Tripsacum dactyloides (Poaceae): a natural model system to study parthenogenesis

Bantin, Jörg; Matzk, Fritz; Dresselhaus, Thomas

doi:10.1007/s00497-001-0119-z

Cited by 10 publications

(3 citation statements)

References 47 publications

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“…Further differentiation into megagametophytes resembles that of the Polygonum type found in sexual species, but cells contain nuclei of maternal genetic makeup. Activation of unreduced egg cells through unknown developmental alterations in female gametogenesis induces embryogenesis in absence of fertilization (Bantin et al, 2001, Farquharson, 1955 but the developmental course of maternal embryos stops after a few rounds of mitotic divisions resulting in quiescent proembryos within unfertilized megagametophytes (Grimanelli et al, 2003). Pollination, followed by the delivery of two sperm cells into the mature megagametophyte and by the fertilization of the central cell only, is required for seed development.…”

Section: Introductionmentioning

confidence: 99%

Seed development and inheritance studies in apomictic maize-Tripsacum hybrids reveal barriers for the transfer of apomixis into sexual crops

Leblanc¹,

Grimanelli²,

Hernandez-Rodriguez³

et al. 2009

Int. J. Dev. Biol.

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Apomixis in plants covers a variety of cloning systems through seeds of great potential for plant breeding. Among long-standing approaches for crop improvement is the attempt to exploit wild relatives as natural, vast reservoirs for novel genetic variation. With regard to apomixis, maize possesses an apomictic wild relative, Tripsacum, which we used to produce advanced maize-Tripsacum hybrid generations. However, introgression of apomixis in maize has failed so far. In order to understand the how's and why's, we undertook characterization of seed development and inheritance studies in these materials. We show that apomictic seeds suffer from epigenetic loads. Both seed tissues, the endosperm and the embryo, displayed developmental defects resulting from imbalanced parental genomic contributions and aberrant methylation patterns, respectively. Progeny characterization of several maize-Tripsacum hybrid generations allowed significant progress toward the unraveling of the genetics of apomixis. First, chromosome deletion mapping showed that expression of apomixis requires one single Tripsacum chromosome. However, inheritance studies revealed that female gametes inheriting this segment were unequivalent carriers depending on their origin: unreduced gametes transmit a functional segment, whereas progeny derived from reduced ones reproduced sexually. Finally, chromosomal or genomic dosage variation barely affected the apomictic phenotype suggesting no dependency for ploidy in these materials. We conclude that epigenetic information imposes constraints for apomictic seed development and seems pivotal for transgenerational propagation of apomixis. The nature of the triggering mechanisms remains unknown as-yet, but it certainly explains the modest success relative to the development of apomictic maize thus far.

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Section: Introductionmentioning

confidence: 99%

Seed development and inheritance studies in apomictic maize-Tripsacum hybrids reveal barriers for the transfer of apomixis into sexual crops

Leblanc¹,

Grimanelli²,

Hernandez-Rodriguez³

et al. 2009

Int. J. Dev. Biol.

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“…However, the use of the modern methods of research (molecular techniques and gene engineering) in combination with the traditional approaches (hybridological, cytoembryological, and cytogenetic) did not provide answers to most questions related to this problem. For instance, the explanations of the genetic control of this phenomenon are still hypothetical, although some progress has been made in this direction [1][2][3][4][5]. The character and nature of genetic variability in apomictic populations [6,7] and the role of gametophytic apomixis in evolution remain largely unclear.…”

Section: Introductionmentioning

confidence: 99%

Studying allozyme variation in sexual and apomictic Taraxacum and Pilosella (Asteraceae) populations

2005

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Allozyme spectra of peroxidase, esterase, superoxid dismutase, tyrosinase, alcohol dehydrogenase, lactate dehydrogenase, and acid phosphatase were examined in populations of sexual ( Taraxacum serotinum and Pilosella echioides ) and apomictic ( T. officinale and P. officinarum ) plant species. The heterozygosity in these populations (0. 455-0.620) proved to be considerably higher than the average level characteristic of plant populations (0.058-0.185). The populations examined did not differ in the mean phenotype number µ , i.e., they exhibited the same diversity (3.188-3.380). The proportion of rare phenotypes h also did not differ between the sexual and apomictic species of the same genus, whereas this parameter in the Pilosella populations (0.150-0.174) was significantly higher than in the Taraxacum ones (0.093-0.114). The populations were characterized by numerous isozyme spectra (more than 11 per populations) and displayed multiple allelism (the mean allele frequency was 3.63-4.38 per locus). They exhibited a high percentage of rare (occurring at a frequency lower than 5%) spectra (35-80%). This indicates that agamic complexes, to which these populations belong, may have a more complicated genetic structure of both apomictic and sexual populations than the species that do not belong to agamic complexes.

