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1. The Streptochaeta genome and the evolution of the grasses

   https://doi.org/https://ddoi.org/10.1101/2021.06.08.444730  

   Seetharam, A ; Yunqing, Y ; Belange, r S ; Clark, LG ; Meyers, BC ; Kellogg, EA ; Hufford, MB. ( June 2021 , bioRxiv)

   null (Ed.)

   In this work, we sequenced and annotated the genome of Streptochaeta angustifolia, one of two genera in the grass subfamily Anomochlooideae, a lineage sister to all other grasses. The final assembly size is over 99% of the estimated genome size, capturing most of the gene space. Streptochaeta is similar to other grasses in the structure of its fruit (a caryopsis or grain) but has peculiar flowers and inflorescences that are distinct from those in the outgroups and in other grasses. To provide tools for investigations of floral structure, we analyzed two large families of transcription factors, AP2-like and R2R3 MYBs, that are known to control floral and spikelet development in rice and maize among other grasses. Many of these are also regulated by small RNAs. Structure of the gene trees showed that the well documented whole genome duplication at the origin of the grasses (ρ) occurred before the divergence of the Anomochlooideae lineage from the lineage leading to the rest of the grasses (the spikelet clade) and thus that the common ancestor of all grasses probably had two copies of the developmental genes. However, Streptochaeta (and by inference other members of Anomochlooideae) has lost one copy of many genes. The peculiar floral morphology of Streptochaeta may thus have derived from an ancestral plant that was morphologically similar to the spikelet-bearing grasses. We further identify 114 loci producing microRNAs and 89 loci generating phased, secondary siRNAs, classes of small RNAs known to be influential in transcriptional and post-transcriptional regulation of several plant functions. 

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2. Divergent gene expression networks underlie morphological diversity of abscission zones in grasses

   https://doi.org/10.1111/nph.16087  

   Yu, Yunqing ; Hu, Hao ; Doust, Andrew N. ; Kellogg, Elizabeth A. ( August 2019 , New Phytologist)

   Abscission is a process in which plants shed their parts, and is mediated by a particular set of cells, the abscission zone (AZ). In grasses (Poaceae), the position of the AZ differs among species, raising the question of whether its anatomical structure and genetic control are conserved.

   The ancestral position of the AZ was reconstructed. A combination of light microscopy, transmission electron microscopy, RNA‐Seq analyses and RNAin situhybridisation were used to compare three species, two (weedy rice andBrachypodium distachyon) with the AZ in the ancestral position and one (Setaria viridis) with the AZ in a derived position below a cluster of flowers (spikelet).

   Rice andBrachypodiumare more similar anatomically thanSetaria. However, the cell wall properties and the transcriptome of rice andBrachypodiumare no more similar to each other than either is toSetaria. The set of genes expressed in the studied tissues is generally conserved across species, but the precise developmental and positional patterns of expression and gene networks are almost entirely different.

   Transcriptional regulation of AZ development appears to be extensively rewired among the three species, leading to distinct anatomical and morphological outcomes.

    

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3. Differential alternative polyadenylation contributes to the developmental divergence between two rice subspecies, japonica and indica

   https://doi.org/10.1111/tpj.14209  

   Zhou, Qian ; Fu, Haihui ; Yang, Dewei ; Ye, Congting ; Zhu, Sheng ; Lin, Juncheng ; Ye, Wenbin ; Ji, Guoli ; Ye, Xinfu ; Wu, Xiaohui ; et al ( February 2019 , The Plant Journal)

