Long-term development of subalpine lakes : effects of nutrients, climate and hydrological variability as assessed by biological and geochemical sediment proxies

Milan, Manuela

January 2016

Sediment records of two Italian subalpine lakes (Lake Garda and Lake Ledro) were analyzed in order to reconstruct their ecological evolution over the past several hundred years. A multi-proxy and multi-site approach was applied in order to disentangle the effects of local anthropogenic forcings, such as nutrients, and climate impacts on the two lakes and their catchments. Biological indicators (sub-fossil pigments, diatoms and Cladocera) were used to reconstruct changes in the aquatic food web and to define the lake reference conditions, while geochemical methods, i.e. wavelength-dispersive X-ray fluorescence spectroscopy (WD-XRF), were used to provide quantitative information on the different physical or chemical processes affecting both lake and catchment systems. Sub-fossil pigments and diatoms, together with their respective inferred TP values, suggested very stable oligotrophic conditions in both lakes until the 1960s. The period following was affected by nutrient enrichment, which led to a drastic shift in the phytoplanktonic community. The response of sub-fossil pigments and diatoms to major climatic anomalies such as the Medieval Climatic Anomaly (MCA) and the Little Ice Age (LIA) were not pronounced, and the taxonomic composition remained relatively stable. On the contrary, these proxies showed an indirect response to climate variability since the beginning of the nutrient enrichment phase in the 1960s. In Lake Garda, the winter temperature regulates the water column mixing, which in its turn controls the degree of nutrient fertilization of the entire water column, and the related phytoplankton growth. In Lake Ledro a rapid reorganization of planktonic diatoms was observed only during the temperature recovery after the LIA, while recent temperature effects are masked by the prevailing nutrient effects. In Lake Garda, Cladocera remains responded in quantitative and qualitative terms to climatic changes, whereas in Lake Ledro they appeared to be mainly affected by variations in hydrological regimes, i.e. flood events. Cladocera remains corroborated the nutrient enrichment after the 1960s in both lakes as inferred by diatoms and pigments. In Lake Garda, the geochemical data showed a pronounced shift in elemental composition since the mid-1900s, when major elements and lithogenic tracers started to decrease, while some elements related to redox conditions and other (contaminant) trace elements increased. The general trends since the mid-1900s agree with the biological records. However, some differences recorded in the two different basins of Lake Garda reflected the effects of local conditions, both related to hydrology and sedimentation patterns. Lake Ledro showed higher short-term variability for most elements, even though some features were comparable to Lake Garda. The geochemical record of Lake Ledro revealed a major influence of human-induced lake-level fluctuations and catchment properties. This paleolimnological study allows us to place temporally restricted limnological surveys into a longer-term secular perspective, which is highly valuable for the definition of lake reference conditions. Because the restoration targets are usually based on the lake reference conditions, this study highlighted also the necessity to pay particular attention to the lake-specific sensitivity patterns. The multi-proxy and multi-site approach showed that the lake conditions of large and deep lakes in northern Italy, such as Lake Garda, are mainly driven by nutrient enrichment and/or climate change. In contrast, smaller lakes with larger catchment areas, such as Lake Ledro, are seemingly more impacted by conditions and processes occurring in the drainage basin.

Paleolimnology

diatoms

Cladocera

sub-fossil pigments

geochemistry

Lake Garda

Lake Ledro

reference conditions

nutrient enrichment

climate change

hydrological regime.

Interactions between ecosystems and disease in the plankton of freshwater lakes

Penczykowski, Rachel M.

13 January 2014

I investigated effects of environmental change on disease, and effects of disease on ecosystems, using a freshwater zooplankton host and its fungal parasite. This research involved lake surveys, manipulative experiments, and mathematical models. My results indicate that ecosystem characteristics such as habitat structure, nutrient availability, and quality of a host’s resources (here, phytoplankton) can affect the spread of disease. For example, a survey of epidemics in lakes revealed direct and indirect links between habitat structure and epidemic size, where indirect connections were mediated by non-host species. Then, in a mesocosm experiment in a lake, manipulations of habitat structure and nutrient availability interactively affected the spread of disease, and nutrient enrichment increased densities of infected hosts. In a separate laboratory experiment, poor quality resources were shown to decrease parasite transmission rate by altering host foraging behavior. My experimental results also suggest that disease can affect ecosystems through effects on host densities and host traits. In the mesocosm experiment, the parasite indirectly increased abundance of algal resources by decreasing densities of the zooplankton host. Disease in the experimental zooplankton populations also impacted nutrient stoichiometry of algae, which could entail a parasite-mediated shift in food quality for grazers such as the host. Additionally, I showed that infection dramatically reduces host feeding rate, and used a dynamic epidemiological model to illustrate how this parasite-mediated trait change could affect densities of resources and hosts, as well as the spread of disease. I discuss the implications of these ecosystem–disease interactions in light of ongoing changes to habitat and nutrient regimes in freshwater ecosystems.

