Regulation of gametogenesis and zoosporogenesis in Ulva linza (Chlorophyta): comparison with Ulva mutabilis and potential for laboratory culture

Vesty, Eleanor F.; Kessler, Ralf W.; Wichard, Thomas; Coates, Juliet C.

doi:10.3389/fpls.2015.00015

Cited by 61 publications

(60 citation statements)

References 34 publications

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“…Upon removal of the sporulation inhibitors, the gametogenesis of the thalli can be artificially and synchronously initiated ( Stratmann et al 1996, Wichard andOertel 2010). This was also observed in Ulva linza L. (Vesty et al 2015) and Ulva lactuca L. (Wichard and Oertel 2010).…”

Section: Introductionmentioning

confidence: 89%

Cell structure and microtubule organisation during gametogenesis of Ulva mutabilis Føyn (Chlorophyta)

et al. 2017

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Cell structure and microtubule organisation during gametogenesis of the green alga Ulva mutabilis was studied using light microscopy, transmission electron microscopy (TEM) and tubulin immunofluorescence. Micro tubules in vegetative cells are organised in parallel bundles traversing the cortical cytoplasm. During gameto genesis, induced blade cells are transformed to gametangia, depending on the maturity of the algae and the removal of regulatory sporulation inhibitors. This differentiation is accompanied by formation of a conical cell projection (papilla) towards the exterior of the thallus. Microtubules form a clear, basket-like configuration converging towards the conical tip, but not reaching it. The conical microtubule structure stops below the tip, leaving a circular "opening". Parallel to the above, the cell wall of the tip is differentiated, forming a "cap". Nuclear divisions start at this stage, finally forming the nuclei of future gametes. Cytokinesis takes place by membrane furrowing and vesicle fusion, giving rise to 16 oval-shaped gametes. The conical microtubule organisation is gradually depoly merised, and a cortical, intensely fluorescing micro tubule bundle is formed in each gamete. At this stage, the cap at the conical cell wall projection is removed and the exit pore opens. The biflagellate gametes remain initially motionless, connected by thin cytoplasmic bridges. Finally, they are released to the environment upon additional removal of a swarming inhibitor accumulated in the growth medium during gametogenesis.

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Section: Introductionmentioning

confidence: 89%

Cell structure and microtubule organisation during gametogenesis of Ulva mutabilis Føyn (Chlorophyta)

et al. 2017

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“…SI-2 is excreted into the space between the two cell layers. Gametogenesis or sporogenesis can be induced by cutting the thallus into fragments and subsequent washing as observed in different Ulva species, since this is thought to result in the removal of both sporulation inhibitors (Stratmann et al 1996, Wichard and Oertel 2010, Vesty et al 2015. The SI-2-type sporulation inhibitor forms a gradient from the base to the top of the thallus, resulting in higher percentages of gamete formation and discharge from the apical regions (Wichard and Oertel 2010).…”

Section: Endogenous Signalingmentioning

confidence: 99%

Seaweed reproductive biology: environmental and genetic controls

et al. 2017

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Knowledge of life cycle progression and reproduction of seaweeds transcends pure academic interest. Successful and sustainable seaweed exploitation and domestication will indeed require excellent control of the factors controlling growth and reproduction. The relative dominance of the ploidy-phases and their respective morphologies, however, display tremendous diversity. Consequently, the ecological and endogenous factors controlling life cycles are likely to be equally varied. A vast number of research papers addressing theoretical, ecological and physiological aspects of reproduction have been published over the years. Here, we review the current knowledge on reproductive strategies, trade-offs of reproductive effort in natural populations, and the environmental and endogenous factors controlling reproduction. Given that the majority of ecophysiological studies predate the "-omics" era, we examine the extent to which this knowledge of reproduction has been, or can be, applied to further our knowledge of life cycle control in seaweeds.

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“…Phenotyping of plant collections to search for beneficial plant traits such as resistance to insect pests is a crucial part of developing new germplasm for breeding of elite varieties that will thrive under likely climate change and pesticide constrained conditions. This is increasingly being done on any accessions that could perceivably be useful to crop improvement (Grosskinsky et al , 2015; Rahaman et al , 2015). …”

Section: Introductionmentioning

confidence: 99%

Searching for wheat resistance to aphids and wheat bulb fly in the historical Watkins and Gediflux wheat collections

Aradottir

Martin

Clark

et al. 2016

Annals of Applied Biology

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Insect pests can reduce wheat yield by direct feeding and transmission of plant viruses. Here we report results from laboratory and field phenotyping studies on a wide range of wheat, including landraces from the Watkins collection deriving from before the green revolution, more modern cultivars from the Gediflux collection (north‐western Europe) and modern UK Elite varieties, for resistance to the bird cherry‐oat aphid, Rhopalosiphum padi (Homoptera: Aphididae) and the English grain aphid, Sitobion avenae (Homoptera: Aphididae). A total of 338 lines were screened for R. padi and 340 lines for S. avenae. Field trials were also conducted on 122 Watkins lines to identify wheat bulb fly, Delia coarctata, preference on these landraces. Considerable variation was shown in insect performance among and within different wheat collections, with reduced susceptibility in a number of varieties, but phenotyping did not identify strong resistance to aphids or wheat bulb fly. Field trials showed within collection differences in aphid performance, with fewer aphids populating lines from the Watkins collection. This differs from development data in laboratory bioassays and suggests that there is a pre‐alighting cue deterring aphid settlement and demonstrates differences in aphid preference and performance on older plants in the field compared with seedlings in the laboratory, highlighting the need for phenotyping for aphid resistance at different plant growth stages. No association was identified between performance of the different insect species on individual varieties, potentially suggesting different nutritional requirements or resistance mechanisms.

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Regulation of gametogenesis and zoosporogenesis in Ulva linza (Chlorophyta): comparison with Ulva mutabilis and potential for laboratory culture

Cited by 61 publications

References 34 publications

Cell structure and microtubule organisation during gametogenesis of Ulva mutabilis Føyn (Chlorophyta)

Cell structure and microtubule organisation during gametogenesis of Ulva mutabilis Føyn (Chlorophyta)

Seaweed reproductive biology: environmental and genetic controls

Searching for wheat resistance to aphids and wheat bulb fly in the historical Watkins and Gediflux wheat collections

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