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48,590 results on '"PLANT evolution"'

151. Historical Landscape Studies.

Author

Moisés Santana-Cordero, Aarón and García-Lozano, Carla

Subjects
*PLANT evolution, *TRANSHUMANCE, *LANDSCAPES, *LAND use, *SAND dunes
Abstract

The article "Historical Studies of the Landscape" presents different approaches and methods for studying the relationship between landscape and history. It highlights the importance of understanding past and current landscapes, as well as the interaction between the environment and the societies that inhabit them. The article also mentions several specific studies that focus on different regions, such as Central America, Central Europe, and Spain. These studies analyze the evolution of plant landscapes, changes in land use, coastal dune fixation, and the impact of transhumance on the landscapes of Gran Canaria. Overall, the article emphasizes the importance of adopting an integrated and multidisciplinary approach to understanding historical landscapes. [Extracted from the article]

Published
2024
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152. Back to the future: Using herbarium specimens to isolate nodule‐associated bacteria.

Author

Petipas, Renee H., Antoch, Amanda A., Eaker, Ashton A., Kehlet‐Delgado, Hanna, and Friesen, Maren L.

Subjects
*BOTANICAL specimens, *PLANT evolution, *PLANT ecology, *HERBARIA, *MEDICAGO
Abstract

Herbarium specimens are increasingly being used as sources of information to understand the ecology and evolution of plants and their associated microbes. Most studies have used specimens as a source of genetic material using culture‐independent approaches. We demonstrate that herbarium specimens can also be used to culture nodule‐associated bacteria, opening the possibility of using specimens to understand plant–microbe interactions at new spatiotemporal scales. We used historic and contemporary nodules of a common legume, Medicago lupulina, to create a culture collection. We were able to recover historic bacteria in 15 genera from three specimens (collected in 1950, 2004, and 2015). This work is the first of its kind to isolate historic bacteria from herbarium specimens. Future work should include inoculating plants with historic strains to see if they produce nodules and if they affect plant phenotype and fitness. Although we were unable to recover any Ensifer, the main symbiont of Medicago lupulina, we recovered some other potential nodulating species, as well as many putative growth‐promoting bacteria. [ABSTRACT FROM AUTHOR]

Published
2024
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153. Extreme functional specialization of fertile leaves in a widespread fern species and its implications on the evolution of reproductive dimorphism.

Author

Suissa, Jacob S., Barkoff, Noah, and Watkins, James E.

Subjects
*RESOURCE allocation, *PLANT evolution, *PHANEROGAMS, *EVOLUTIONARY economics, *CAVITATION, *FERNS
Abstract

Resource allocation theory posits that organisms distribute limited resources across functions to maximize their overall fitness. In plants, the allocation of resources among maintenance, reproduction, and growth influences short‐term economics and long‐term evolutionary processes, especially during resource scarcity. The evolution of specialized structures to divide labor between reproduction and growth can create a feedback loop where selection can act on individual organs, further increasing specializaton and resource allocation. Ferns exhibit diverse reproductive strategies, including dimorphism, where leaves can either be sterile (only for photosynthesis) or fertile (for spore dispersal). This dimorphism is similar to processes in seed plants (e.g., the production of fertile flowers and sterile leaves), and presents an opportunity to investigate divergent resource allocation between reproductive and vegetative functions in specialized organs. Here, we conducted anatomical and hydraulic analyses on Onoclea sensibilis L., a widespread dimorphic fern species, to reveal significant structural and hydraulic divergences between fertile and sterile leaves. Fertile fronds invest less in hydraulic architecture, with nearly 1.5 times fewer water‐conducting cells and a nearly 0.5 times less drought‐resistant xylem compared to sterile fronds. This comes at the increased relative investment in structural support, which may help facilitate spore dispersal. These findings suggest that specialization in ferns—in the form of reproductive dimorphism—can enable independent selection pressures on each leaf type, potentially optimizing spore dispersal in fertile fronds and photosynthetic efficiency in sterile fronds. Overall, our study sheds light on the evolutionary implications of functional specialization and highlights the importance of reproductive strategies in shaping plant fitness and evolution. [ABSTRACT FROM AUTHOR]

Published
2024
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154. Population sequencing enhances understanding of tea plant evolution

Author

Xinchao Wang, Hu Feng, Yuxiao Chang, Chunlei Ma, Liyuan Wang, Xinyuan Hao, A’lun Li, Hao Cheng, Lu Wang, Peng Cui, Jiqiang Jin, Xiaobo Wang, Kang Wei, Cheng Ai, Sheng Zhao, Zhichao Wu, Youyong Li, Benying Liu, Guo-Dong Wang, Liang Chen, Jue Ruan, and Yajun Yang

Subjects
Science
Abstract

Tea is an important beverage crop with a large and heterozygous genome. Here, the authors assemble the genome of the cultivar Longjing 43 and conduct a population genetics study to reveal divergent selection for disease resistance and flavor between the two variety groups.

Published
2020
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156. Assembly and comparative analysis of the first complete mitochondrial genome of zicaitai (Brassica rapa var. Purpuraria): insights into its genetic architecture and evolutionary relationships.

