Comparative flowering ecology of Fraxinus excelsior, Acer platanoides, Acer pseudoplatanus and Tilia cordata in the canopy of Leipzig's floodplain forest

Tal, Ophir

22 June 2006

How do gender separation and the transition to wind pollination happen in temperate trees? What does the reproductive ecology in the crowns of temperate forest trees look like? These connected questions intrigued researchers before and since Darwin but it is only in the last years that a direct study of the latter question has been enabled. A research crane was used to study the flowering ecology of Fraxinus excelsior, Acer platanoides, Acer pseudoplatanus and Tilia cordata in Leipzig’s floodplain forest. These species originate from hermaphrodite insect pollinated plant families and exhibit different grades of gender separation and different stages between insect and wind pollination. As they are typical elements of temperate deciduous forests, an ecological comparison of their flowering ecology may shed new light on the evolution of gender separation and wind pollination in this habitat. Using the crane, gender distribution, flowering phenology in relation to microclimate, pollination levels (including pollen tubes in the styles) and fruit set were studied in ca. 200 trees over 2-4 years. Main results are a new appreciation of the sexual system of Fraxinus excelsior as dioecy, of Tilia cordata as andromonoecy and a detailed description of the intricacies of the heterodichogamous sexual system of Acer pseudoplatanus. Several flowering phenological patterns are described in Fraxinus excelsior and Acer platanoides in relation to microclimate in early spring. The role of small arthropods is underlined as gall mites may play a role in gender specialisation in Fraxinus excelsior, gall midges are related to maleness in T. cordata and thrips are probably the pollinators of Acer pseudoplatanus in the stand. Thrips pollination is suggested to be a possible stepping-stone between insect pollination and wind pollination, which may drive the transition in Acer pseudoplatanus and possibly in intensively flowering dominant species in other habitats. The study presents the complexity of the reproductive systems and the strong interdependencies among their elements.

info:eu-repo/classification/ddc/570

ddc:570

Biologie

THE PHYLOGENOMICS OF THRIPS (THYSANOPTERA)

David A Stanford-Beale (13989918)

09 November 2022

<p><br></p> <p>Thrips, Thysanoptera, represent an ancient (~407 m.y.a.) order of ~6000 tiny insects from 9 families. Despite the small size of the order, thrips have a diversity of life histories, diets, and survival strategies. Thrips represent a challenge to fieldworkers and axonomists alike due to the morphological similarity between species and the lack of homologies between families. Recent </p> <p>molecular evidence has reopened debate over the phylogenetic relationships of the families of Thysanoptera.</p> <p>In this thesis we use genomic approaches to elucidate and clarify the early nodes in order to answer evolutionary questions about the Thysanoptera, their mitochondrion symbiotes, and their </p> <p>coevolutionary interactions with a group of economically important viruses; tospoviruses. Our results support previous ordinal hypotheses and show families in both sub-orders radiating </p> <p>around the emergence of the angiosperms ~120 m.y.a. We show that all thrips lineages likely have highly rearranged mitochondrial genomes, even on an intraspecies level, and that this rearrangement phenomena occurs very quickly in evolutionary time. We provide comment on the caution that must be taken with mitochondrial loci in any phylogenetic analysis with this new </p> <p>evidence and argue for the impact of among-site-rate-heterogeneity to be further investigated within thrips hylogenetics. We show that much more data is needed before thrips and tospovirus relationships can be fully elucidated but that two dueling hypotheses are emergent from our studies: either 5 very new separate vector/virus relationships, or one very old relationship that has been lost by the vast amount of thrips. We call for targeted taxa selection and show how new genomic methods can target certain taxa based upon the identification of </p> <p>assembled proteins from illumine shotgun read data.</p>

Animal systematics and taxonomy

Evolutionary ecology

Host-parasite interactions

Phylogeny and comparative analysis

Genomics

Genetics not elsewhere classified

thrips

entomology

genomics

evolution

mitochondria

mitogenomes

tospoviruses

virus interactions

Coevolution

Non chemical alternatives for pest management: Entomopathogenic nematodes and UV-C light