Daphnia

Epidemiology

Eutrophication

Foraging behavior

Fungal pathogen

Habitat structure

Host-parasite

Nutrient enrichment

Zooplankton

Epidemiology Research

Marine ecosystem health

Marine ecology

Plankton

Freshwater plankton

?Efeitos da til?pia do Nilo (Oreochromis niloticus) e do enriquecimento por nutrientes sobre a comunidade planct?nica em um lago artificial no semi-?rido brasileiro

Menezes, Rosemberg Fernandes de

02 June 2008

Made available in DSpace on 2014-12-17T14:01:57Z (GMT). No. of bitstreams: 1 RosembergFM.pdf: 688143 bytes, checksum: b1661c0d65a3b582ed47216926346188 (MD5) Previous issue date: 2008-06-02 / Coordena??o de Aperfei?oamento de Pessoal de N?vel Superior / ?The major aim of this study was to test the hypothesis that the introduction of the Nile tilapia (Oreochromis niloticus) and the enrichment with nutrients (N and P) interact synergistically to change the structure of plankton communities, increase phytoplankton biomass and decrease water transparency of a semi-arid tropical reservoir. One field experiment was performed during five weeks in twenty enclosures (8m3) to where four treatments were randomly allocated: with tilapia addition (T), with nutrients addition (NP), with tilapia and nutrients addition (T+NP) and a control treatment with no tilapia or nutrients addition (C). A two-way repeated measures ANOVA was done to test for time (t), tilapia (T) and nutrient (NP) effects and their interaction on water transparency, total phosphorus, total nitrogen, phytoplankton and zooplankton. The results show that there was no effect of nutrient addition on these variables but significant fish effects on the biomass of total zooplankton, nauplii, rotifers, cladocerans and calanoid copepods, on the biovolume of Bacillariophyta, Zygnemaphyceae and large algae (GALD ? 50 ?m) and on Secchi depth. In addition, we found significant interaction effects between tilapia and nutrients on Secchi depth and rotifers. Overall, tilapia decreased the biomass of most zooplankton taxa and large algae (diatoms) and decreased the water transparency while nutrient enrichment increased the biomass of zooplankton (rotifers) but only in the absence of tilapia. In conclusion, the influence of fish on the reservoir plankton community and water transparency was greater than that of nutrient loading. This finding suggests that biomanipulation should be a greater priority in the restoration of eutrophic reservoirs in tropical semi-arid regions / ?O principal objetivo deste estudo foi testar a hip?tese de que a introdu??o da til?pia do Nilo (Oreochromis niloticus) e o enriquecimento por nutrientes (N e P) interagem sinergicamente ocasionando mudan?as na estrutura da comunidade planct?nica atrav?s do aumento da biomassa fitoplanct?nica e diminui??o da transpar?ncia da ?gua em um reservat?rio tropical do semi-?rido. Um experimento de campo foi realizado durante cinco semanas em vinte mesocosmos (8m3) nos quais quatro tratamentos foram alocados aleatoriamente: com adi??o de til?pia (T), com adi??o de nutrientes (NP), com adi??o de til?pia e nutrientes (T+NP) e um tratamento controle sem adi??o de til?pia ou nutrientes (C). Uma ANOVA bifatorial com medidas repetidas foi realizada para testar os efeitos do tempo, da til?pia (T) e dos nutrientes (NP) e seus efeitos de intera??o sobre a transpar?ncia da ?gua, f?sforo total, fitopl?ncton e zoopl?ncton. Os resultados mostraram que n?o houve efeito da adi??o de nutrientes sobre essas vari?veis mas houve um efeito significativo dos peixes sobre a biomassa do zoopl?ncton total, n?uplios, rot?feros, clad?ceros e cop?podos calan?ides, sobre o biovolume de Bacillariophyta, Zygnemaphyceae e algas de grande porte (GALD ? 50?m) e sobre a profundidade do disco de Secchi. Al?m disso, foi encontrado um efeito significativo da intera??o entre as til?pias e nutrientes sobre a profundidade do disco de Secchi e tamb?m sobre a biomassa de rot?feros. As til?pias diminu?ram a biomassa da maioria dos taxa zooplanct?nicos, das algas de grande porte e diminu?ram a transpar?ncia da ?gua, enquanto que o enriquecimento por nutrientes aumentou a biomassa do zoopl?ncton (rotiferos) mas somente na aus?ncia das til?pias. Portanto podemos concluir que a influ?ncia dos peixes sobre a comunidade planct?nica do reservat?rio e a transpar?ncia da ?gua foi maior do que o aporte por nutrientes, sugerindo assim que a biomanipula??o deve ter maior prioridade na restaura??o de reservat?rios eutrofizados em regi?es semi-?ridas tropicais