Author

Wanyu Xiao, Xian Wu, Xianyu Zhou, Jing Zhang, Jianghua Huang, Xiuchun Dai, Hailong Ren, and Donglin Xu

Subjects
MITOCHONDRIAL DNA, CHLOROPLAST DNA, BASE pairs, RNA editing, PLANT evolution
Abstract

Introduction: Zicaitai (Brassica rapa var. purpuraria) is a Brassica variety renowned for its distinctive taste and rich nutritional profile. In recent years, the mitochondrial genomes of several Brassica species have been documented, but the mitogenome of Zicaitai remains unreported. Methods: In this study, we characterized the Zicaitai mitogenome achieved through the assembly of sequencing reads derived from both the Oxford Nanopore and Illumina platforms. A detailed comparative analysis was carried out with other Brassica species to draw comparisons and contrasts. In-depth analyses of codon usage patterns, instances of RNA editing, and the prevalence of sequence repeats within the mitogenome were also conducted to gain a more nuanced understanding of its genetic architecture. A phylogenetic analysis was performed, utilizing the coding sequences (CDS) from the mitochondrial genome of Zicaitai and that of 20 closely related species/varieties to trace evolutionary connections. Results: The Zicaitai mitogenome is characterized by a circular structure spanning 219,779 base pairs, and it encompasses a total of 59 genes. This gene set includes 33 protein-coding genes, 23 tRNA genes, and 3 rRNA genes, providing a rich foundation for further genomic study. An analysis of the Ka/Ks ratios for 30 protein-coding genes shared by the mitogenomes of Zicaitai and seven other Brassica species revealed that most of these genes had undergone purifying selection. Additionally, the study explored the migration of genes between the chloroplast and nuclear genomes and the mitogenome, offering insights into the dynamics of genetic exchange within the Brassica genus. Discussion: The collective results in this study will serve as a foundational resource, aiding future evolutionary studies focused on B. rapa, and contributing to a broader understanding of the complexities of plant evolution. [ABSTRACT FROM AUTHOR]

Published
2024
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157. Gene Expression Divergence in Eugenia uniflora Highlights Adaptation across Contrasting Atlantic Forest Ecosystems.

Author

Turchetto-Zolet, Andreia C., Salgueiro, Fabiano, Guzman, Frank, Vetö, Nicole M., Rodrigues, Nureyev F., Balbinott, Natalia, Margis-Pinheiro, Marcia, and Margis, Rogerio

Subjects
GENE expression, GENETIC regulation, RIPARIAN forests, CLIMATE change, PLANT evolution
Abstract

Understanding the evolution and the effect of plasticity in plant responses to environmental changes is crucial to combat global climate change. It is particularly interesting in species that survive in distinct environments, such as Eugenia uniflora, which thrives in contrasting ecosystems within the Atlantic Forest (AF). In this study, we combined transcriptome analyses of plants growing in nature (Restinga and Riparian Forest) with greenhouse experiments to unveil the DEGs within and among adaptively divergent populations of E. uniflora. We compared global gene expression among plants from two distinct ecological niches. We found many differentially expressed genes between the two populations in natural and greenhouse-cultivated environments. The changes in how genes are expressed may be related to the species' ability to adapt to specific environmental conditions. The main difference in gene expression was observed when plants from Restinga were compared with their offspring cultivated in greenhouses, suggesting that there are distinct selection pressures underlying the local environmental and ecological factors of each Restinga and Riparian Forest ecosystem. Many of these genes engage in the stress response, such as water and nutrient transport, temperature, light intensity, and gene regulation. The stress-responsive genes we found are potential genes for selection in these populations. These findings revealed the adaptive potential of E. uniflora and contributed to our understanding of the role of gene expression reprogramming in plant evolution and niche adaptation. [ABSTRACT FROM AUTHOR]

Published
2024
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158. Development History, Structure, and Function of ASR (Abscisic Acid-Stress-Ripening) Transcription Factor.

Author

Zhang, Yue, Wang, Mengfan, Kitashov, Andery V., and Yang, Ling

Subjects
TRANSCRIPTION factors, CULTIVARS, PLANT genes, GENE families, PLANT evolution, TOMATOES
Abstract

Abiotic and biotic stress factors seriously affect plant growth and development. The process of plant response to abiotic stress involves the synergistic action of multiple resistance genes. The ASR (Abscisic acid stress-ripening) gene is a plant-specific transcription factor that plays a central role in regulating plant senescence, fruit ripening, and response to abiotic stress. ASR family members are highly conserved in plant evolution and contain ABA/WBS domains. ASR was first identified and characterized in tomatoes (Solanum lycopersicum L.). Subsequently, the ASR gene has been reported in many plant species, extending from gymnosperms to monocots and dicots, but lacks orthologues in Arabidopsis (Arabidopsis thaliana). The promoter regions of ASR genes in most species contain light-responsive elements, phytohormone-responsive elements, and abiotic stress-responsive elements. In addition, ASR genes can respond to biotic stresses via regulating the expression of defense genes in various plants. This review comprehensively summarizes the evolutionary history, gene and protein structures, and functions of the ASR gene family members in plant responses to salt stress, low temperature stress, pathogen stress, drought stress, and metal ions, which will provide valuable references for breeding high-yielding and stress-resistant plant varieties. [ABSTRACT FROM AUTHOR]

Published
2024
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159. Translational Regulation of Duplicated Gene Expression Evolution in Allopolyploid Cotton.

