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1. Seed Cryopreservation, Germination, and Micropropagation of Eastern Turkeybeard, Xerophyllum asphodeloides (L.) Nutt.: A Threatened Species from the Southeastern United States

   https://doi.org/10.3390/plants10071462  

   Issac, Michelle; Kuriakose, Princy; Leung, Stacie; Costa, Alex B.; Johnson, Shannon; Bucalo, Kylie; Stober, Jonathan M.; Determann, Ron O.; Rogers, Will L.; Cruse-Sanders, Jenifer M.; et al (July 2021, Plants)

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   Xerophyllum asphodeloides (Xerophyllaceae), known as eastern turkeybeard, is an herbaceous perennial found in eastern North America. Due to decline and destruction of its habitat, several states rank X. asphodeloides as “Imperiled” to “Critically Imperiled”. Protocols for seed cryopreservation, in vitro germination, sustainable shoot micropropagation, shoot establishment in soil, and seed germination are presented. Seeds from two tested sources were viable after 20 months of cryopreservation. Germination of isolated embryos in vitro was necessary to overcome strong seed dormancy. Shoot multiplication and elongation occurred on ½ MS medium without PGRs. Shoots rooted in vitro without PGRs or with 0.5 mg/L NAA or after NAA rooting powder treatment and placement in potting mix. When planted in wet, peaty soil mixes, shoots grew for two months and then declined. When planted in a drier planting mix containing aged bark, most plants continued growth. In the field, plant survival was 73% after three growing seasons. Safeguarding this species both ex situ and in situ is possible and offers a successful approach to conservation. Whole seeds germinated after double dormancy was overcome by incubation under warm moist conditions for 12 weeks followed by 12 weeks cold at 4 °C and then warm. 

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2. Common milkweed seeds exhibit latitudinal clines more consistent with adaptation to growing season length than temperature

   https://doi.org/10.1111/rec.13878  

   Mohl, Emily K.; McCall, Andrew C.; Wood, Madelyn; Sherman, Lauren; Reid, Mari V.; Saunders, Patricia A.; Scanga, Sara E.; Danielson, Clara; Fisher‐Reid, M. Caitlin; Marella, Heather; et al (February 2023, Restoration Ecology)

   Overwintering monarch (Danaus plexippus) populations have declined since the 1990s. In response, restoration of milkweeds, including Asclepias syriaca (common milkweed), an important host plant in their breeding grounds, has become increasingly common. However, latitudinal variation in milkweed populations suggests the possibility of regional adaptation and the potential for seed provenance to affect restoration success. Using seeds from 20 populations throughout the range of A. syriaca, we tested whether seed mass, germination success, and germination time in the greenhouse demonstrate geographic clines consistent with available evidence for this species from other studies. In addition, we tested for patterns in germination traits consistent with adaptation to spring thermal conditions by planting seeds from 10 populations in growth chambers simulating Minnesota and Kentucky spring temperatures. Even after accounting for seed mass, seeds from higher latitudes germinated faster on average under all conditions. Elevated temperatures accelerated germination time and leaf development time; however, we did not detect geographic patterns in leaf development time, indicating that the processes underlying the latitudinal cline in germination time may be unique to the germination stage. In the thermal adaptation study, high-latitude populations produced larger seeds and seeds that germinated at a higher rate; however, neither latitudinal trend was observed in the geographic clines study, even though individual seed mass predicted germination success. High-latitude populations express more favorable germination traits in every setting measured, perhaps due to reduced dormancy. Consequently, we conclude that latitudinal clines are more consistent with adaptation to growing season length than to spring temperatures. 

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3. Plant‐driven changes in soil microbial communities influence seed germination through negative feedbacks

   https://doi.org/10.1002/ece3.5476  

   Miller, Lee_C; Perron, Gabriel_G; Collins, Cathy_D (July 2019, Ecology and Evolution)

