach for high diversity species.
PLoS One
6:e19379 .2011.
Eticha D, Stass A, Horst WJ. 2005. Cell-wall pectin and its
degree of methylation in the maize root-apex: Signifi-
cance for genotypic differences in aluminium resistance.
Plant Cell and Environment
28:1410-1420.
Flores CI, Gourley LM, Pedersen JF, Clark RB. 1991. Inheri-
tance of acid-soil tolerance in sorghum .Sorghum bicolor.
grown on an ultisol. In: RJ Wright, VC Baligar, RP Mur-
rman, eds,
Plant-Soil Interactions at Low pH
. Dordrecht:
Kluwer Academic Publishers, pp 1081-1093.
Foy CD, Duncan RR, Waskom RM, Miller DR. 1993. Tol-
erance of sorghum genotypes to an acid, aluminum toxic
tatum subsoil.
Journal of Plant Nutrition
16:97-127.
Furlani PR, Lima M, Miranda LT De, Miranda LEC De,
Sawazaki E, Magnavaca R. 1986. Avalia¸ ao de lin-
hagens, materiais comerciais e duas popula¸ oes de milho
para
Handbook of Soil Acidity
. New York and Basel: Marcel
Dekker, Inc., pp 387-406.
Gourley LM, Rogers SA, Ruiz-Gomez C, Clark RB. 1990.
Genetic aspects of aluminum tolerance in sorghum.
Plant
and Soil
123:211-216.
Hoekenga OA, Maron LG, Pi neros MA, Cancado GMA,
Shaff J, Kobayashi Y, Ryan PR, Dong B, Delhaize
E, Sasaki T, Matsumoto H, Yamamoto Y, Koyama H,
Kochian LV. 2006. AtALMT1, which encodes a malate
transporter, is identified as one of several genes critical
for aluminum tolerance in Arabidopsis.
Proceedings of
the National Academy of Sciences of the United States of
America
103:9738-9743.
Jorge RA, Arruda P. 1997. Aluminum-induced organic acids
exudation by roots of an aluminum-tolerant tropical
maize.
Phytochemistry
45:675-681.
Kidd PS, Llugany M, Poschenrieder C, Gunse B, Barcelo J.
2001. The role of root exudates in aluminium resistance
and silicon-induced amelioration of aluminium toxicity
in three varieties of maize .Zea mays L . . .
Journal of
Experimental Botany
52:1339-1352.
Kochian LV, Hoekenga OA, Pi neros MA. 2004. How do crop
plants tolerate acid soils? - Mechanisms of aluminum
tolerance and phosphorous efficiency.
Annual Review of
Plant Biology
55:459-493.
Kollmeier M, Dietrich P, Bauer CS, Horst WJ, Hedrich
R. 2001. Aluminum activates a citrate-permeable anion
channel in the aluminum-sensitive zone of the maize
root apex. A comparison between an aluminum-sensitive
and an aluminum-resistant cultivar.
Plant Physiology
126:397-410.
Kovermann P, Meyer S, Hortensteiner S, Picco C, Scholz-
Starke J, Ravera S, Lee Y, and Martinoia E. 2007.
The Arabidopsis vacuolar malate channel is a mem-
beroftheALMTfamily.
The Plant Journal
52:1169-
1180.
Krill AM, Kirst M, Kochian LV, Buckler ES, Hoekenga OA.
2010. Association and linkage analysis of aluminum tol-
erance genes in maize.
Plos One
5:1-11.
Li L, He Z, Pandey GK, Tsuchiya T, Luan S. 2002. Functional
Cloning and Characterization of a Plant Efflux Carrier
for Multidrug and Heavy Metal Detoxification.
Journal
of Biological Chemistry
277:5360-5368.
Ligaba A, Katsuhara M, Ryan PR, Shibasaka M, Matsumoto
M. 2006. The BnALMT1 and BnALMT2 Genes From
Brassica napus L. Encode Aluminum-Activated Malate
Transporters that Enhance the Aluminum Resistance of
Plant Cells.
Plant Physiology
142:1294-1303.
Ligaba A, Maron L, Shaff J, Kochian L, Pi neros M. 2012.
Maize ZmALMT2 is a root anion transporter that medi-
ates constitutive root malate efflux.
Plant, Cell & Envi-
ronment
35:1185-1200.
Liu J, Magalhaes JV, Shaff J, Kochian LV. 2009. Aluminum-
activated citrate and malate transporters from the MATE
and ALMT families function independently to con-
fer Arabidopsis aluminum tolerance.
The Plant Journal
57:389-399.
tolerancia
ao
alumınio.
Pesquisa
Agropecu aria
Brasileira
21(6):655-660.
Furlani PR, Bastos CR, Borgonovi RA, Schaffert RE.1987.
Resposta diferencial de gen otipos de sorgo para
tolerancia ao alumınio em solu¸ ao nutritiva.
Pesquisa
Agropecu aria Brasileira
22:323-330.
Furlani PR, Bastos CR. 1990. Genetic control of aluminum
tolerance in sorghum. In: N El Bassam, M Dambroth,
BC Loughman, eds,
Genetic Aspects of Plant Mineral
Nutrition
. Dordrecht: Kluwer Academic Publishers, pp
215-219.
Furukawa J, Yamaji N, Wang H, Mitani N, Murata Y, Sato
K, Katsuhara M, Takeda K, Ma JF. 2007. An aluminum-
activated citrate transporter in barley.
Plant and Cell
Physiology
48:1081-1091.
Garcia Junior O, Silva WJ. 1979. Analise genetica da
tolerancia ao alumınio em milho.
Cienc. Cult.
31:585.
Garcia Junior O, Silva WJ, Massei MAS. 1979. An efficient
method for screening maize inbreds for Al tolerance.
Maydica
24:75-82.
Garvin DF, Carver BF. 2003. Role of the genotype in toler-
ance to acidity and aluminum toxicity. In: Rengel Z, ed,
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