Global ETD Search

1	Assessment of Growth Response and Patterns of Biomass Allocation by Panicum hemitomon Schultes: Implications for Thick-mat Floating Marsh Creation and Restoration Mayence, C. Ellery 15 December 2007 (has links) I carried out several large, manipulative greenhouse and controlled-setting experiments to elucidate Panicum hemitomon growth response as influenced by environmental conditions associated with restoring thick-mat floating marsh. Initially, Panicum hemitomon growth response was assessed in conjunction with manipulated nutrient availability and hydrology. Next, I assessed Panicum hemitomon growth response in conjunction with a suite of substrate and mat or containment materials. Finally, I evaluated Panicum hemitomon growth response, as well as overall created floating marsh vegetated development, using both a multi-species planting approach and a suite of Panicum hemitomon establishment techniques. All partitions of Panicum hemitomon biomass (shoot, rhizome, and root material) were enhanced under nitrogen, and to a lesser extent, phosphorous enrichment. Saturated (not inundated) hydrologic conditions were most conducive for robust growth by all partitions of Panicum hemitomon biomass. Substrate and mat or containment materials had a significant effect on Panicum hemitomon vigor, with peat and peat-containing blended substrate materials being most conducive for vigorous Panicum hemitomon growth. Duralast coconut fiber was the most suitable mat or containment material based not only on measures of plant vigor, but also for reasons associated with strength and stability, as well as buoyancy. The combination of Panicum hemitomon and Ludwigia peploides was superior to any other multi-species treatment tested. Ludwigia peploides was highly resilient to transplanting, grew vigorously in a lateral fashion, produced significantly more biomass than any other secondary species, and enhanced overall mat buoyancy, all key metrics regarding successful floating marsh restoration. Equally as important, the large amount of biomass attained by Ludwigia peploides was not totally at the expense of vigorous Panicum hemitomon growth. With respect to establishment technique, the positive response of Panicum hemitomon rhizome growth to humic acid amendment warrants further study. This research generated data that not only advance the body of general ecological knowledge pertaining to Panicum hemitomon, the dominant macrophyte of thick-mat floating marsh, but equally as important, data that are likely to augment or enhance the creation and restoration of this important freshwater marsh type. Panicum hemitomon floating marsh biomass allocation multi-species approach
2	Experimental Assessment of Butomus Umbellatus L. Growth and Expansion Using a Mesocosm Approach Carter, Christian 15 August 2014 (has links) Over the last century, flowering rush (Butomus umbellatus L.: Butomaceae) has escaped its native Eurasian range and has become a problematic species in North America. As an aquatic invasive species, flowering rush has degraded native wetlands and has interfered with human water usage. Although experimental work has been done regarding the reproductive biology of the species, few empirical studies regarding the ecology of the species have been conducted. The research reported here demonstrates that flowering rush is capable of aggressive clonal growth and propagation, and can perform well along a depth gradient from zero to 132cm. Proper management and control of invasive species relies on sound ecological knowledge of the target species, and this work aims to help gather that information. root shoot ratio wetland vegetative propagule biomass allocation monoculture triploid
3	Competition mechanisms of native and exotic tree species Kawaletz, Heike 02 August 2013 (has links) Der Anteil an nicht-einheimischen Pflanzenarten (Neophyten), die durch menschlichen Einfluss in neue Gebiete eingebracht worden sind, hat in den letzten zwei Jahrhunderten deutlich zugenommen. Weltweit gefährdet die Invasion von Neophyten beträchtlich die einheimische Biodiversität und Ökosystemfunktionen. Verschiedene biologische Eigenschaften (z.B. hohe Zuwachsrate und schnelle Vermehrung) führen zu einer besseren Konkurrenzfähigkeit von invasiven Arten und verursachen Veränderungen in der natürlichen Artzusammensetzung. Eine genauere Erfassung der Eigenschaften, die Neophyten zu starken Konkurrenten machen, könnte dabei helfen pflanzliche Invasionen besser zu verstehen und zukünftig effektiver zu steuern. Topfversuche ermöglichen die Untersuchung von Pflanzeninteraktionen unter kontrollierten Bedingungen ohne den schwer kalkulierbaren Einfluss heterogener Umweltfaktoren. Allerdings führen die Langlebigkeit und die größeren Dimensionen von Baumindividuen zu mehr Problemen in Topfversuchen im Vergleich