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“…It represents an untapped genetic resource for crop improvement and contains many useful agronomic traits like disease and pest resistance and harsh-environment adaptation (Hoisington et al 1999;Chia et al 2012). It is also a natural model system to study parthenogenesis, an important trait for crop improvement (Hoisington et al 1999;Bantin et al 2001). Tripsacum can hybridize with maize and the hybrids can grow well (Harlan and de Wet 1977).…”

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confidence: 99%

Genomic Resources for Gene Discovery, Functional Genome Annotation, and Evolutionary Studies of Maize and Its Close Relatives

et al. 2013

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Maize is one of the most important food crops and a key model for genetics and developmental biology. A genetically anchored and high-quality draft genome sequence of maize inbred B73 has been obtained to serve as a reference sequence. To facilitate evolutionary studies in maize and its close relatives, much like the Oryza Map Alignment Project (OMAP) (www.OMAP.org) bacterial artificial chromosome (BAC) resource did for the rice community, we constructed BAC libraries for maize inbred lines Zheng58, Chang7-2, and Mo17 and maize wild relatives Zea mays ssp. parviglumis and Tripsacum dactyloides. Furthermore, to extend functional genomic studies to maize and sorghum, we also constructed binary BAC (BIBAC) libraries for the maize inbred B73 and the sorghum landrace Nengsi-1. The BAC/BIBAC vectors facilitate transfer of large intact DNA inserts from BAC clones to the BIBAC vector and functional complementation of large DNA fragments. These seven Zea Map Alignment Project (ZMAP) BAC/BIBAC libraries have average insert sizes ranging from 92 to 148 kb, organellar DNA from 0.17 to 2.3%, empty vector rates between 0.35 and 5.56%, and genome equivalents of 4.7-to 8.4-fold. The usefulness of the Parviglumis and Tripsacum BAC libraries was demonstrated by mapping clones to the reference genome. Novel genes and alleles present in these ZMAP libraries can now be used for functional complementation studies and positional or homology-based cloning of genes for translational genomics.M AIZE is one of the most important crops worldwide, already producing more tons of grain than any other plant species, and with continuing expansion of planted acreage in the developed and developing world. It is used as a staple food crop, but also for animal feed, biofuel, and various industrial by-products, such as starches, oil, sugars, sweeteners, beverages, and adhesives. It is also a key model species for research in genetics, epigenetics, genomics, development, physiology, and evolution (Bennetzen and Hake 2009;Schnable et al. 2009;Walbot 2009). Maize was domesticated 10,000 years ago from an annual wild teosinte, Zea mays ssp. parviglumis, that originated in the balsas river lowland in Mexico (Doebley et al. 2006;van Heerwaarden et al. 2011). One feature of contemporary maize is that it is probably the most genetically diverse of all crop species. Analyses of haplotypes; sequences around the bz, z1C1, and adh1 loci; and sequences of large genomic regions all showed striking structural diversity in maize inbred lines (Fu and Dooner 2002;Song et al. 2002;Song and Messing 2003;Jung et al. 2004;Brunner et al. 2005;Wang and Dooner 2006;Gore et al. 2009;Chia et al. 2012). It also has been shown that the two ancestral progenitors of maize and the progenitor of sorghum split 11.9 MYA and the progenitors of maize hybridized 4.8 MYA to form allotetraploid maize . Hybridization resulted in broken and fused chromosomes with the reduced set of today's 10 chromosomes (Wei et al. 2007 Divergence of the two homologous chromosomal regions contin...

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Tripsacum dactyloides (Poaceae): a natural model system to study parthenogenesis

Cited by 10 publications

References 47 publications

Seed development and inheritance studies in apomictic maize-Tripsacum hybrids reveal barriers for the transfer of apomixis into sexual crops

Seed development and inheritance studies in apomictic maize-Tripsacum hybrids reveal barriers for the transfer of apomixis into sexual crops

Studying allozyme variation in sexual and apomictic Taraxacum and Pilosella (Asteraceae) populations

Genomic Resources for Gene Discovery, Functional Genome Annotation, and Evolutionary Studies of Maize and Its Close Relatives

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