Higginbotham, Matthew Travis

10 November 2021

The primary objectives of this research are to determine effective biological and alternative control strategies of insect and disease pests in order to reduce harsh chemical use during greenhouse crop production and transport s. This research includes two separate studies: 1) testing the practical viability of rearing and storing four species of entomopathogenic nematode (EPN), Steinernema feltiae, Steinernema carpocapsae, Heterorhabditis bacteriophora, Heterorhabditis indica; and, 2) the efficacy of UV-C radiation applied, pre-transport, as a preventative disease control strategy against Botrytis cinerea. A study was conducted testing EPN infectious juvenile (IJ) rearing production counts and IJ viability after a six-day storage period. When all four species are compared, S. feltiae had a greater number of infectious juveniles emerge from the wax moth cadavers and S. carpocasae had the least. All four species survived the six day storage period but EPN infectious juvenile counts were significantly different among species. Our second study tested the efficacy of UV-C radiation as an alternative control to traditional fungicides to deactivate B. cinerea in vitro and to determine plant tolerance to UV-C. The crops tested were poinsettia (Euphorbia pulcherrima) and primula (Primula vulgaris). All the UV-C doses, 1.0, 2.8, 3.7 or 4 W/m2, significantly decreased B. cinerea conidial germination in vitro and resulted in zero percent damage on poinsettia bracts. However, all UV-C doses during both replications caused minor damage, 15% or less, to primula flowers. / Master of Science in Life Sciences / Entomopathogenic nematodes (EPN) shows promise in being non-chemical and environmentally friendly solution for greenhouse pest and disease control. These can also be referred to as Biological Controls (Biocontrols). Entomopathogenic nematodes are used widely to control multiple greenhouse plant pests which include both Lycoriella spp., Fungus Gnats, and Frankliniella spp., Western Flower Thrips. However, there are challenges with EPN viability and storage from the manufacture to the greenhouse producer. We studied four EPN species, Steinernema feltiae, Steinernema carpocapsae, Heterorhabditis bacteriophora, Heterorhabditis indica, which were reared and stored to determine differences in production viability between species. Results show that the EPN species do not respond the same to storage and produce different amounts of infectious juveniles during rearing when conditions are the same. Separate from, but just as concerning as greenhouses plant pests are plant diseases. Ultraviolet radiation in the C spectra is known to be germicidal due to its narrow wavelengths. Because of this, UV-C has been shown to deactivate many different plant pathogens on contact and is being considered as a possible Biocontrol alternative to harsh traditional fungicides and bactericides. One disease that is known to contribute to the highest volume of annual crop losses is Botrytis cinerea. Botrytis cinerea is a plant disease that impacts floricultural crops to vegetables during propagation through the production supply chain to shipping and storage. We evaluated UV-C radiation at different doses, to determine if it could be used to replace a traditional fungicide before plants are shipped to reduce B. cinerea infection during transport. We found that UV-C successfully deactivated B. cinerea in vitro, but the viability of the application to plant tissue before transport has yet to be proven successful as a practical method of reducing B. cinerea during transport.

Steinernema feltiae

Steinernema carpocasae

Heterorhabditis bacteriophora

Heterorhabditis indica

infective juvenile

Fungus gnat

Western flower thrips

shore fly

Xenorhabdus

UV-C

Botrytis cinerea

Primula

poinsettia

Euphorbia

Impatiens Necrotic Spot Virus Resistance in Transgenic Impatiens walleriana and Lycopersicon esculentum

Sears, Vicki P.

29 January 2018

vegetable crops. Micro-Tom is a model tomato cultivar used for research due to its small size and short time to fruiting. This project evaluated I. walleriana and Micro-Tom transformed with Agrobacterium. The construct contained GFP (green fluorescent protein) and hygromycin antibiotic-resistant selectable markers, and the antisense sequence of open reading frame of INSV nucleocapsid protein (N). The N gene is expected to confer INSV resistance by RNA interference or gene silencing. The presence of transgenes was confirmed by PCR. Transgenic Impatiens was selfed for two generations. Transgenic Micro-Tom was selfed for 4 generations. Spinach was used as an INSV reservoir. Impatiens, spinach and Micro-Tom were mechanically inoculated with INSV and evaluated visually, with assay tests, ELISA testing, and PCR. Spinach was successfully infected with INSV six times of seven attempts. Impatiens and Micro-Tom had no successful inoculations of three and five attempts, respectively. / Master of Science

Impatiens walleriana

Impatiens Necrotic Spot Virus

INSV

Solanum lycopersicum

Micro-Tom

Spinacia oleracea

Spinach

Orthotospovirus

Tospoviridae

Frankliniella occidentalis

Western Flower Thrips

transformation

PCR