Author

Fu, Guiling, Luo, Haotian, Jia, Juqing, Hou, Mingming, and Hu, Guanjing

Subjects
GENE expression, GENETIC regulation, GENETIC transcription regulation, PLANT evolution, PHENOTYPES, GENETIC translation
Abstract

Polyploidy, a prevalent event in plant evolution, drives phenotypic diversification and speciation. While transcriptional changes and regulation in polyploids have been extensively studied, the translational level impact remains largely unexplored. To address this gap, we conducted a comparative transcriptomic and translatomic analysis of cotton leaves from allopolyploid species G. hirsutum (AD1) and G. barbadense (AD2) relative to their model A-genome and D-genome diploid progenitors. Our data revealed that while allopolyploidization significantly affects the transcriptional landscape, its impact on translation was relatively modest, evidenced by a narrower expression range and fewer expression changes in ribosome-protected fragments than in mRNA levels. Allopolyploid-specific changes commonly identified in both AD1 and AD2 were observed in 7393 genes at either transcriptional or translational levels. Interestingly, the majority of translational changes exhibited concordant down-regulation in both ribosome-protected fragments and mRNA, particularly associated with terpenoid synthesis and metabolism (352 genes). Regarding translational efficiency (TE), at least one-fifth of cotton genes exhibit translational level regulation, with a general trend of more down-regulation (13.9–15.1%) than up-regulation (7.3–11.2%) of TE. The magnitude of translational regulation was slightly reduced in allopolyploids compared with diploids, and allopolyploidy tends to have a more profound impact on genes and functional associations with ultra-low TE. Moreover, we demonstrated a reduced extent of homeolog expression biases during translation compared with transcription. Our study provides insights into the regulatory consequences of allopolyploidy post-transcription, contributing to a comprehensive understanding of regulatory mechanisms of duplicated gene expression evolution. [ABSTRACT FROM AUTHOR]

Published
2024
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162. Does variable epigenetic inheritance fuel plant evolution?

Author

Minow, Mark A.A. and Colasanti, Joseph

Subjects
Nucleotide sequencing, Gene expression, Genomics, Fuel industry, Genes, DNA sequencing, RNA, Epigenetic inheritance, Plant physiology, Plants -- Evolution, Biological sciences
Abstract

Epigenetic changes influence gene expression and contribute to the modulation of biological processes in response to the environment. Transgenerational epigenetic changes in gene expression have been described in many eukaryotes. However, plants appear to have a stronger propensity for inheriting novel epialleles. This mini-review discusses how plant traits, such as meristematic growth, totipotency, and incomplete epigenetic erasure in gametes promote epiallele inheritance. Additionally, we highlight how plant biology may be inherently tailored to reap the benefits of epigenetic metastability. Importantly, environmentally triggered small RNA expression and subsequent epigenetic changes may allow immobile plants to adapt themselves, and possibly their progeny, to thrive in local environments. The change of epigenetic states through the passage of generations has ramifications for evolution in the natural and agricultural world. In populations containing little genetic diversity, such as elite crop germplasm or habitually self-reproducing species, epigenetics may provide an important source of heritable phenotypic variation. Basic understanding of the processes that direct epigenetic shifts in the genome may allow for breeding or bioengineering for improved plant traits that do not require changes to DNA sequence. Key words: small RNA, meristems, plant development, epigenetics, evolution. Les modifications epigenetiques influencent l'expression genique et contribuent a moduler les processus biologiques en reponse a l'environnement. Des changements epigenetiques trans-generationnels de l'expression genique ont ete decrits chez plusieurs eucaryotes. Cependant, les plantes semblent avoir une propension plus grande pour la transmission d'epialleles inedits. Dans cette mini-synthese, les auteurs discutent comment certaines proprietes des plantes, telles que la croissance des meristemes, la totipotence et l'effacement epigenetique incomplete chez les gametes, contribuent la transmission des epialleles. De plus, les auteurs soulignent de quelle maniere la biologie des plantes est adaptee pour recolter les benefices d'une meta-stabilite epigenetique. De maniere importante, l'expression induite par l'environnement de petits ARN et les changements epigenetiques subsequents peuvent permettre aux plantes, par ailleurs immobiles, de s'adapter elles-memes, ainsi que possiblement leur progeniture, pour prosperer dans des environnements locaux. Le changement d'etats epigenetiques au cours des generations a des consequences en matiere d'evolution tant dans le contexte naturel qu'agricole. Chez des populations contenant peu de diversite genetique, telles que les varietes elites ou des especes a reproduction autogame, l'epigenetique procure possiblement une source importante de variation phenotypique heritable. Une comprehension des processus qui menent a des changements epigenetiques dans le genome pourrait permettre une selection ou une ingenierie de caracteres ameliores qui ne necessitent aucun changement a la sequence d'ADN. [Traduit par la Redaction] Mots-cles : petits ARN, meristemes, developpement de la plante, epigenetique, evolution., Introduction Plants differ from animals in several fundamental ways. In addition to being typically autotrophic and immobile, plants react to their environment through developmental plasticity. Plant cells are totipotent and, [...]

Published
2020
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164. Eukaryotic Components Remodeled Chloroplast Nucleoid Organization during the Green Plant Evolution.

