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1. Rapid mini‐chromosome divergence among fungal isolates causing wheat blast outbreaks in Bangladesh and Zambia

   https://doi.org/10.1111/nph.19402  

   Liu, Sanzhen; Lin, Guifang; Ramachandran, Sowmya R.; Daza, Lidia Calderon; Cruppe, Giovana; Tembo, Batiseba; Singh, Pawan Kumar; Cook, David; Pedley, Kerry F.; Valent, Barbara (November 2023, New Phytologist)

   Summary The fungal pathogen,Magnaporthe oryzae Triticumpathotype, causing wheat blast disease was first identified in South America and recently spread across continents to South Asia and Africa. Here, we studied the genetic relationship among isolates found on the three continents.Magnaporthe oryzaestrains closely related to a South American field isolate B71 were found to have caused the wheat blast outbreaks in South Asia and Africa. Genomic variation among isolates from the three continents was examined using an improved B71 reference genome and whole‐genome sequences.We found strong evidence to support that the outbreaks in Bangladesh and Zambia were caused by the introductions of genetically separated isolates, although they were all close to B71 and, therefore, collectively referred to as the B71 branch. In addition, B71 branch strains carried at least one supernumerary mini‐chromosome. Genome assembly of a Zambian strain revealed that its mini‐chromosome was similar to the B71 mini‐chromosome but with a high level of structural variation.Our findings show that while core genomes of the multiple introductions are highly similar, the mini‐chromosomes have undergone marked diversification. The maintenance of the mini‐chromosome and rapid genomic changes suggest the mini‐chromosomes may serve important virulence or niche adaptation roles under diverse environmental conditions. 

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2. Homoeologous Recombination: A Novel and Efficient System for Broadening the Genetic Variability in Wheat

   https://doi.org/10.3390/agronomy10081059  

   Koo, Dal-Hoe; Friebe, Bernd; Gill, Bikram S. (August 2020, Agronomy)

   null (Ed.)

   Gene transfer from wild wheat relatives to bread wheat is restricted to homologous recombination. The presence of the Pairing homoeologous 1 (Ph1) gene in the long arm of wheat chromosome 5B allows only homologous chromosomes to pair and recombine, resulting in diploid inheritance of polyploid wheat. Previously, we identified a potent homoeologous pairing promotor gene(s) (Hpp-5Mg); its carrier chromosome 5Mg derived from Aegilops geniculata and its wheat homoeologous chromosome 5D freely recombined in the presence of the Ph1 gene. In this study, we investigated the effect of Hpp-5Mg on homoeologous recombination in the absence of Ph1. In Hpp-5Mg/ph1bph1b plants, we observed a vast genome-wide increase in homoeologous recombination and multiple crossovers (CO), including CO breakpoints in proximal regions of the chromosomes where recombination is known to be suppressed. We tested the efficacy of Hpp-5Mg/ph1bph1b-induced homoeologous recombination by producing new recombinants for the wheat streak mosaic virus resistance gene, Wsm3, present in the wheat-Thinopyrum intermedium Robertsonian translocation (RobT T7BS.7S#3L). A recombination frequency of 6.5% was detected by screening the progenies double monosomic for T7BS.7S#3L and 7B by genomic in situ hybridization. This recombination frequency was about 100-fold higher compared with the recombinant frequency of 0.06% observed by using ph1b-induced homoeologous recombination alone. Our results indicate that chromosome 5Mg promotes homoeologous recombination between wheat and wild wheat relative chromosomes, which helps in the generation of pre-breeding materials thereby accelerating wheat crop improvement. 