zur Untersuchung krautiger Pflanzen. Aus diesem Grund wurde im Rahmen eines Reviews Literatur ausgewertet, um einen Überblick über die praktische Durchführung von Topfversuchen, die sich ausschließlich mit Baumarten beschäftigen, zu geben. Es ist offensichtlich, dass der Vorteil von Topfversuchen zugleich auch einen Nachteil darstellt: Aufgrund der kontrollierten Bedingungen sind Topfversuche in ihrer Eignung natürliche Gegebenheiten zu imitieren immer eingeschränkt. Die Zuverlässigkeit von Topfversuchen bei der Vorhersage des Baumwachstums unter natürlichen Bedingungen ist daher problematisch. Eine Möglichkeit um die Übertragbarkeit von Topfversuchen zu verbessern, könnte die Durchführung zusätzlicher Felduntersuchungen sein. In einem Topfversuch wurden die, durch Unterschiede in der Wuchsrate, Biomasseproduktion und Biomasseverteilung bedingten, Konkurrenzmechanismen von zwei einheimischen (Quercus robur L., Carpinus betulus L.) und zwei nicht-einheimischen Baumarten untersucht (Prunus serotina Ehrh., Robinia pseudoacacia L.). Einjährige Jungpflanzen wurden verschiedenen intra- und interspezifischen Konkurrenzbedingungen ausgesetzt, mit oder ohne den Einfluss von Wurzelkonkurrenz. Um die Konkurrenzmechanismen genauer zu bestimmen, wurde zwischen Wurzel- und Sprosskonkurrenz unterschieden, indem entweder ober- oder unterirdische Plastiktrennwände in die Töpfe integriert wurden. Es wurde angenommen, dass die Gesamtbiomasseproduktion der Neophyten im Vergleich zur Biomasseproduktion der einheimischen Baumarten signifikant höher ist und dies zu einer Verringerung der Biomasse von Q. robur und C. betulus führt. Des Weiteren wurde der Einfluss der unterirdischen Konkurrenz auf das Wachstum und die Biomasseverteilung der einheimischen Arten gemäß der ‚balanced-growth hypothesis‘ untersucht. Unsere Ergebnisse bestätigen die Annahmen, dass die Biomasseproduktion der beiden Neophyten P. serotina und R. pseudoacacia signifikant höher ist und dies zu einem großen Konkurrenzvorteil und zu einer Biomassereduktion der beigemischten konkurrenzschwächeren einheimischen Arten führt. Der Konkurrenzdruck auf Q. robur und C. betulus wurde vor allem durch die Wurzelkonkurrenz der nicht-einheimischen Arten verursacht. Die Ausschaltung von unterirdischen Pflanzeninteraktionen durch Trennwände führte somit zu einem Anstieg der Biomasseproduktion der beiden einheimischen Arten. Demzufolge scheint sogar ein begrenztes Wurzelvolumen bessere Wachstumsbedingungen zu bieten als direkter Wurzelkontakt mit invasiven Konkurrenten. In Übereinstimmung mit der ‚balanced-growth hypothesis‘ reagieren Q. robur und C. betulus auf die starke unterirdische Konkurrenz durch die Neophyten, indem sie mehr Biomasse in Richtung der Wurzeln transportieren. Die verstärkte Investition der Pflanzen in die Wurzeln geht vor allem zu Lasten von Blatt- und Astbiomasse. Außerdem hat sich gezeigt, dass Artenmischungen aus einheimischen und nicht-einheimischen Bäumen mehr Biomasse produzieren, als man anhand des Wachstums dieser Arten in Monokulturen erwartet hätte. Im Vergleich zu Monokulturen oder Mischungen beider Neophyten war der Konkurrenzdruck für P. serotina und R. pseudoacacia in Mischungen mit den weniger produktiven einheimischen Baumarten geringer. Bei Betrachtung der beiden nicht-einheimischen Arten wird deutlich, dass P. serotina signifikant mehr Biomasse produziert. Trotzdem hat R. pseudoacacia aufgrund der starken Wurzelkonkurrenz einen negativen Einfluss auf die Biomasseproduktion von P. serotina. Wachsen die beiden konkurrenzstarken Neophyten zusammen in einem Topf, produzieren sie weniger Biomasse als in den entsprechenden Monokulturen. Es gibt Anzeichen dafür, dass die starke Konkurrenzfähigkeit der invasiven Neophyten oftmals zu Lasten ihrer Stresstoleranz geht. Damit einhergehend zeigten die beiden nicht-einheimischen Arten im Topfversuch eine höhere Mortalitätsrate: Vor allem P. serotina scheint zudem empfindlich gegenüber Schatten, Trockenheit und Überflutung zu sein. Möglicherweise könnte diese Schwachstelle der Neophyten genutzt werden, um eine weitere Ausbreitung einzudämmen. 570 pot experiment plant competition plant invasion biomass allocation Prunus serotina Robinia pseudoacacia Forstwirtschaft (PPN621305413)
