SUMMARYArabidopsis seed size is regulated by the IKU pathway that includes IKU2 (a leucine-rich repeat kinase) and MINI3 (a WRKY transcription factor). We report the cloning of the IKU1 (At2g35230) gene. iku1 mutants cause reduced endosperm growth and the production of small seeds. IKU1 encodes a protein containing a VQ motif, which is a motif specific to plants. IKU1 is expressed in the early endosperm and its progenitor, the central cell. Restoration of IKU1 function in the endosperm is sufficient to rescue seed size. A genomic construct carrying mutations in the VQ motif failed to complement the iku1 mutation, suggesting an essential role for the VQ motif. IKU1 interacts with MINI3 in the yeast two-hybrid system, consistent with an IKU1 function in the IKU-MINI pathway. Our data support the proposition that endosperm development is an important determinant of seed size.
accelerated isolation of a new stem rust avirulence gene -wheat resistance gene pair. Nature Plants.
Breeding wheat with durable resistance to the fungal pathogen Puccinia graminis f. sp. tritici (Pgt), a major threat to cereal production, is challenging due to the rapid evolution of pathogen virulence. Increased durability and broad-spectrum resistance can be achieved by introducing more than one resistance gene, but combining numerous unlinked genes by breeding is laborious. Here we generate polygenic Pgt resistance by introducing a transgene cassette of five resistance genes into bread wheat as a single locus and show that at least four of the five genes are functional. These wheat lines are resistant to aggressive and highly virulent Pgt isolates from around the world and show very high levels of resistance in the field. The simple monogenic inheritance of this multigene locus greatly simplifies its use in breeding. However, a new Pgt isolate with virulence to several genes at this locus suggests gene stacks will need strategic deployment to maintain their effectiveness.Pgt continues to overcome resistant wheat cultivars, with three new, highly virulent isolates emerging in the last 20 years, and the disease reappearing in Europe and the UK 1 . Two classes of Pgt resistance genes have been cloned from wheat: all-stage resistance (ASR) genes and adult plant resistance (APR) genes 2 . ASR genes (for example, Sr22 (ref. 3 ), Sr35 (ref. 4 ), Sr45 (ref. 3 ) and Sr50 (ref. 5 )) generally encode nucleotide-binding, leucine-rich repeat (NLR) proteins that recognize a specific Pgt molecule (an effector) introduced into host plant cells by the fungus to promote parasitism, whereupon a plant defense response is activated 2 . The presence, absence or allelic variation of the fungal effector determines which Pgt isolates an ASR gene is effective against. ASR genes are extremely valuable for crop protection but, when deployed singly, often show transient resistance, as pathogen effectors rapidly evolve to avoid recognition. Combining ASR genes increases their durability, and theoretical estimates suggest that the chance of a single Pgt isolate gaining virulence for five or more ASR genes in wheat is infinitesimally small 6 .The second gene class, APR genes, can be remarkably durable and, in some cases, effective against multiple pathogen species. However, these genes generally provide partial resistance that is often insufficient for crop protection during severe pathogen epidemics.