Author

山岡, 尚平, 河内, 孝之, 鹿内, 利治, 西村, 芳樹, 00378770, 40202056, 70444099, Kobayashi, Yusuke, Takusagawa, Mari, Harada, Naomi, Fukao, Yoichiro, Yamaoka, Shohei, Kohchi, Takayuki, Hori, Koichi, Ohta, Hiroyuki, Shikanai, Toshiharu, Nishimura, Yoshiki, 山岡, 尚平, 河内, 孝之, 鹿内, 利治, 西村, 芳樹, 00378770, 40202056, 70444099, Kobayashi, Yusuke, Takusagawa, Mari, Harada, Naomi, Fukao, Yoichiro, Yamaoka, Shohei, Kohchi, Takayuki, Hori, Koichi, Ohta, Hiroyuki, Shikanai, Toshiharu, and Nishimura, Yoshiki

Abstract

Chloroplast (cp) DNA is thought to originate from the ancestral endosymbiont genome and is compacted to form nucleoprotein complexes, cp nucleoids. The structure of cp nucleoids is ubiquitously observed in diverse plants from unicellular algae to flowering plants and is believed to be a multifunctional platform for various processes, including cpDNA replication, repair/recombination, transcription, and inheritance. Despite its fundamental functions, the protein composition for cp nucleoids in flowering plants was suggested to be divergent from those of bacteria and algae, but the evolutionary process remains elusive. In this research, we aimed to reveal the evolutionary history of cp nucleoid organization by analyzing the key organisms representing the three evolutionary stages of eukaryotic phototrophs: the chlorophyte alga Chlamydomonas reinhardtii , the charophyte alga Klebsormidium flaccidum , and the most basal land plant Marchantia polymorpha . To clarify the core cp nucleoid proteins in C. reinhardtii , we performed an LC-MS/MS analysis using highly purified cp nucleoid fractions and identified a novel SAP domain-containing protein with a eukaryotic origin as a constitutive core component. Then, homologous genes for cp nucleoid proteins were searched for in C. reinhardtii , K. flaccidum , and M. polymorpha using the genome databases, and their intracellular localizations and DNA binding activities were investigated by cell biological/biochemical analyses. Based on these results, we propose a model that recurrent modification of cp nucleoid organization by eukaryotic factors originally related to chromatin organization might have been the driving force for the diversification of cp nucleoids since the early stage of green plant evolution.

Published
2020

165. Assembling the picture of stomatal evolution.

Author

Clark, James W.

Subjects
*PLANT evolution, *BOTANY, *GAS exchange in plants, *HOMOLOGY (Biology), *FOSSIL plants, *STOMATA, *FERNS
Abstract

This article explores the evolution of stomata, microscopic pores that facilitate gas exchange in plants. The authors argue that stomata in the gametophyte generation of hornworts should be considered the earliest example of stomata in the gametophyte generation of living plants. They challenge the previous belief that stomata are only found in the diploid, sporophyte generation. The article emphasizes the unique characteristics of hornworts and their significance in understanding the evolution of early land plants. The presence of stomata in both generations suggests a potential common ancestor for plants, although this is speculative. Genetic analyses have revealed that stomatal development is controlled by a shared genetic toolkit across land plants. The establishment of a model system in Anthoceros allows for further investigation of stomatal development. Comparative anatomy and other types of evidence are crucial for comprehending the evolution of stomata. [Extracted from the article]

Published
2024
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169. Genome evolution in plants and the origins of innovation.

Author

Clark, James W.

Subjects
*HORIZONTAL gene transfer, *PLANT evolution, *CHROMOSOME duplication, *PLANT genomes, *PLANT diversity, *PLANT competition, *PLANT genes
Abstract

Summary: Plant evolution has been characterised by a series of major novelties in their vegetative and reproductive traits that have led to greater complexity. Underpinning this diversification has been the evolution of the genome. When viewed at the scale of the plant kingdom, plant genome evolution has been punctuated by conspicuous instances of gene and whole‐genome duplication, horizontal gene transfer and extensive gene loss. The periods of dynamic genome evolution often coincide with the evolution of key traits, demonstrating the coevolution of plant genomes and phenotypes at a macroevolutionary scale. Conventionally, plant complexity and diversity have been considered through the lens of gene duplication and the role of gene loss in plant evolution remains comparatively unexplored. However, in light of reductive evolution across multiple plant lineages, the association between gene loss and plant phenotypic diversity warrants greater attention. James Clark is a finalist of the 2023 New Phytologist Tansley Medal competition for excellence in plant science. See Slater & Dolan (2023, 240: 2171–2172) for more details. [ABSTRACT FROM AUTHOR]

Published
2023
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170. The origin and early evolution of plants.

Author

Bowles, Alexander M.C., Williamson, Christopher J., Williams, Tom A., Lenton, Timothy M., and Donoghue, Philip C.J.

Subjects
*PLANT evolution, *MOLECULAR clock, *BIOGEOCHEMICAL cycles, *FOSSILS, *PHYLOGENY, *PLANT genomes
Abstract

Plant (archaeplastid) evolution has transformed the biosphere, but we are only now beginning to learn how this took place through comparative genomics, phylogenetics, and the fossil record. This has illuminated the phylogeny of Archaeplastida, Viridiplantae, and Streptophyta, and has resolved the evolution of key characters, genes, and genomes – revealing that many key innovations evolved long before the clades with which they have been casually associated. Molecular clock analyses estimate that Streptophyta and Viridiplantae emerged in the late Mesoproterozoic to late Neoproterozoic, whereas Archaeplastida emerged in the late-mid Palaeoproterozoic. Together, these insights inform on the coevolution of plants and the Earth system that transformed ecology and global biogeochemical cycles, increased weathering, and precipitated snowball Earth events, during which they would have been key to oxygen production and net primary productivity (NPP). The origin of the first photosynthetic eukaryotes through to the first land plants transformed the Earth's biosphere. There is no single unified view of the processes and timing of early plant evolution despite myriad fossil and geochemical evidence. Phylogenetically targeted genomic, morphological, and Earth system data will be necessary to make significant advances in our understanding of early plant evolution given the deep timescales. [ABSTRACT FROM AUTHOR]

Published
2023
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171. Historical biogeography of Vochysiaceae reveals an unexpected perspective of plant evolution in the Neotropics.