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3. Vegetative phase change causes age‐dependent changes in phenotypic plasticity

   https://doi.org/10.1111/nph.19174  

   Lawrence‐Paul, Erica H.; Poethig, R. Scott; Lasky, Jesse R. (August 2023, New Phytologist)

   Summary Phenotypic plasticity allows organisms to optimize traits for their environment. As organisms age, they experience diverse environments that benefit from varying degrees of phenotypic plasticity. Developmental transitions can control these age‐dependent changes in plasticity, and as such, the timing of these transitions can determine when plasticity changes in an organism.Here, we investigate how the transition from juvenile‐to adult‐vegetative development known as vegetative phase change (VPC) contributes to age‐dependent changes in phenotypic plasticity and how the timing of this transition responds to environment using both natural accessions and mutant lines in the model plantArabidopsis thaliana.We found that the adult phase of vegetative development has greater plasticity in leaf morphology than the juvenile phase and confirmed that this difference in plasticity is caused by VPC using mutant lines. Furthermore, we found that the timing of VPC, and therefore the time when increased plasticity is acquired, varies significantly across genotypes and environments.The consistent age‐dependent changes in plasticity caused by VPC suggest that VPC may be adaptive. This genetic and environmental variation in the timing of VPC indicates the potential for population‐level adaptive evolution of VPC. 

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4. LTP2 hypomorphs show genotype‐by‐environment interaction in early seedling traits in Arabidopsis thaliana

   https://doi.org/10.1111/nph.19334  

   Alexandre, Cristina_M; Bubb, Kerry_L; Schultz, Karla_M; Lempe, Janne; Cuperus, Josh_T; Queitsch, Christine (October 2023, New Phytologist)

   Summary Isogenic individuals can display seemingly stochastic phenotypic differences, limiting the accuracy of genotype‐to‐phenotype predictions. The extent of this phenotypic variation depends in part on genetic background, raising questions about the genes involved in controlling stochastic phenotypic variation.Focusing on early seedling traits inArabidopsis thaliana, we found that hypomorphs of the cuticle‐related geneLIPID TRANSFER PROTEIN 2(LTP2) greatly increased variation in seedling phenotypes, including hypocotyl length, gravitropism and cuticle permeability. Manyltp2hypocotyls were significantly shorter than wild‐type hypocotyls while others resembled the wild‐type.Differences in epidermal properties and gene expression betweenltp2seedlings with long and short hypocotyls suggest a loss of cuticle integrity as the primary determinant of the observed phenotypic variation. We identified environmental conditions that reveal or mask the increased variation inltp2hypomorphs and found that increased expression of its closest paralogLTP1is necessary forltp2phenotypes.Our results illustrate how decreased expression of a single gene can generate starkly increased phenotypic variation in isogenic individuals in response to an environmental challenge. 

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5. Plant carbohydrate storage: intra‐ and inter‐specific trade‐offs reveal a major life history trait

   https://doi.org/10.1111/nph.18213  

   Blumstein, Meghan; Sala, Anna; Weston, David_J; Holbrook, Noel_Michelle; Hopkins, Robin (May 2022, New Phytologist)

   Summary Trade‐offs among carbon sinks constrain how trees physiologically, ecologically, and evolutionarily respond to their environments. These trade‐offs typically fall along a productive growth to conservative, bet‐hedging continuum. How nonstructural carbohydrates (NSCs) stored in living tree cells (known as carbon stores) fit in this trade‐off framework is not well understood.We examined relationships between growth and storage using both within species genetic variation from a common garden, and across species phenotypic variation from a global database.We demonstrate that storage is actively accumulated, as part of a conservative, bet‐hedging life history strategy. Storage accumulates at the expense of growth both within and across species. Within the speciesPopulus trichocarpa, genetic trade‐offs show that for each additional unit of wood area growth (in cm² yr⁻¹) that genotypes invest in, they lose 1.2 to 1.7 units (mg g⁻¹NSC) of storage. Across species, for each additional unit of area growth (in cm² yr⁻¹), trees, on average, reduce their storage by 9.5% in stems and 10.4% in roots.Our findings impact our understanding of basic plant biology, fit storage into a widely used growth‐survival trade‐off spectrum describing life history strategy, and challenges the assumptions of passive storage made in ecosystem models today. 

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