4	Towards a better characterization of morphological plasticity and biomass partitioning of trees in structural dynamics of mangrove forests Olagoke, Adewole 15 March 2017 (has links) (PDF) Changing environmental conditions often impose stressful growing conditions in plant communities. Until now, morphological plasticity, i.e. polymorphic growth physiognomies of plants, has not been sufficiently studied as a pivotal strategy for the whole ecosystem adaptation to environmental stress. We consider mangrove ecosystems as suitable models to provide insights on this subject. In the thesis, I investigate the ecological significance of tree morphological plasticity in the structural development and the dynamics of mangrove forests. I conducted field experiments in two regions located on both sides of the Amazon River mouths i.e. in French Guiana and North Brazil. Forest inventories were carried out in contrasting mangrove stands in both regions. The thesis combines empirical analysis of field data, terrestrial laser scanning (TLS), and mechanistic, individual-based computer simulations. We published results that proved the TLS-based analysis of individual tree structure useful for a better knowledge on biomass allocation between trunk and branches in tall and large Avicennia germinans mangrove trees reaching 45 m high and 125 cm of trunk diameter. Combining structural descriptions of A. germinans trees found in both sites, I highlighted the site-specific differences in tree allometries. The study suggests that regional differences in mangrove tree structure and function could be captured through better description of crown metrics, and that selected indicators of local morphological plasticity and consequent stand structure could generate a plus-value in the understanding of mangrove stand dynamics across contrasting coastal environments. Beyond the extension of allometric models to large Avicennia trees, we proposed new biomass equations with improved predictive power when crown metrics is taken into account. Additionally, we developed a novel software tool, named Lollymangrove, based on the AMAPStudio suite of software, with the objective of maximizing the potential of further field descriptions and modeling works. Lollymangrove allows standardized forest data capture, 3D visualization of structural data, aboveground biomass computations from a configurable module and export formats for forest dynamics and remote sensing models. Simulation experiments were conducted by means of the spatially explicit, individual-based stand model BETTINA_IBM. This model describes the important mechanism of water uptake limited by salt stress, and revealed insights into the relation between environmental conditions, allometric variations and biomass partitioning of mangrove trees, and stand characteristics. The simulation results suggest close matches with observed ecological patterns (e.g., tree allometries, mortality distributions, and self-thinning trajectories) under higher salinity. In low salinity conditions, however, the current parameterization underestimates the maximum tree height and diameter, and consequently, aboveground biomass and self-thinning trajectories of forest stands. This suggests that the morphology of trees under low levels of salinity are explained by further regulation mechanism(s) that still need to be addressed in a subsequent model improvement. Overall, this work has essentially pointed out the need to elucidate how morphological plasticity relates with structural development of forest stands. It establishes that TLS measurements and structural data analysis associated to efforts for integrative software and mechanistic modelling works could link mangrove dynamics to fast-changing coastal processes. Plant plasticity Biomass allocation Tree allometry Forest structure Coastal dynamics Mechanistic ecological modelling Mangrove ecosystem ddc:630 rvk:ZC 74040
5	Ekologické rozdíly mezi bylinami a dřevinami a evoluce bylinnosti / Ecological differences between herbs and woody plants, and evolution of the herbaceous habit Klimeš, Adam January 2020 (has links) Ecological differences between herbs and woody plants, and evolution of the herbaceous habit Adam Klimeš, doctoral thesis Abstract Flowering plants (angiosperms), which make up most present-day vegetation, were originally woody. While flowering plants have repeatedly given rise to herbaceous lineages since their first appearance, we lack a clear explanation for these common evolutionary events. Freezing temperatures and drought periods have been proposed as factors which had caused huge success of the younger growth form but the evidence is very limited and not in favour of these hypotheses. In this thesis, we aimed to build the foundations of research on the evolution of herbs. We outlined new potential drivers of the evolution of herbs, suggested solutions to some methodological challenges and provided evidence about differences between herbs and woody plants relevant to the hypotheses on herb evolution. To this end, we used common garden experiments with young plants of both growth forms and global trait data from public databases which we evaluated using phylogenetic comparative techniques. Annuality of aboveground biomass and fast life-strategy of herbs are characteristics which differentiate them from woody plants and which in some conditions are expected to be behind their success. Apart from the...
