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3. Duplicate and Conquer: Multiple Homologs of PHOSPHORUS-STARVATION TOLERANCE1 Enhance Phosphorus Acquisition and Sorghum Performance on Low-Phosphorus Soils

Author

Hufnagel, Barbara, de Sousa, Sylvia M., Assis, Lidianne, Guimaraes, Claudia T., Leiser, Willmar, Azevedo, Gabriel C., Negri, Barbara, Larson, Brandon G., Shaff, Jon E., Pastina, Maria Marta, Barros, Beatriz A., Weltzien, Eva, Rattunde, Henry Frederick W., Viana, Joao H., Clark, Randy T., Falcão, Alexandre, Gazaffi, Rodrigo, Garcia, Antonio Augusto F., Schaffert, Robert E., Kochian, Leon V., and Magalhaes, Jurandir V.

Published
2014
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5. Aluminum tolerance in maize is associated with higher MATE1 gene copy number

Author

Maron, Lyza G., Guimarães, Claudia T., Kirst, Matias, Albert, Patrice S., Birchler, James A., Bradbury, Peter J., Buckler, Edward S., Coluccio, Alison E., Danilova, Tatiana V., Kudrna, David, Magalhaes, Jurandir V., Piñeros, Miguel A., Schatz, Michael C., Wing, Rod A., and Kochian, Leon V.

Published
2013

7. ZmMATE1 improves grain yield and yield stability in maize cultivated on acid soil.

Author

Vasconcellos, Renato C. C., Mendes, Flávia F., de Oliveira, Antônio Carlos, Guimarães, Lauro J. M., Albuquerque, Paulo E. P., Pinto, Marcos O., Barros, Beatriz A., Pastina, Maria Marta, Magalhaes, Jurandir V., and Guimaraes, Claudia T.

Subjects
ACID soils, LOCUS (Genetics), GRAIN yields, TOXICOLOGY of aluminum, CORN breeding, FOOD supply, CORN
Abstract

The development of aluminum (Al)‐tolerant cultivars is a complementary strategy to overcome the constraints caused by Al toxicity on acid soils and can contribute positively to the food supply for the growing global population. A major Al tolerance quantitative trait locus in maize is controlled by a citrate transporter encoded by ZmMATE1. Our goal was to evaluate the impact of the superior allele of ZmMATE1 on the yield performance of maize lines and hybrids cultivated on acid soils. Near‐isogenic lines carrying the superior allele of ZmMATE1, and the recurrent Al‐sensitive parent were crossed with elite lines, generating near‐isogenic hybrids contrasting for these alleles. All maize genotypes carrying this superior allele were more Al tolerant in nutrient solution than their isogenic counterparts having the ZmMATE1 allele derived from the Al‐sensitive parent. These genotypes were cultivated in control and Al stress soils for 2 yr. Aluminum toxicity caused a significant yield reduction of 18.7% for lines and 14.7% for hybrids over the 2 yr. The yield performance of maize genotypes declined in the second year compared with the first year, probably due to water deficiency after the grain‐filling stage. The superior allele of ZmMATE1 in maize hybrids conferred yield gains from 21 to 48% compared with the hybrids harboring the alternative allele in the Al stress soil in the first and second years, respectively. As this superior allele is rare in maize and is likely absent in several elite germplasms, molecular breeding based on ZmMATE1 can improve maize yield stability on acid soils. Core Ideas: High Al toxicity on acid soil causes a significant reduction in maize yield.The superior allele of ZmMATE1 improves maize yield on acid soil.Yield constraints on acid soil are ameliorated by this ZmMATE1 allele in maize hybrids.This ZmMATE1 allele is strategic in maize breeding to increase yield stability on acid soils. [ABSTRACT FROM AUTHOR]

Published
2021
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8. Root Adaptation via Common Genetic Factors Conditioning Tolerance to Multiple Stresses for Crops Cultivated on Acidic Tropical Soils.

Author

Barros, Vanessa A., Chandnani, Rahul, de Sousa, Sylvia M., Maciel, Laiane S., Tokizawa, Mutsutomo, Guimaraes, Claudia T., Magalhaes, Jurandir V., and Kochian, Leon V.