Author

Gonçalves, Deise J. P., Shimizu, Gustavo H., Ortiz, Edgardo M., Jansen, Robert K., and Simpson, Beryl B.

Subjects
*PLANT evolution, *BIOGEOGRAPHY, *FOREST plants, *PHYLOGENY, *MYRTACEAE, *PROBABILITY theory
Abstract

Premise: Despite the fast pace of exploration of the patterns and processes influencing Neotropical plant hyperdiversity, the taxa explored are mostly from large groups that are widely distributed, morphologically diverse, or economically important. Vochysiaceae is an example of an undersampled taxon, providing an excellent system for investigating Neotropical biogeography. We present a phylogenomics‐based hypothesis of species relationships in Vochysiaceae to investigate its evolutionary history through space and time. Methods: We inferred a phylogeny for 122 species from Vochysiaceae and seven other families of Myrtales. Fossils from four myrtalean families were used to estimate the divergence times within Vochysiaceae. Historical biogeography was estimated using ancestral range probabilities and stochastic mapping. Results: Monophyly of all genera was supported except for Qualea, which was split by Ruizterania into two clades. Vochysiaceae originated ~100 mya, splitting into an Afrotropical and a Neotropical lineage ~50 mya, and its ancestral range is in the area currently occupied by the Cerrado. Conclusions: The most recent common ancestor of Vochysiaceae + Myrtaceae had a West Gondwanan distribution, supporting a South American + African ancestral range of Vochysiaceae. On a global scale, geographic range reduction was the principal biogeographic event. At a finer scale, initial range reduction was also important and the Cerrado region was the most ancestral area with multiple colonization events to the Amazon, Central America, and the Atlantic Forest. Colonization events occurred from open areas to forest vegetation, an unusual finding regarding the evolution of plants in the Neotropics. [ABSTRACT FROM AUTHOR]

Published
2020
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172. Zygnema circumcarinatum UTEX 1559 chloroplast and mitochondrial genomes provide insight into land plant evolution.

Author

Orton, Lauren M, Fitzek, Elisabeth, Feng, Xuehuan, Grayburn, W Scott, Mower, Jeffrey P, Liu, Kan, Zhang, Chi, Duvall, Melvin R, and Yin, Yanbin

Subjects
*COMPARATIVE genomics, *PLANT evolution, *CHLOROPLAST DNA, *RNA polymerases, *DNA polymerases, *BACTERIAL proteins, *NUCLEOTIDE sequence
Abstract

The complete chloroplast and mitochondrial genomes of Charophyta have shed new light on land plant terrestrialization. Here, we report the organellar genomes of the Zygnema circumcarinatum strain UTEX 1559, and a comparative genomics investigation of 33 plastomes and 18 mitogenomes of Chlorophyta, Charophyta (including UTEX 1559 and its conspecific relative SAG 698-1a), and Embryophyta. Gene presence/absence was determined across these plastomes and mitogenomes. A comparison between the plastomes of UTEX 1559 (157 548 bp) and SAG 698-1a (165 372 bp) revealed very similar gene contents, but substantial genome rearrangements. Surprisingly, the two plastomes share only 85.69% nucleotide sequence identity. The UTEX 1559 mitogenome size is 215 954 bp, the largest among all sequenced Charophyta. Interestingly, this large mitogenome contains a 50 kb region without homology to any other organellar genomes, which is flanked by two 86 bp direct repeats and contains 15 ORFs. These ORFs have significant homology to proteins from bacteria and plants with functions such as primase, RNA polymerase, and DNA polymerase. We conclude that (i) the previously published SAG 698-1a plastome is probably from a different Zygnema species, and (ii) the 50 kb region in the UTEX 1559 mitogenome might be recently acquired as a mobile element. [ABSTRACT FROM AUTHOR]

Published
2020
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173. Deciphering Soil-Plant and Soil-Insect Interactions: A Mathematical Modeling Approach.

Author

Khelalfa, Khaoula and Khelalfa, Houssam

Subjects
*PLANT-soil relationships, *PLANT evolution, *MATHEMATICAL models, *MATHEMATICAL functions, *HYPOTHESIS
Abstract

The Pev and Rv functions were introduced as a way of summarizing the mechanical phenomenon of root-soil interactions and the effect of root growth on soil volume. The Mohr-Coulomb criterion was applied to the Rv function to demonstrate the relationship between root morphology, soil mechanical properties, and soil stability. The theory of elasticity and plasticity was applied in the analysis of the Bio-Geo Interface, which showed that the force F generated by the roots increased with time due to the growth of the roots and the increase in their volume. The forces acting on the Bio-Geo Interface were represented mathematically through the use of vector arithmetic, which helped to calculate the direction of the forces acting on the system. The Pev function was used to study the evolution of the plant and how it affected the Rv function. The results showed that the interplay between plant growth and soil mechanics is crucial in understanding the behavior of the Bio-Geo Interface, and can provide valuable insights into the interactions between plants and soil in natural and engineered systems. In the study of soil-insect interaction, a mathematical function, Iev, was proposed to represent the insect's evolution in the soil environment. The function takes into account factors such as food sources and void ratio, which are important indicators of the biological and geotechnical aspects of the soil respectively. Despite the potential impact of insects on the soil environment, it has been concluded that their force resulting from their movement and behavior is negligible according to theories of elasticity and plasticity. This means that the impact of insects on the soil is minimal and does not significantly affect the soil's mechanical properties. However, the biological aspects of the soil, such as food sources, remain important factors in the study of insect evolution in the soil environment. [ABSTRACT FROM AUTHOR]