6	Rozhodující fáze v semenném rozmnožování rostlin / Decisions in seed reproduction in plants Mašková, Tereza January 2019 (has links) Seed reproduction is a key part of the life cycle of the most plant species. It allows for the dispersal of species in space and time and, thus, significantly affects dynamics of plant populations and communities. Seed formation, germination and seedling establishment are subjected to selection pressures from the environment and lead to optimization of maternal investments (maternal care), manifested by the number of seeds and amount and composition of nutrients stored in individual seeds. The thesis aims to answer two questions: (i) whether maternal investments in terms of seed mass and seed nutrient stoichiometry is optimized according to the environmental conditions in which seedling development is expected and (ii) how nutrient availability, considering nutrients both stored in the seed by the mother plant and those available in the substrate, affects seedling growth and development. To answer the first question, we focused on interspecific comparisons of seed nutrient stoichiometry linking it with data on seed mass and species niche along gradients of nu- trient availability. We used a phylogenetically informed comparative approach to explore the ratio between phosphorus, nitrogen and nonstructural carbon in seeds from 510 wild herbaceous species. We analyzed seed nutrient stoichiometry with...
7	Modificações morfológicas e metabólicas em gramínea e leguminosa forrageiras tropicais relativas ao suprimento de enxofre / Metabolic and morphological changes in grass and legume tropical forages related to sulfur supply Schmidt, Fábiana 12 December 2012 (has links) O enxofre é um dos elementos essenciais para as plantas e as exigências nutricionais nesse nutriente variam com a espécie e a taxa de crescimento das plantas. Com o objetivo geral de avaliar o efeito da nutrição em enxofre no crescimento e no metabolismo do capimtanzânia (Panicum maximum cv. Tanzânia) e do estilosante (Stylosanthes guianensis cv. Mineirão) desenvolveu-se a presente pesquisa com os objetivos específicos de avaliar os efeitos do fornecimento de enxofre em: i) modificações morfológicas, produtivas e nutricionais ocorridas na parte aérea e nas raízes; ii) metabolismo do nitrogênio e as consequentes alterações na composição e concentrações de aminoácidos; iii) concentrações de enxofre total, enxofre-sulfato e glutationa e na atividade das enzimas glutationa redutase e glutationa sulfo-transferase nas folhas recém-expandidas e raízes; iv) crescimento, metabolismo da glutationa e atividade das enzimas envolvidas no ciclo ascorbato-glutationa e v) absorção de sulfato e a expressão de genes de transportadores de sulfato. Os experimentos foram conduzidos em casa de vegetação e camara de crescimento, empregando-se soluções nutritivas. As doses de enxofre aplicadas foram ajustadas de modo a permitir nutrição baixa, intermediária e alta em enxofre para cada espécie. O enxofre afetou diretamente na emissão de folhas e de perfilhos, área foliar, comprimento e superfície radicular do capim-tanzânia e do estilosante Mineirão, aumentando a produção de massa seca da parte aérea e das raízes. A baixa disponibilidade de enxofre ocasionou o desequilíbrio nutricional com o nitrogênio nas plantas, evidenciado por alta relação nitrogênio:enxofre e altas concentrações de nitrato e aminoácidos livres no tecido vegetal. Sob limitação de enxofre, o capim apresentou predomínio de asparagina na composição aminoacídica, enquanto no estilosante ocorreu a predominância de arginina. A aplicação de enxofre aumentou as concentrações de enxofre total, enxofre-sulfato e glutationa nas folhas diagnósticas e raízes para ambas as espécies forrageiras. As plantas crescidas sob limitação de enxofre apresentaram alta atividade da enzima glutationa redutase visando regenerar a glutationa reduzida, que atua protegendo as células contra danos oxidativos decorrentes do estresse da deficiência nutricional. O fornecimento de enxofre aumentou a atividade da glutationa sulfo-transferase incrementando a capacidade do vegetal de suportar estresses ambientais. A baixa disponibilidade de enxofre induziu o aumento da atividade de enzimas antioxidantes que atuam na regeneração da glutationa e do ascorbato na forma reduzida. As plantas crescidas em baixa disponibilidade de enxofre apresentaram aumento da concentração de glutationa e maior alocação desse composto nas raízes. A distribuição de glutationa das folhas para as raízes em condição de limitação de enxofre regula a absorção de sulfato no capim e no estilosante de modo diferenciado. Para o capim com alta concentração de glutationa nas raízes decresce o influxo total de 34S, enquanto para o estilosante não ocasiona a redução da absorção de sulfato. / Sulfur is an essential element required by plants and the nutritional requirements in this nutrient vary according to species and plant growth rate. This research