Subjects
ACID soils, PLANT breeding, ZINC-finger proteins, PROTEIN kinases, GENE regulatory networks, WATERLOGGING (Soils), PLANT-water relationships
Abstract

Crop tolerance to multiple abiotic stresses has long been pursued as a Holy Grail in plant breeding efforts that target crop adaptation to tropical soils. On tropical, acidic soils, aluminum (Al) toxicity, low phosphorus (P) availability and drought stress are the major limitations to yield stability. Molecular breeding based on a small suite of pleiotropic genes, particularly those with moderate to major phenotypic effects, could help circumvent the need for complex breeding designs and large population sizes aimed at selecting transgressive progeny accumulating favorable alleles controlling polygenic traits. The underlying question is twofold: do common tolerance mechanisms to Al toxicity, P deficiency and drought exist? And if they do, will they be useful in a plant breeding program that targets stress-prone environments. The selective environments in tropical regions are such that multiple, co-existing regulatory networks may drive the fixation of either distinctly different or a smaller number of pleiotropic abiotic stress tolerance genes. Recent studies suggest that genes contributing to crop adaptation to acidic soils, such as the major Arabidopsis Al tolerance protein, AtALMT1, which encodes an aluminum-activated root malate transporter, may influence both Al tolerance and P acquisition via changes in root system morphology and architecture. However, trans -acting elements such as transcription factors (TFs) may be the best option for pleiotropic control of multiple abiotic stress genes, due to their small and often multiple binding sequences in the genome. One such example is the C2H2-type zinc finger, AtSTOP1, which is a transcriptional regulator of a number of Arabidopsis Al tolerance genes, including AtMATE and AtALMT1 , and has been shown to activate AtALMT1 , not only in response to Al but also low soil P. The large WRKY family of transcription factors are also known to affect a broad spectrum of phenotypes, some of which are related to acidic soil abiotic stress responses. Hence, we focus here on signaling proteins such as TFs and protein kinases to identify, from the literature, evidence for unifying regulatory networks controlling Al tolerance, P efficiency and, also possibly drought tolerance. Particular emphasis will be given to modification of root system morphology and architecture, which could be an important physiological "hub" leading to crop adaptation to multiple soil-based abiotic stress factors. [ABSTRACT FROM AUTHOR]

Published
2020
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9. Multiple interval QTL mapping and searching for PSTOL1 homologs associated with root morphology, biomass accumulation and phosphorus content in maize seedlings under low-P.

Author

Azevedo, Gabriel C., Cheavegatti-Gianotto, Adriana, Negri, Bárbara F., Hufnagel, Bárbara, da Costa e Silva, Luciano, Magalhaes, Jurandir V., Garcia, Antonio Augusto F., Lana, Ubiraci G. P., de Sousa, Sylvia M., and Guimaraes, Claudia T.

Subjects
CORN seeds, PLANT root morphology, BIOMASS, ECOPHYSIOLOGY of seedlings, PHOSPHORUS in soils, GENE expression in plants
Abstract

Background: Modifications in root morphology are important strategies to maximize soil exploitation under phosphorus starvation in plants. Here, we used two multiple interval models to map QTLs related to root traits, biomass accumulation and P content in a maize RIL population cultivated in nutrient solution. In addition, we searched for putative maize homologs to PSTOL1, a gene responsible to enhance early root growth, P uptake and grain yield in rice and sorghum. Results: Based on path analysis, root surface area was the root morphology component that most strongly contributed to total dry weight and to P content in maize seedling under low-P availability. Multiple interval mapping models for single (MIM) and multiple traits (MT-MIM) were combined and revealed 13 genomic regions significantly associated with the target traits in a complementary way. The phenotypic variances explained by all QTLs and their epistatic interactions using MT-MIM (23.4 to 35.5 %) were higher than in previous studies, and presented superior statistical power. Some of these QTLs were coincident with QTLs for root morphology traits and grain yield previously mapped, whereas others harbored ZmPSTOL candidate genes, which shared more than 55 % of amino acid sequence identity and a conserved serine/threonine kinase domain with OsPSTOL1. Additionally, four ZmPSTOL candidate genes co-localized with QTLs for root morphology, biomass accumulation and/or P content were preferentially expressed in roots of the parental lines that contributed the alleles enhancing the respective phenotypes. Conclusions: QTL mapping strategies adopted in this study revealed complementary results for single and multiple traits with high accuracy. Some QTLs, mainly the ones that were also associated with yield performance in other studies, can be good targets for marker-assisted selection to improve P-use efficiency in maize. Based on the co-localization with QTLs, the protein domain conservation and the coincidence of gene expression, we selected novel maize genes as putative homologs to PSTOL1 that will require further validation studies. [ABSTRACT FROM AUTHOR]

Published
2015
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10. Genetic Architecture of Phosphorus Use Efficiency in Tropical Maize Cultivated in a Low-P Soil.

Author

Mendes, Flávia F., Guimarães, Lauro J. M., Souza, João Cândido, Guimarães, Paulo Evaristo O., Magalhaes, Jurandir V., Garcia, Antonio Augusto F., Parentoni, Sidney N., and Guimaraes, Claudia T.