Published
2024
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179. The timescale of early land plant evolution

Author

Morris, JL, Puttick, MN, Clark, JW, Edwards, D, Kenrick, P, Pressel, S, Wellman, CH, Yang, Z, Schneider, Harald, Donoghue, PCJ, Morris, JL, Puttick, MN, Clark, JW, Edwards, D, Kenrick, P, Pressel, S, Wellman, CH, Yang, Z, Schneider, Harald, and Donoghue, PCJ

Abstract

ORCiD: 0000-0002-3626-5460, Establishing the timescale of early land plant evolution is essential for testing hypotheses on the coevolution of land plants and Earth’s System. The sparseness of early land plant megafossils and stratigraphic controls on their distribution make the fossil record an unreliable guide, leaving only the molecular clock. However, the application of molecular clock methodology is challenged by the current impasse in attempts to resolve the evolutionary relationships among the living bryophytes and tracheophytes. Here, we establish a timescale for early land plant evolution that integrates over topological uncertainty by exploring the impact of competing hypotheses on bryophyte−tracheophyte relationships, among other variables, on divergence time estimation. We codify 37 fossil calibrations for Viridiplantae following best practice. We apply these calibrations in a Bayesian relaxed molecular clock analysis of a phylogenomic dataset encompassing the diversity of Embryophyta and their relatives within Viridiplantae. Topology and dataset sizes have little impact on age estimates, with greater differences among alternative clock models and calibration strategies. For all analyses, a Cambrian origin of Embryophyta is recovered with highest probability. The estimated ages for crown tracheophytes range from Late Ordovician to late Silurian. This timescale implies an early establishment of terrestrial ecosystems by land plants that is in close accord with recent estimates for the origin of terrestrial animal lineages. Biogeochemical models that are constrained by the fossil record of early land plants, or attempt to explain their impact, must consider the implications of a much earlier, middle Cambrian–Early Ordovician, origin., Copyright © 2018 the Author(s). This open access article is distributed under Creative Commons Attribution-NonCommercial-NoDerivatives License 4.0 (CC BY-NC-ND). The attached file is the published version of the article., NHM Repository, NHM Repository

Published
2019

180. Plant Evolution: Divergent Plants, Divergent Functions for C1HDZ Orthologs

Author

Monte, Isabel and Monte, Isabel

Abstract

Ortholog identification inferred by phylogenetic analyses does not always correlate with functional conservation. The recent functional characterization of the C1HDZ transcription factor in the early-diverging land plant Marchantia polymorpha reveals its role in biotic stress responses, contrary to its orthologs in flowering plants.

Published
2020

185. A century‐long record of plant evolution reconstructed from a coastal marsh seed bank

Author

Colin J. Saunders, Christopher B. Craft, Jennifer L. Summers, Michael J. Blum, Jeffrey D. Herrick, and Jason S. McLachlan

Subjects
Marsh, Letter, Evolution, Climate change, Biology, Chesapeake Bay, Schoenoplectus americanus, salinity, QH359-425, Genetics, Scirpus olneyi, Ecosystem, Letters, resurrection ecology, Ecology, Evolution, Behavior and Systematics, Plant evolution, geography, Resurrection ecology, geography.geographical_feature_category, Ecology, biology.organism_classification, Salinity, climate change, sea level rise, Paleosalinity
Abstract

Evidence is mounting that climate-driven shifts in environmental conditions can elicit organismal evolution, yet there are sparingly few long-term records that document the tempo and progression of responses, particularly for plants capable of transforming ecosystems. In this study, we “resurrected” cohorts of a foundational coastal marsh sedge (Schoenoplectus americanus) from a time-stratified seed bank to reconstruct a century-long record of heritable variation in response to salinity exposure. Common-garden experiments revealed that S. americanus exhibits heritable variation in phenotypic traits and biomass-based measures of salinity tolerance. We found that responses to salinity exposure differed among the revived cohorts, with plants from the early 20th century exhibiting greater salinity tolerance than those from the mid to late 20th century. Fluctuations in salinity tolerance could reflect stochastic variation but a congruent record of genotypic variation points to the alternative possibility that the loss and gain in functionality are driven by selection, with comparisons to historical rainfall and paleosalinity records suggesting that selective pressures vary according to shifting estuarine conditions. Because salinity tolerance in S. americanus is tightly coupled to primary productivity and other vital ecosystem attributes, these findings indicate that organismal evolution merits further consideration as a factor shaping coastal marsh responses to climate change.