   Alternative polyadenylation (APA) is a widespread post‐transcriptional mechanism that regulates gene expression throughmRNAmetabolism, playing a pivotal role in modulating phenotypic traits in rice (Oryza sativaL.). However, little is known about theAPA‐mediated regulation underlying the distinct characteristics between two major rice subspecies,indicaandjaponica. Using a poly(A)‐tag sequencing approach, polyadenylation (poly(A)) site profiles were investigated and compared pairwise from germination to the mature stage betweenindicaandjaponica, and extensive differentiation inAPAprofiles was detected genome‐wide. Genes with subspecies‐specific poly(A) sites were found to contribute to subspecies characteristics, particularly in disease resistance ofindicaand cold‐stress tolerance ofjaponica. In most tissues, differential usage ofAPAsites exhibited an apparent impact on the gene expression profiles between subspecies, and genes with those APA sites were significantly enriched in quantitative trait loci (QTL) related to yield traits, such as spikelet number and 1000‐seed weight. In leaves of the booting stage,APAsite‐switching genes displayed global shortening of 3′ untranslated regions with increased expression inindicacompared withjaponica, and they were overrepresented in the porphyrin and chlorophyll metabolism pathways. This phenomenon may lead to a higher chlorophyll content and photosynthesis inindicathan injaponica, being associated with their differential growth rates and yield potentials. We further constructed an online resource for querying and visualizing the poly(A) atlas in these two rice subspecies. Our results suggest thatAPAmay be largely involved in developmental differentiations between two rice subspecies, especially in leaf characteristics and the stress response, broadening our knowledge of the post‐transcriptional genetic basis underlying the divergence of rice traits.

    

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4. MicroRNAs meet with quantitative trait loci: Small powerful players in regulating quantitative yield traits in rice

   https://doi.org/10.1002/wrna.1556  

   Peng, Ting ; Teotia, Sachin ; Tang, Guiliang ; Zhao, Quanzhi ( June 2019 , WIREs RNA)

   MicroRNAs (miRNAs) are small noncoding RNAs which regulate various functions related to growth, development, and stress responses in plants and animals. Rice,Oryza sativa, is one of the most important food crops of the world. In rice, a number of quantitative trait loci (QTL) controlling yield‐related traits have been identified. Some of them are actually controlled by miRNAs, which control various yield‐related quantitative traits in rice. On one hand, many of these miRNAs are found to regulate more than one yield‐related traits, such as tillering, grain size, and branch number of a panicle. On the other hand, a rice yield‐related trait is usually controlled by multiple miRNAs, for example, grain size being controlled by miR156, miR167, miR396, miR397, and miR1432. In rare case, a single miRNA may specifically regulate only one yield‐related trait, such as, miR444 regulating rice tillering. In this review, we focus on the functions of miRNAs in controlling yield‐related quantitative traits in rice, including panicle grain number, grain weight/size, panicle length and branching, tiller number per plant, spikelet number, seed setting rate, and leaf inclination, and discuss how to modulate the expression of these miRNAs using modern molecular biology tools to promote grain yield.

   This article is categorized under:

   RNA in Disease and Development > RNA in Development

    

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5. Tissue-specific transcriptomics reveal functional differences in floral development

   https://doi.org/10.1093/plphys/kiab557  

   Yang, Hailong ; Nukunya, Kate ; Ding, Queying ; Thompson, Beth E. ( December 2021 , Plant Physiology)

   Flowers are produced by floral meristems, groups of stem cells that give rise to floral organs. In grasses, including the major cereal crops, flowers (florets) are contained in spikelets, which contain one to many florets, depending on the species. Importantly, not all grass florets are developmentally equivalent, and one or more florets are often sterile or abort in each spikelet. Members of the Andropogoneae tribe, including maize (Zea mays), produce spikelets with two florets; the upper and lower florets are usually dimorphic, and the lower floret is greatly reduced compared to the upper floret. In maize ears, early development appears identical in both florets but the lower floret ultimately aborts. To gain insight into the functional differences between florets with different fates, we used laser capture microdissection coupled with RNA-sequencing to globally examine gene expression in upper and lower floral meristems in maize. Differentially expressed genes were involved in hormone regulation, cell wall, sugar, and energy homeostasis. Furthermore, cell wall modifications and sugar accumulation differed between the upper and lower florets. Finally, we identified a boundary domain between upper and lower florets, which we hypothesize is important for floral meristem activity. We propose a model in which growth is suppressed in the lower floret by limiting sugar availability and upregulating genes involved in growth repression. This growth repression module may also regulate floret fertility in other grasses and potentially be modulated to engineer more productive cereal crops.

    

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