Subjects
PHOSPHORUS in agriculture, AGRICULTURAL productivity, PHOSPHORUS in soils, CORN genetics, PLANT gene mapping, CORN varieties, CORN breeding
Abstract

Phosphorus (P) deficiency is a major limiting factor for crop production in several countries. A better understanding of the genetic components of P use efficiency (PUE) is required to improve crop performance in low-P soils. To date, no QTLs (quantitative trait loci) were mapped for PUE using grain yield and other late phenotypic data in tropical conditions. Thus, we evaluated the genetic architecture of PUE in tropical maize (Zea mays L.) using multiple interval mapping for design III in a population of 140 RILs (recombinant inbred lines) backcrossed with both parental lines. The parental lines contrasted for yield and for PUE, a phenotypic index that was further decomposed into P acquisition efficiency (PAE) and P utilization efficiency. Our results showed that dominance effects were more important than additive effects for explaining the variations in PUE and its components. Approximately 80% of the QTLs mapped for PAE co-localized with those for PUE, indicating that the efficiency in acquiring P is the main determinant of PUE in tropical maize. Also, QTLs for PUE and PAE were located near to candidate genes previously associated with root development. Thus, we present important information to guide breeding strategies for the development of maize cultivars more adapted to P deficiency. [ABSTRACT FROM AUTHOR]

Published
2014
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11. Genetic dissection of Al tolerance QTLs in the maize genome by high density SNP scan.

Author

Guimaraes, Claudia T., Simoes, Christiano C., Pastina, Maria Marta, Maron, Lyza G., Magalhaes, Jurandir V., Vasconcellos, Renato C. C., Guimaraes, Lauro J. M., Lana, Ubiraci G. P., Tinoco, Carlos F. S., Noda, Roberto W., Jardim-Belicuas, Silvia N., Kochian, Leon V., Alves, Vera M. C., and Parentoni, Sidney N.

Subjects
*PLANT genomes, *PLANT chromosomes, *TOXICOLOGY of aluminum, *ACID soils, CORN genetics
Abstract

Background Aluminum (Al) toxicity is an important limitation to food security in tropical and subtropical regions. High Al saturation on acid soils limits root development, reducing water and nutrient uptake. In addition to naturally occurring acid soils, agricultural practices may decrease soil pH, leading to yield losses due to Al toxicity. Elucidating the genetic and molecular mechanisms underlying maize Al tolerance is expected to accelerate the development of Altolerant cultivars. Results Five genomic regions were significantly associated with Al tolerance, using 54,455 SNP markers in a recombinant inbred line population derived from Cateto Al237. Candidate genes co-localized with Al tolerance QTLs were further investigated. Near-isogenic lines (NILs) developed for ZmMATE2 were as Al-sensitive as the recurrent line, indicating that this candidate gene was not responsible for the Al tolerance QTL on chromosome 5, qALT5. However, ZmNrat1, a maize homolog to OsNrat1, which encodes an Al3+ specific transporter previously implicated in rice Al tolerance, was mapped at ~40 Mbp from qALT5. We demonstrate for the first time that ZmNrat1 is preferentially expressed in maize root tips and is up-regulated by Al, similarly to OsNrat1 in rice, suggesting a role of this gene in maize Al tolerance. The strongest-effect QTL was mapped on chromosome 6 (qALT6), within a 0.5 Mbp region where three copies of the Al tolerance gene, ZmMATE1, were found in tandem configuration. qALT6 was shown to increase Al tolerance in maize; the qALT6-NILs carrying three copies of ZmMATE1 exhibited a two-fold increase in Al tolerance, and higher expression of ZmMATE1 compared to the Al sensitive recurrent parent. Interestingly, a new source of Al tolerance via ZmMATE1 was identified in a Brazilian elite line that showed high expression of ZmMATE1 but carries a single copy of ZmMATE1. Conclusions High ZmMATE1 expression, controlled either by three copies of the target gene or by an unknown molecular mechanism, is responsible for Al tolerance mediated by qALT6. As Al tolerant alleles at qALT6 are rare in maize, marker-assisted introgression of this QTL is an important strategy to improve maize adaptation to acid soils worldwide. [ABSTRACT FROM AUTHOR]

Published
2014
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12. Association Mapping Provides Insights into the Origin and the Fine Structure of the Sorghum Aluminum Tolerance Locus, AltSB.

Author

Caniato, Fernanda F., Hamblin, Martha T., Guimaraes, Claudia T., Zhang, Zhiwu, Schaffert, Robert E., Kochian, Leon V., and Magalhaes, Jurandir V.