Published
2021

186. Plant evolution and environmental adaptation unveiled by long-read whole-genome sequencing of Spirodela.

Author

Dong An, Yong Zhou, Changsheng Li, Qiao Xiao, Tao Wang, Yating Zhang, Yongrui Wu, Yubin Li, Dai-Yin Chao, Messing, Joachim, and Wenqin Wang

Subjects
*PLANT evolution, *SMALL interfering RNA, *COMPLEMENTARY DNA, *ANTISENSE DNA, *PEPTIDE antibiotics
Abstract

Aquatic plants have to adapt to the environments distinct from where land plants grow. A critical aspect of adaptation is the dynamics of sequence repeats, not resolved in older sequencing platforms due to incomplete and fragmented genome assemblies from short reads. Therefore, we used PacBio long-read sequencing of the Spirodela polyrhiza genome, reaching a 44-fold increase of contiguity with an N50 (a median of contig lengths) of 831 kb and filling 95.4% of gaps left from the previous version. Reconstruction of repeat regions indicates that sequentially nested long terminal repeat (LTR) retrotranspositions occur early in monocot evolution, featured with both prokaryote-like gene-rich regions and eukaryotic repeat islands. Protein-coding genes are reduced to 18,708 gene models supported by 492,435 high-quality full-length PacBio complementary DNA (cDNA) sequences. Different from land plants, the primitive architecture of Spirodela's adventitious roots and lack of lateral roots and root hairs are consistent with dispensable functions of nutrient absorption. Disease-resistant genes encoding antimicrobial peptides and dirigent proteins are expanded by tandem duplications. Remarkably, disease-resistant genes are not only amplified, but also highly expressed, consistent with low levels of 24-nucleotide (nt) small interfering RNA (siRNA) that silence the immune system of land plants, thereby protecting Spirodela against a wide spectrum of pathogens and pests. The long-read sequence information not only sheds light on plant evolution and adaptation to the environment, but also facilitates applications in bioenergy and phytoremediation. [ABSTRACT FROM AUTHOR]

Published
2019
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187. Rapid plant evolution driven by the interaction of pollination and herbivory.

Author

Ramos, Sergio E. and Schiest, Florian P.

Subjects
*PLANT evolution, *POLLINATION by bees, *HERBIVORES, *BRASSICA, *BUMBLEBEES
Abstract

Pollination and herbivory are both key drivers of plant diversity but are traditionally studied in isolation from each other. We investigated real-time evolutionary changes in plant traits over six generations by using fast-cycling Brassica rapa plants and manipulating the presence and absence of bumble bee pollinators and leaf herbivores. We found that plants under selection by bee pollinators evolved increased floral attractiveness, but this process was compromised by the presence of herbivores. Plants under selection from both bee pollinators and herbivores evolved higher degrees of self-compatibility and autonomous selfing, as well as reduced spatial separation of sexual organs (herkogamy). Overall, the evolution of most traits was affected by the interaction of bee pollination and herbivory, emphasizing the importance of the cross-talk between both types of interactions for plant evolution. [ABSTRACT FROM AUTHOR]

Published
2019
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189. Plant evolution along the 'fast-slow' growth economics spectrum under altered precipitation regimes

Author

Lindh, Magnus, Manzoni, Stefano, Lindh, Magnus, and Manzoni, Stefano

Abstract

Plants have evolved different strategies to withstand drought. In general, these strategies can be defined along a plant economics spectrum, which classifies plants depending on whether their growth rate is fast or slow, where fast growth is associated with high mortality, high water use, and high sensitivity to drought. Which strategy along this economy spectrum will be selected under different precipitation regimes is an open question. We address this question with a minimal soil-plant model in which a single plant economy trait related to growth rate characterizes the plant strategy. This generic and dimensionless trait influences both recruitment and mortality, but not background mortality. We explore the evolution of this trait by quantifying its effects on birth, mortality, and transpiration rates. Furthermore, we explore the influence of direct plant density dependence acting on recruitment and mortality, in addition to the indirect density dependence caused by plant feedback on soil water content. We show that: (1) Increasingly fast-growing plants always evolve under increasing background mortality. (2) When soil water only depends on plant density and is independent of precipitation and abiotic water losses, the strategy minimizing soil water content is an evolutionarily stable strategy (ESS); i.e., the evolutionary outcome is a tragedy of the commons (Hardin, 1968). (3) When precipitation, abiotic water losses and trait dependent transpiration determine soil water content, the ESS lies between the strategy maximizing plant density and that minimizing soil water content; i.e., no tragedy of the commons occurs. (4) With a deterministic precipitation model and density dependence acting directly only on recruitment, higher precipitation promotes the evolution of faster plants. The opposite result is found when density dependence is acting directly only on mortality. (5) Similar trends in the economy trait are observed when forcing the model with stochastic pre

Published
2021
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190. Geobiological Impacts of PalaeozoicLand Plant Evolution