had the main objective of evaluating the effect of sulfur nutrition on growth and metabolism of Guinea grass (Panicum maximum cv. Tanzânia) and stylo (Stylosanthes guianensis cv. Mineirão) and was developed with the specific objectives to determine the effects on i) morphological, productive and nutritional changes in plant shoots and roots, ii) nitrogen metabolism and the changes in the composition and concentrations of amino acids, iii) concentrations of total sulfur, sulfur-sulfate and glutathione and the activity of the enzymes glutathione reductase and glutathione sulfo-transferase in recently expanded leaves and roots, iv) growth, glutathione metabolism and activity of enzymes involved in ascorbate-glutathione cycle and v) sulfate uptake and expression of sulfur transporters genes. The experiments were carried out in greenhouse and growth chamber, by using nutrient solutions. Sulfur supply were adjusted to low, intermediate and high S nutrition for each species. Sulfur supply influences the emission of leaves, tillering, leaf area, root length and surface of Guinea grass and stylo increasing production of dry mass of aboveground and roots. Sulfur limitation alters the distribution of photosynthates between aboveground and roots of Guinea grass and stylo providing reduction in dry matter production of roots. The plants of Guinea grass increase root surface as a mechanism for adaptation to limited S in the culture medium. The relative chlorophyll index (RCI) in the recently expanded leaves relates to the production of dry mass of aboveground and can be used to assess S nutritional status in Guinea grass and stylo. The application of S proves necessary to increase production of dry mass in Guinea grass and stylo. Low S availability caused nutritional imbalance with N in Guinea grass and stylo plants, as shown by a high N:S ratio and high concentrations of N-nitrate and free amino acids in plant tissues. Among amino acids, asparagine predominated in S-limited guineagrass and arginine in Slimited stylo. Increased S supply regulates N:S ratio at values close to 20:1, which provides N and S concentrations that are more suitable for protein synthesis and forage production in plants of both species. Adding S increased concentrations of total S, S-sulfate, and glutathione in diagnostic leaves and roots of both species collected at the two harvests. Plants grown under S limitation showed high levels of GR activity, related to the regeneration of GSH, which acts to protect cells against oxidative damage caused by the stress of nutritional deficiency. S supply increased GST activity, and consequently plants\' capacity to withstand environmental stresses. Low S availability increased activity of the antioxidant enzymes that act in the regeneration of GSH and AsA. Plants grown with low S availability showed higher concentration of glutathione and greater allocation of glutathione to roots. For Guinea grass, high glutathione concentrations in roots decrease the 34S uptake. For stylo not cause reduction of 34S uptake. Amino acid composition Biomass allocation Biomassa Cycle ascorbate-glutathione Enxofre Forages production Forragem - Produção Glutathione Glutationa Gramíneas forrageiras Leguminosas forrageiras Nutrição vegetal Sulfate transporters Sulfur nutrition Tropical forages
8	Performance of slash pine (Pinus elliottii Engelm.) containerized rooted cuttings and bare-root seedlings established on five planting dates in the flatlands of western Louisiana Akgul, Alper 29 August 2005 (has links) The forest product industry is keenly interested in extending the normal planting season, as well as in the comparative field performance of standard nursery bare-root seedlings and containerized rooted cuttings. The effect of seasonal planting dates on survival, above and belowground biomass allocation, water relations, gas exchange attributes and foliar carbon isotope composition (δ13C) of two stock types of slash pine (Pinus elliottii Engelm.) were examined. Slash pine bare-root seedlings (BRS) and containerized rooted cuttings (CRC) were hand planted in September, November, January, March and April in three consecutive planting seasons (2000-2001, 2001-2002 and 2002-2003) on three sites with silt loam topsoils in southwestern Louisiana. First-year mean survival of CRC across all planting dates and sites was consistently high at 96 to 98%, whereas BRS survival was significantly (P < 0.0001) lower at 59 to 81% and highly variable among study sites and dates through three planting seasons. Generally, there was a negative relationship between soil moisture at the time of planting and first-year survival of BRS planted September through March in 2001-2002 and 2002-2003 planting seasons, whereas the opposite was observed only for BRS planted in April 2002 and 2003. Survival of CRC was affected very little by the variation in soil moisture. Containerized rooted cuttings had higher early above and belowground biomass, and height and diameter