   Abstract Plant–soil feedbacks (PSFs) drive plant community diversity via interactions between plants and soil microbes. However, we know little about how frequently PSFs affect plants at the seed stage, and the compositional shifts in fungi that accompany PSFs on germination.We conducted a pairwise PSF experiment to test whether seed germination was differentially impacted by conspecific versus heterospecific soils for seven grassland species. We used metagenomics to characterize shifts in fungal community composition in soils conditioned by each plant species. To investigate whether changes in the abundance of certain fungal taxa were associated with multiple PSFs, we assigned taxonomy to soil fungi and identified putative pathogens that were significantly more abundant in soils conditioned by plant species that experienced negative or positive PSFs.We observed negative, positive, and neutral PSFs on seed germination. Although conspecific and heterospecific soils for pairs with significant PSFs contained host‐specialized soil fungal communities, soils with specialized microbial communities did not always lead to PSFs. The identity of host‐specialized pathogens, that is, taxa uniquely present or significantly more abundant in soils conditioned by plant species experiencing negative PSFs, overlapped among plant species, while putative pathogens within a single host plant species differed depending on the identity of the heterospecific plant partner. Finally, the magnitude of feedback on germination was not related to the degree of fungal community differentiation between species pairs involved in negative PSFs.Synthesis. Our findings reveal the potential importance of PSFs at the seed stage. Although plant species developed specialized fungal communities in rhizosphere soil, pathogens were not strictly host‐specific and varied not just between plant species, but according to the identity of plant partner. These results illustrate the complexity of microbe‐mediated interactions between plants at different life stages that next‐generation sequencing can begin to unravel. 

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4. Assessments in early growth of corn seedlings after hausmanite (Mn ₃ O ₄ ) nanoscale seed priming

   https://doi.org/10.1080/01904167.2021.1871745  

   Esper Neto, Michel; Britt, David W.; Jackson, Kyle Alan; Coneglian, Carolina Fedrigo; Cordioli, Vitor Rodrigues; Braccini, Alessandro Lucca; Inoue, Tadeu Takeyoshi; Batista, Marcelo Augusto (January 2021, Journal of Plant Nutrition)

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   Nanofertilizer application is becoming a sustainable alternative for plants micronutrients supply. Seed nutrient priming before seeding reduces non- target dispersion; although, applying nanofertilizer in correct concentration must be narrowly chosen to prevent germination and development issues. Here, we evaluated corn seedlings development and germination after seed priming with Mn3O4 nanoparticle (NP), Mn3O4 bulk and MnCl2. Sterile seeds were soaked for 8hours in priming solutions of 0, 20, 40, 80 and 160mg L
   1 for each Mn sources. The seeds vigor and germination were evaluated after 7 days on germination paper. Root, shoot and total lengths were measured as well as root, shoot and total dry biomass. Compared to the control, the Mn3O4 NP and Mn3O4 bulk promoted beneficial effects. Mn3O4 NP seed-priming exhibited a concentration dependent profile in improving seedling growth, with greatest benefit around 20mg L
   1, pro- viding higher germination, vigor, dry biomass and length than control and the other source tested. Particle size plays an important role in the reactiv- ity of Mn3O4 NP. On the other hand, seeds primed with soluble source did not differ from the control. These findings support NP-seed priming as an alternative to delivery micronutrients. 

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5. Rapid and Robust Polysome Isolation and Fraction RNA Extraction for Studying the Seed Translatome

   https://doi.org/10.1002/cpz1.70007  

   Duong, Ha Ngoc; Ansaf, Huda; Cornish, Peter; Mendoza‐Cozatl, David; Schenck, Craig; Angelovici, Ruthie (September 2024, Current Protocols)

   Abstract Translation of mRNA into functional proteins is a fundamental process underlying many aspects of plant growth and development. Yet, the role of translational regulation in plants across diverse tissue types, including seeds, is not well known due to the lack of methods targeting these processes. Studying the seed translatome could unveil seed‐specific regulatory mechanisms, offering valuable insights for breeding efforts to enhance seed traits. Polysome profiling is a widely used technique for studying mRNAs being translated. However, the traditional method is time‐consuming and has a low polysome recovery rate; therefore, it requires substantial starting material. This is particularly challenging for species or mutants with limited seed quantities. Additionally, seed polysome fractions often yield low quality RNA due to the abundance of various compounds that interfere with conventional RNA extraction protocols. Here we present a robust polysome extraction method incorporating a size‐exclusion step for polysome concentration streamlined with a rapid RNA extraction method optimized for seeds. This protocol works across multiple plant species and offers increased speed and robustness, requiring less than half the amount of seed tissue and time compared to conventional methods while ensuring high polysome recovery and yield of high‐quality RNA for downstream experiments. These features make this protocol an ideal tool for studying seed translation efficiency and hold broad applicability across various plant species and tissues. © 2024 Wiley Periodicals LLC. Basic Protocol 1: Robust polysome extraction for seeds Basic Protocol 2: Rapid fraction total RNA extraction 

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