Hybridization in plants leads to transinteractions between the parental genomes and epigenomes that can result in changes to both 24 nt siRNA and cytosine methylation ( m C) levels in the hybrid. In Arabidopsis the principle processes altering the hybrid methylome are Trans Chromosomal Methylation (TCM) and Trans Chromosomal deMethylation (TCdM) in which the m C pattern of a genomic segment attains the same m C pattern of the corresponding segment on the other parental chromosome. We examined two loci that undergo TCM/TCdM in the Arabidopsis C24/Landsberg erecta (Ler) F1 hybrids, which show patterns of inheritance dependent on the properties of the particular donor and recipient chromosomal segments. At At1g64790 the TCM-and TCdMderived m C patterns are maintained in the F2 generation but are transmitted in outcrosses or backcrosses only by the C24 genomic segment. At a region between and adjacent to At3g43340 and At3g43350, the originally unmethylated Ler genomic segment receives the C24 m C pattern in the F1, which is then maintained in backcross plants independent of the presence of the parental C24 segment. In backcrosses to an unmethylated Ler allele, the newly methylated F1 Ler segment may act as a TCM source in a process comparable to paramutation in maize. TCM-derived m C patterns are associated with reduced expression of both At3g43340 and At3g43350 in F1 and F2 plants, providing support for such events influencing the transcriptome. The inheritance of the F1 m C patterns and the segregation of other genetic and epigenetic determinants may contribute to the reduced hybrid vigor in the F2 and subsequent generations.heterosis | chromatin | histones | RdDM
Hybrid Arabidopsis plants undergo epigenetic reprogramming producing decreased levels of 24-nt siRNAs and altered patterns of DNA methylation that can affect gene expression. Driving the changes in methylation are the processes trans-chromosomal methylation (TCM) and trans-chromosomal demethylation (TCdM). In TCM/TCdM the methylation state of one allele is altered to resemble the other allele. We show that Pol IV-dependent sRNAs are required to establish TCM events. The changes in DNA methylation and the associated changes in sRNA levels in the F1 hybrid can be maintained in subsequent generations and affect hundreds of regions in the F2 epigenome. The inheritance of these altered epigenetic states varies in F2 individuals, resulting in individuals with genetically identical loci displaying different epigenetic states and gene expression profiles. The change in methylation at these regions is associated with the presence of sRNAs. Loci without any sRNA activity can have altered methylation states, suggesting that a sRNA-independent mechanism may also contribute to the altered methylation state of the F1 and F2 generations.H ybrid vigor, heterosis, is important in agriculture due to the increased performance of hybrid plants over parental lines. The increase in performance is attributable to changes in gene expression (1, 2) but how these changes result in the increased performance of the hybrid is still not known. The level of hybrid vigor is believed to correlate with the genetic distance between parental lines; however, hybrid vigor can occur in progeny derived from crosses of genetically similar parents. An example is found in intraspecific crosses between Arabidopsis thaliana accessions. In crosses between C24 and Landsberg erecta (Ler), up to a 100% increase in plant biomass and seed yield is observed (3). The different epigenomes of the two parental accessions could provide the diversity required to initiate gene expression changes and vigor-related characteristics. A number of laboratories have investigated whether there are epigenetic changes in Arabidopsis hybrids, whether they affect gene expression, and whether they contribute to the hybrid vigor phenotype (1, 3-6).We have previously established that F1 hybrids between Arabidopsis accessions undergo some epigenetic reprogramming. We found that the abundance of 24-nt siRNAs is reduced in F1 hybrids and that a second epigenetic system, DNA methylation ( m C), is also altered in the hybrid genome (1, 3, 5). The altered m C patterns in the hybrids involve the processes trans-chromosomal methylation (TCM) and trans-chromosomal demethylation (TCdM), where the m C state of one parental allele is altered to resemble the other allele (reviewed in ref. 7). Due to the presence of siRNAs at regions that undergo TCM/TCdM, we have suggested that siRNAs are the initiating molecules that establish these TCM/TCdM events (reviewed in ref. 8). In the hybrid nucleus, the complement of 24-nt siRNAs can interact with homologous sequences from either parent.The TCM and TCdM...
Hybrids are used extensively in agriculture due to their superior performance in seed yield and plant growth, yet the molecular mechanisms underpinning hybrid performance are not well understood. Recent evidence has suggested that a decrease in basal defense response gene expression regulated by reduced levels of salicylic acid (SA) may be important for vigor in certain hybrid combinations. Decreasing levels of SA in the Arabidopsis (Arabidopsis thaliana) accession C24 through the introduction of the SA catabolic enzyme salicylate1 hydroxylase (NahG) increases plant size, phenocopying the large-sized C24/Landsberg erecta (Ler) F1 hybrids. C24♀ 3 Ler♂ F1 hybrids and C24 NahG lines shared differentially expressed genes and pathways associated with plant defense and leaf senescence including decreased expression of SA biosynthetic genes and SA response genes. The expression of TL1 BINDING TRANSCRIPTION FACTOR1, a key regulator in resource allocation between growth and defense, was decreased in both the F1 hybrid and the C24 NahG lines, which may promote growth. Both C24 NahG lines and the F1 hybrids showed decreased expression of the key senescence-associated transcription factors WRKY53, NAC-CONTAINING PROTEIN29, and ORESARA1 with a delayed onset of senescence compared to C24 plants. The delay in senescence resulted in an extension of the photosynthetic period in the leaves of F1 hybrids compared to the parental lines, potentially allowing each leaf to contribute more resources toward growth.
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