than did BRS. However, three years after planting the size differences between stock types disappeared or became negligible. Early size differences among trees planted September through March also decreased after three years, although September trees were tallest. Growth of the April-planted trees was poor compared to trees planted in other months. Late-planted April trees had higher δ13C values, and higher water-use efficiency in the first growing season compared to earlier planted trees. Differences in δ13C values among the planting dates disappeared in the second growing season. Net photosynthesis rates did not differ considerably between stock types or among planting dates in the second and third growing seasons. This study indicates that it is possible to extend the planting season to as early as September and as late as March by using CRC. Slash pine planting season soil moisture bare-root seedlings containerized rooted cuttings survival growth water relations gas exchange photosynthesis stomatal conductance carbon isotope discrimination above and belowground biomass allocation
9	Performance of slash pine (Pinus elliottii Engelm.) containerized rooted cuttings and bare-root seedlings established on five planting dates in the flatlands of western Louisiana Akgul, Alper 29 August 2005 (has links) The forest product industry is keenly interested in extending the normal planting season, as well as in the comparative field performance of standard nursery bare-root seedlings and containerized rooted cuttings. The effect of seasonal planting dates on survival, above and belowground biomass allocation, water relations, gas exchange attributes and foliar carbon isotope composition (δ13C) of two stock types of slash pine (Pinus elliottii Engelm.) were examined. Slash pine bare-root seedlings (BRS) and containerized rooted cuttings (CRC) were hand planted in September, November, January, March and April in three consecutive planting seasons (2000-2001, 2001-2002 and 2002-2003) on three sites with silt loam topsoils in southwestern Louisiana. First-year mean survival of CRC across all planting dates and sites was consistently high at 96 to 98%, whereas BRS survival was significantly (P < 0.0001) lower at 59 to 81% and highly variable among study sites and dates through three planting seasons. Generally, there was a negative relationship between soil moisture at the time of planting and first-year survival of BRS planted September through March in 2001-2002 and 2002-2003 planting seasons, whereas the opposite was observed only for BRS planted in April 2002 and 2003. Survival of CRC was affected very little by the variation in soil moisture. Containerized rooted cuttings had higher early above and belowground biomass, and height and diameter than did BRS. However, three years after planting the size differences between stock types disappeared or became negligible. Early size differences among trees planted September through March also decreased after three years, although September trees were tallest. Growth of the April-planted trees was poor compared to trees planted in other months. Late-planted April trees had higher δ13C values, and higher water-use efficiency in the first growing season compared to earlier planted trees. Differences in δ13C values among the planting dates disappeared in the second growing season. Net photosynthesis rates did not differ considerably between stock types or among planting dates in the second and third growing seasons. This study indicates that it is possible to extend the planting season to as early as September and as late as March by using CRC. Slash pine planting season soil moisture bare-root seedlings containerized rooted cuttings survival growth water relations gas exchange photosynthesis stomatal conductance carbon isotope discrimination above and belowground biomass allocation
10	Strategies in aboveground space occupancy in herbs from disturbed habitats / Strategies in aboveground space occupancy in herbs from disturbed habitats BARTUŠKOVÁ, Alena January 2012 (has links) Disturbance is an important phenomenon affecting plant lives and shaping plant strategies in disturbed habitats. A variety of ecological concepts on individual plant response to injury has been proposed for specific natural ecosystems or growth forms. In central Europe, man-made habitats are often cases of disturbed places, so the aim of the thesis was to apply four chosen concepts on them. The thesis is composed of four original studies performed in two model ecosystems: recurrently disturbed ruderal place and regularly mown central European meadow. The occupying of the aboveground space after a disturbance event was studied here either as renovation of biomass or architecture. Regenerative strategies in herbs occupying disturbed habitats were described and confronted with concepts proposed originally for ecosystems subjected to natural disturbance regimes.

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