Author

Valette, Camille and Valette, Camille

Abstract

For two centuries, questions about the origin of terrestrial plants and their impacts on the Earth systemhave occupied palaeobotanists. This essay attempts to synthesise the state of research to date, and outlineareas where major questions remain. Fossil evidence for land plants first appears in rocks of MiddleOrdovician age (~ 470 Ma), but it was not until the Devonian that vascular plants became the dominantgeobiological agents on the continents. Plants began as small organisms, lacking any vascular tissues,and essentially confined to wetlands. Key developments in their reproductive biology and the evolutionof mycorrhizal symbiosis subsequently enabled early plants to exploit a broader range of environments,enhancing water uptake and absorption of nutrients. In turn, the evolution of plant roots has significantlyimpacted terrestrial landscapes. The Devonian rise of plants led to a modification of the weathering rateand a sharp increase in the rate of mudrock production. This was driven by the impacts that plants exerted on watercourses, with the creation of meandering rivers and deltas that retained fine siliciclasticmaterials. This increase in weathering rate, combined with the development of leaves and the intensification of photosynthesis also had consequences for the carbon cycle and atmosphere, reducing the levelof CO2 and increasing that of O2 in the atmosphere. The increased proportion of oxygen and creation ofcombustible material is also thought to have led to the planets first wildfires, whilst the decrease in CO2lowered global temperatures. Via a complex set of feedbacks, these modifications may even have drivena series of anoxic events in the oceans, generating one of the five major mass extinctions at the end ofthe Devonian., Paleobotanik är studien om fossiliserade växter. Då växter ursprungligen först saknades från jordens ytahar deras utveckling och kolonisering av kontinenterna (för 450 miljoner år sedan) haft många effekter.Ursprungligen var de första landväxter små och liknande modernt gräs. Deras små rötter begränsadedem till närvaron av vattenkällor (hav, flod, träsk…). En symbios med svampen (kallad mykorrhizalsymbios) underlättade landväxtens upptag av näring samt utvecklingen av djupare rötter, vilket ocksåunderlättade deras upptag av vatten. Då landväxter nu kunde migrera till torrare landskap har antaletlandväxter ökat med tiden. Det växande antalet landväxter var viktigt för bildningen av exempelvis kol,vilket är slutprodukten av dött växtmaterial som begravts och utsatts för höga tryck och temperaturförhållanden. Den geologiska perioden Karbon (359–299 miljoner år sedan) namngavs tack vare av denenorma andelen kol som kan dateras tillbaka till denna tid. Genom fotosyntes kan växter även absorbera CO2 och frigöra syre, och på så vis förändra atmosfärenssammansättning. På grund av högre syrehalter i atmosfären blev bränder ett allt vanligare fenomen eftersom det försågs med växter och syre som bränsle, som i sin tur även förbättrade bevarandet av frönoch växtvävnader i form av träkol. Oavsett om det är växtens frigöring av syre, minskning av CO2 (som är en växthusgas) eller genombränder, har uppkomst av landväxter haft en stor inverkan på atmosfärens sammansättning, och därföräven klimatet. På grund av en hastig nedgång av temperatur och syrehalt i haven mellan 450–375 miljoner år sedan (från 40 till 25 °C), utrotades nästan 75% av allt djurliv. Upphovet av denna massutrotning, genom försämringen av vattenkvalité, och uppkomsten av syrefritt vattenmiljöer tros bero på näringsläckage av jordar orsakat av ett ökat tillstånd av alger som spreds i samband med landväxters rotutveckling.

Published
2021

192. Three new species of the genus Argyresthia Hübner, [1825] from Guatemala, with notes on host plant evolution and Nearctic taxa (Lepidoptera: Argyresthiidae)

Author

Jacob A. Gorneau, Loren D. Jones, José Monzón-Sierra, and Jason J. Dombroskie

Subjects
Insect Science, Animal Science and Zoology, Ecology, Evolution, Behavior and Systematics
Abstract

Neotropical species of the genus Argyresthia Hübner, [1825] represent a reservoir of undescribed biodiversity and are the most poorly known members of this cosmopolitan genus. From a series of Guatemalan material, three new species are described: Argyresthia quetzaltenangonella Gorneau & Dombroskie, sp. nov., Argyresthia guatemala Gorneau & Dombroskie, sp. nov., Argyresthia iridescentia Gorneau & Dombroskie, sp. nov., representing the first Neotropical species to be described in over a century, and the first from Central America. A phylogeny is inferred using the barcode gene cytochrome c oxidase subunit I (COI), representing an initial foray into the internal relationships of the family. For species with known host plants and available molecular data, a stochastic character mapping analysis was conducted to estimate character states at internal nodes. Furthermore, this phylogeny allows for preliminary insights into the monophyly of the subgenus Blastotere Ratzeburg 1840. Systematic work onArgyresthia remains particularly salient as species in the genus run the gamut from being pests to being considered extinct. Furthermore, notes are provided regarding the status of select Nearctic species, such as the ongoing confusion in North America between Argyresthia goedartella (Linnaeus, 1758) and A. calliphanes Meyrick 1913. Focusing taxonomic efforts on Argyresthia of the Neotropics will lay the foundation for future work regarding biodiversity, ecology, and biogeography of the family.

Published
2023

197. Temporal regulation of vegetative phase change in plants.

Author

Poethig, R. Scott and Fouracre, Jim

Subjects
*PLANT evolution, *PHASE transitions, *LEAF development, *FLOWERING time, *GREENHOUSES
Abstract

During their vegetative growth, plants reiteratively produce leaves, buds, and internodes at the apical end of the shoot. The identity of these organs changes as the shoot develops. Some traits change gradually, but others change in a coordinated fashion, allowing shoot development to be divided into discrete juvenile and adult phases. The transition between these phases is called vegetative phase change. Historically, vegetative phase change has been studied because it is thought to be associated with an increase in reproductive competence. However, this is not true for all species; indeed, heterochronic variation in the timing of vegetative phase change and flowering has made important contributions to plant evolution. In this review, we describe the molecular mechanism of vegetative phase change, how the timing of this process is controlled by endogenous and environmental factors, and its ecological and evolutionary significance. [ABSTRACT FROM AUTHOR]

Published
2024
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