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1	Variations in cross-fertility in two xenogamous grasses, Bromus inermis Leyss and Phleum pratense L MacKay, Kenneth Hugh, January 1960 (has links) Thesis (Ph. D.)--University of Wisconsin--Madison, 1960. / Typescript. Vita. eContent provider-neutral record in process. Description based on print version record. Includes bibliographical references.
2	Bulk Hybridization of Smooth Bromegrass (Bromus Inermis) Domingo, Wayne E. 01 May 1940 (has links) Large populations of controlled hybrids are essential to the most rapid progress in many phases of plant breeding programs. Plant species vary in the ease with which they may be hybridized. Hand hybridization of forage grasses is usually slow and laborious, and the minuteness of the floral parts of most of the species which have perfect flowers renders their hybridization by hand especially difficult and tedious. This difficulty limits the use that forage grass breeders are making of the significant principles of hybridization and thereby retards progress in this phase of plant breeding. Any dependable, rapid technique of hybridization which would eliminate many of the present hand operations, that is "bulk" hybridization, would make possible more rapid progress in the breeding of forage grasses. The study herein reported was designed to estimate the feasibility of applying various methods of bulk emasculation and bulk pollination to forage grasses. In limiting the scope of the study, smooth bromegrass (Bromus inermis) was selected to receive the greatest attention because of its importance among forage grasses and the wide range of self-fertility among individual plants of the species, a characteristic which proved very helpful in the study. Bulk hybridization smooth bromegrass bromus inermis Agriculture
3	Smooth brome invasion influences nitrogen cycling and soil bacterial community structure in a fescue grassland 2013 May 1900 (has links) Exotic plant invasions represent a significant threat to the integrity of native grasslands. Across the Northern Great Plains, grasslands invaded by smooth brome (Bromus inermis Leyss) support lower plant diversity, potentially resulting in important consequences for ecosystem function. Previous research on smooth brome has primarily focused on aboveground changes in plant communities, but there is growing evidence that the soil ecosystem can be significantly altered with invasion. The two objectives of this thesis were to examine whether smooth brome invasion alters soil nitrogen cycling, and to determine if changes in plant community diversity or productivity influence soil bacterial communities. Relationships between smooth brome and the soil ecosystem were assessed using data collected from a Festuca hallii Vasey (Piper) (plains rough fescue) grassland located near Macrorie, SK. Gross rates of nitrogen cycling and community productivity from smooth brome invaded and native grassland sites were compared to determine the potential influence of smooth brome invasion on the soil nitrogen cycle. The relationship between increasing smooth brome abundance and soil bacterial structure and composition was also studied. Gross mineralization rates and total soil nitrogen were significantly higher in smooth brome-invaded areas relative to native grassland. Bacterial and archaeal amoA, used as indicators of ammonia-oxidizer population sizes, were altered by smooth brome cover. Higher gross mineralization rates were likely due to stimulated microbial activity caused by increased litter and root production in areas invaded by smooth brome. Smooth brome decreased plant species richness through increased litter production, but had the opposite effect on bacterial communities. Bacterial communities had higher species richness and evenness in soils invaded by smooth brome, and smooth brome invasion was also associated with bacteria important for soil nitrogen cycling. As bacteria dominate microbial biomass and are important for decomposition processes, a more even bacterial community may have supported increased mineralization rates in smooth brome-invaded soils. Specifically, a more even bacterial community may have increased mineralization rates through greater resource utilization and niche partitioning. The responses observed in these studies suggest that belowground changes with smooth brome invasion have the potential to have important consequences for ecosystem processes. Bromus inermis soil nitrogen cycling bacterial community fescue grassland
4	Feeding habits of the yellowtail flounder and production of its invertebrate prey on Georges Bank / Collie, Jeremy S. January 1900 (has links) Thesis (Ph. D.)--Massachusetts Institute of Technology and Woods Hole Oceanographic Institution, 1985. / Vita. "October 1985." Includes bibliographical references (p. 135-142).