Subjects
LOCUS (Genetics), SORGHUM, GENE mapping, TOXICOLOGY of aluminum, PLANT roots, ACID soils, FOOD security
Abstract

Root damage caused by aluminum (Al) toxicity is a major cause of grain yield reduction on acid soils, which are prevalent in tropical and subtropical regions of the world where food security is most tenuous. In sorghum, Al tolerance is conferred by SbMATE, an Al-activated root citrate efflux transporter that underlies the major Al tolerance locus, AltSB, on sorghum chromosome 3. We used association mapping to gain insights into the origin and evolution of Al tolerance in sorghum and to detect functional variants amenable to allele mining applications. Linkage disequilibrium across the AltSB locus decreased much faster than in previous reports in sorghum, and reached basal levels at approximately 1000 bp. Accordingly, intra-locus recombination events were found to be extensive. SNPs and indels highly associated with Al tolerance showed a narrow frequency range, between 0.06 and 0.1, suggesting a rather recent origin of Al tolerance mutations within AltSB. A haplotype network analysis suggested a single geographic and racial origin of causative mutations in primordial guinea domesticates in West Africa. Al tolerance assessment in accessions harboring recombinant haplotypes suggests that causative polymorphisms are localized to a ∼6 kb region including intronic polymorphisms and a transposon (MITE) insertion, whose size variation has been shown to be positively correlated with Al tolerance. The SNP with the strongest association signal, located in the second SbMATE intron, recovers 9 of the 14 highly Al tolerant accessions and 80% of all the Al tolerant and intermediately tolerant accessions in the association panel. Our results also demonstrate the pivotal importance of knowledge on the origin and evolution of Al tolerance mutations in molecular breeding applications. Allele mining strategies based on associated loci are expected to lead to the efficient identification, in diverse sorghum germplasm, of Al tolerant accessions able maintain grain yields under Al toxicity. [ABSTRACT FROM AUTHOR]

Published
2014
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13. Comparative mapping of Andropogoneae: Saccharum L. (sugarcane) and its relation to sorghum and...

Author

Guimaraes, Claudia T., Sills, Gavin R., and Sobral, Bruno W.S.

Subjects
*SUGARCANE, *SORGHUM, *CORN
Abstract

Compares the single-dose DNA marker (SDM) framework maps of Saccharum officinarum and Saccharum robustum (sugarcane) with genetic maps of sorghum and maize, by way of anchor restriction fragment length polymorphism probes. Colinearity between the sorghum and Saccharum genomes; Uses of sugarcane worldwide; Details on the study.

Published
1997
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14. Association Mapping Provides Insights into the Origin and the Fine Structure of the Sorghum Aluminum Tolerance Locus, AltSB.

Author

Caniato, Fernanda F., Hamblin, Martha T., Guimaraes, Claudia T., Zhang, Zhiwu, Schaffert, Robert E., Kochian, Leon V., and Magalhaes, Jurandir V.

Subjects
*LOCUS (Genetics), *SORGHUM, *GENE mapping, *TOXICOLOGY of aluminum, *PLANT roots, *ACID soils, *FOOD security
Abstract

Root damage caused by aluminum (Al) toxicity is a major cause of grain yield reduction on acid soils, which are prevalent in tropical and subtropical regions of the world where food security is most tenuous. In sorghum, Al tolerance is conferred by SbMATE, an Al-activated root citrate efflux transporter that underlies the major Al tolerance locus, AltSB, on sorghum chromosome 3. We used association mapping to gain insights into the origin and evolution of Al tolerance in sorghum and to detect functional variants amenable to allele mining applications. Linkage disequilibrium across the AltSB locus decreased much faster than in previous reports in sorghum, and reached basal levels at approximately 1000 bp. Accordingly, intra-locus recombination events were found to be extensive. SNPs and indels highly associated with Al tolerance showed a narrow frequency range, between 0.06 and 0.1, suggesting a rather recent origin of Al tolerance mutations within AltSB. A haplotype network analysis suggested a single geographic and racial origin of causative mutations in primordial guinea domesticates in West Africa. Al tolerance assessment in accessions harboring recombinant haplotypes suggests that causative polymorphisms are localized to a ∼6 kb region including intronic polymorphisms and a transposon (MITE) insertion, whose size variation has been shown to be positively correlated with Al tolerance. The SNP with the strongest association signal, located in the second SbMATE intron, recovers 9 of the 14 highly Al tolerant accessions and 80% of all the Al tolerant and intermediately tolerant accessions in the association panel. Our results also demonstrate the pivotal importance of knowledge on the origin and evolution of Al tolerance mutations in molecular breeding applications. Allele mining strategies based on associated loci are expected to lead to the efficient identification, in diverse sorghum germplasm, of Al tolerant accessions able maintain grain yields under Al toxicity. [ABSTRACT FROM AUTHOR]

Published
2014
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