5	Etude de nouveaux agents antipaludiques innovants : design, synthèse et bioactivité / New innovative antimalarial agents : design, study and bioactivity Pierrot, David 12 December 2014 (has links) La spéciophylline (ou Uncarine D) est une molécule extraite d’une plante africaine endémique Mitragyna inermis qui présente une activité antipaludique contre la souche chloroquinorésistante W2 de Plasmodium falciparum, un des parasites responsables du paludisme. Son mode d’action est encore inconnu et des quantités plus importantes de produit naturel sont nécessaires pour poursuivre les études d’activité biologiques. Ces quantités ne peuvent être fournies par extraction des feuilles de Mitragyna inermis. Les objectifs de ce travail ont été d’établir une méthodologie de synthèse énantiosélective du motif spiranique de la spéciophylline pour en réaliser la synthèse totale, d’étudier l’activité antiplasmodiale de sous-structures afin de déterminer le pharmacophore de la spéciophylline et de fournir des quantités suffisantes de spéciophylline pour continuer l’étude du mode d’action de cette molécule. / Speciophyllin (or Uncarine D) is a natural product extracted from the endemic African plant Mitragyna inermis. It is active against Plasmodium falciparum’s chloroquine-resistant strain W2 which is one of the malaria responsible parasites. Speciophyllin’s action pathway remains unknown and more important amounts that cannot be provided by plant extraction are required to go on with the biologic activity studies. The aims of this work were to develop an enantioselective synthetic methodology to access speciophyllin’s spiranic core to be able to achieve its total synthesis. Through substructures synthesis and antiplasmodial activity evaluation we could study speciophyllin’s pharmacophore. Spirooxindole Spéciophylline Uncarine D Chimie organique Chimie médicinale Paludisme Mitragyna inermis Synthèse totale Spirooxindole Speciophyllin Uncarine D Organic chemistry Medicinal chemistry Total synthesis Malaria Mitragyna inermis
6	Rough fescue (Festuca hallii) ecology and restoration in Central Alberta Desserud, Peggy Ann Unknown Date No description available. Festuca hallii ecology restoration Poa pratensis natural recovery arbuscular mycorrhizal fungi native hay state and transition Bromus inermis
7	Neoichnology of the Burrowing Spiders <i>Gorgyrella inermis</i> (Araneae: Mygalomorphae) and <i>Hogna lenta</i> (Araneae: Araneomorphae) Hils, John M. 24 September 2014 (has links) No description available. Paleontology Paleoecology Geology Animals Soil Sciences Neoichnology trace fossil spider Araneae Mygalomorphae Araneomorphae Gorgyrella inermis Hogna lenta continental ichnology Skolithos Macanopsis ichnology
8	Patterns and processes of exotic plant invasions in Riding Mountain National Park, Manitoba, Canada Otfinowski, Rafael 10 September 2008 (has links) Invasive exotic species threaten the biodiversity and function of native ecosystems. Existing models, attempting to predict and control successful invaders, often emphasize isolated stages of in their life history and fail to formalize interactions between exotic species and recipient environments. In order to elucidate key mechanisms in the success of select invaders, I investigated the role of dispersal, establishment, proliferation, and persistence in their threat to natural areas. Focusing on Riding Mountain National Park, Manitoba, Canada, I integrated the native climatic range and biological traits of 251 exotic vascular plants reported inside and outside the park. Based on their climatic range in Europe, 155 among 174 exotic plant species absent from the Park were predicted to establish within its boundaries; among these, 40 clonal perennials were considered the highest threat to the Park’s biodiversity. Focusing on smooth brome (Bromus inermis Leyss.), a Eurasian perennial, threatening the structure and function of native prairies throughout the Great Plains, I extended my research to investigate the role of dispersal, establishment, proliferation, and persistence in characterizing its threat to the endemic diversity of northern fescue prairies, protected within Riding Mountain National Park. Patterns of smooth brome invasions were contingent on the type of propagules dispersed. The shallow dispersal gradient of individual florets combined with the steeper gradient of panicles and spikelets suggested that smooth brome is capable of simultaneously invading along dense fronts as well as by establishing isolated foci. While low correlations between the number of dispersed seeds and their recruitment suggested post-dispersal transport, seedling establishment remained contingent on prairie diversity. Seedling biomass increased with declining plant diversity, however, its impact depended on the availability of soil nitrogen. As a result, disturbed areas, preserving the root function of native plants, resisted smooth brome establishment. Even though low nitrogen contributed to a decline in seedling biomass, physiological integration between ramets facilitated their vegetative proliferation in low resource environments. Despite its rapid establishment and proliferation, smooth brome productivity declined at the center of invading clones. Although field and greenhouse observations failed to implicate soilborne pathogens, reasons for the observed decline remain unresolved. My research demonstrates that while Riding Mountain National Park and other natural areas in western Canada will continue to be impacted by exotic plants, integrating key stages in their life history provides an important conceptual framework in predicting their threat to natural areas and prioritizing management. / October 2008 biological invasions risk analysis climate-matching model biological traits smooth brome Bromus inermis plant dispersal inverse power function spatial patterns disturbance invasion resistance community diversity clonal proliferation physiological integration soilborne pathogens negative feedback natural area northern fescue prairie
9	Patterns and processes of exotic plant invasions in Riding Mountain National Park, Manitoba, Canada Otfinowski, Rafael 10 September 2008 (has links) Invasive exotic species threaten the biodiversity and function of native ecosystems. Existing models, attempting to predict and control successful invaders, often emphasize isolated stages of in their life history and fail to formalize interactions between exotic species and recipient environments. In order to elucidate key mechanisms in the success of select invaders, I investigated the role of dispersal, establishment, proliferation, and persistence in their threat to natural areas. Focusing on Riding Mountain National Park, Manitoba, Canada, I integrated the native climatic range and biological traits of 251 exotic vascular plants reported inside and outside the park. Based on their climatic range in Europe, 155 among 174 exotic plant species absent from the Park were predicted to establish within its boundaries; among these, 40 clonal perennials were considered the highest threat to the Park’s biodiversity. Focusing on smooth brome (Bromus inermis Leyss.), a Eurasian perennial, threatening the structure and function of native prairies throughout the Great Plains, I extended my research to investigate the role of dispersal, establishment, proliferation, and persistence in characterizing its threat to the endemic diversity of northern fescue prairies, protected within Riding Mountain National Park. Patterns of smooth brome invasions were contingent on the type of propagules dispersed. The shallow dispersal gradient of individual florets combined with the steeper gradient of panicles and spikelets suggested that smooth brome is capable of simultaneously invading along dense fronts as well as by establishing isolated foci. While low correlations between the number of dispersed seeds and their recruitment suggested post-dispersal transport, seedling establishment remained contingent on prairie diversity. Seedling biomass increased with declining plant diversity, however, its impact depended on the availability of soil nitrogen. As a result, disturbed areas, preserving the root function of native plants, resisted smooth brome establishment. Even though low nitrogen contributed to a decline in seedling biomass, physiological integration between ramets facilitated their vegetative proliferation in low resource environments. Despite its rapid establishment and proliferation, smooth brome productivity declined at the center of invading clones. Although field and greenhouse observations failed to implicate soilborne pathogens, reasons for the observed decline remain unresolved. My research demonstrates that while Riding Mountain National Park and other natural areas in western Canada will continue to be impacted by exotic plants, integrating key stages in their life history provides an important conceptual framework in predicting their threat to natural areas and prioritizing management. biological invasions risk analysis climate-matching model biological traits smooth brome Bromus inermis plant dispersal inverse power function spatial patterns disturbance invasion resistance community diversity clonal proliferation physiological integration soilborne pathogens negative feedback natural area northern fescue prairie
10	Patterns and processes of exotic plant invasions in Riding Mountain National Park, Manitoba, Canada Otfinowski, Rafael 10 September 2008 (has links) Invasive exotic species threaten the biodiversity and function of native ecosystems. Existing models, attempting to predict and control successful invaders, often emphasize isolated stages of in their life history and fail to formalize interactions between exotic species and recipient environments. In order to elucidate key mechanisms in the success of select invaders, I investigated the role of dispersal, establishment, proliferation, and persistence in their threat to natural areas. Focusing on Riding Mountain National Park, Manitoba, Canada, I integrated the native climatic range and biological traits of 251 exotic vascular plants reported inside and outside the park. Based on their climatic range in Europe, 155 among 174 exotic plant species absent from the Park were predicted to establish within its boundaries; among these, 40 clonal perennials were considered the highest threat to the Park’s biodiversity. Focusing on smooth brome (Bromus inermis Leyss.), a Eurasian perennial, threatening the structure and function of native prairies throughout the Great Plains, I extended my research to investigate the role of dispersal, establishment, proliferation, and persistence in characterizing its threat to the endemic diversity of northern fescue prairies, protected within Riding Mountain National Park. Patterns of smooth brome invasions were contingent on the type of propagules dispersed. The shallow dispersal gradient of individual florets combined with the steeper gradient of panicles and spikelets suggested that smooth brome is capable of simultaneously invading along dense fronts as well as by establishing isolated foci. While low correlations between the number of dispersed seeds and their recruitment suggested post-dispersal transport, seedling establishment remained contingent on prairie diversity. Seedling biomass increased with declining plant diversity, however, its impact depended on the availability of soil nitrogen. As a result, disturbed areas, preserving the root function of native plants, resisted smooth brome establishment. Even though low nitrogen contributed to a decline in seedling biomass, physiological integration between ramets facilitated their vegetative proliferation in low resource environments. Despite its rapid establishment and proliferation, smooth brome productivity declined at the center of invading clones. Although field and greenhouse observations failed to implicate soilborne pathogens, reasons for the observed decline remain unresolved. My research demonstrates that while Riding Mountain National Park and other natural areas in western Canada will continue to be impacted by exotic plants, integrating key stages in their life history provides an important conceptual framework in predicting their threat to natural areas and prioritizing management. biological invasions risk analysis climate-matching model biological traits smooth brome Bromus inermis plant dispersal inverse power function spatial patterns disturbance invasion resistance community diversity clonal proliferation physiological integration soilborne pathogens negative feedback natural area northern fescue prairie

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