Enriquecimento por nutrientes

Onivoria

Mesocosmos

Oreochromis niloticus

Cascatas tr?ficas

?

Nutrient enrichment

Omnivory

Mesocosms

Oreochromis niloticus

Trophic cascades

Maintaining a Nitrogen Cap for Virginia's Potomac River: The Contribution of Alternative Development Patterns

Doley, Todd Michael

05 February 1999

The Chesapeake Bay, once one of the worlds most productive estuaries, has been severely impacted by human activity in the water and on the lands around it. Viewed as an ecosystem, the Bay is no longer able to support the variety and abundance of biota that it was historically able to. Several decades of research on the Chesapeake have pointed to human activities as being the principle reason for this decline. Of these detrimental activities, elevated inputs of Nitrogen and Phosphorus to the Bay were singled out as being the greatest cause of water quality deterioration. The state of Virginia is trying to reduce its annual load of Nitrogen, to the Potomac River, to 60% of what the load was estimated to be in 1985. Virginia would like to accomplish this goal at the lowest cost to its citizens. Therefore the state needs to determine the combination of nitrogen control efforts which will achieve the goal at the lowest cost. The state would also like to be able to maintain nitrogen loads at or below this cap level, indefinitely into the future. This study was undertaken with three primary objectives. The first was to project the level of annual nitrogen inputs to the Potomac River, from the state of Virginia, over the next 15 years. The second was to estimate the minimum annual costs necessary to achieve and maintain a 40% reduction in total nitrogen inputs, using the Virginia's estimated 1985 inputs as a baseline. The final objective was to assess the potential cost savings that may result from using one of two alternative development patterns within the rapidly urbanizing Northern Virginia portion of the Potomac Watershed. The first alternative is prohibiting low-density development within the Northern Virginia region, and the second is to restrict all new development to be within 5 miles of an existing urban area. Study results suggest that there has been no significant progress toward meeting the nitrogen reduction goal, due to the increase in population within the watershed, over the past 13 years. To attain the goal in 1998, a minimum of $27 million, above what is currently being spent annually, would be required. Under the current land use trend within Virginia's Potomac Basin, the annual cost for maintaining the goal is estimated to rise to $38 million annually, in 1998 dollars, by the year 2013. This is a 40% increase in cost. If the first alternative development pattern is adhered to over this 15-year period, then the annual cost will be $33 million, for an annual cost saving of approximately $5 million in 2013. The second alternative could achieve similar results if implemented, costing roughly $5 million less in 2013 than the annual cost per year under the current trend. These findings suggest that the use of alternative development patterns can help slow but not prevent the annual cost, of maintaining the cap, from rising. The study indicates that the reason for the continuous rise in annual cost, over this fifteen-year period, is due primarily to an increase in nitrogen loading to the Potomac that will result from the wastewater disposal needs of the growing population within the Basin. Furthermore, the state will eventually exhaust its lower cost options for reducing Nitrogen loadings, and at that point the annual cost for maintaining the Nitrogen Cap will begin to rise exponentially. Under current land use trends this rapid rise in cost is unlikely to occur within the next 15 years, and is more apt to occur sometime within the next 20 to 40 years. Once annual expenditures begin to rise exponentially it is unlikely that the state of Virginia would be able to maintain its 40% reduction goal. / Master of Science

Potomac River

Nutrient Enrichment

Watershed

Northern Virginia

Tributary Strategy

Chesapeake Bay

Land Use

Shenandoah

Sprawl

Water Quality

Best Management Practice

Alternative Development Patterns

Cost-Effectiveness

Community assembly mechanisms in river networks:exploring the effect of connectivity and disturbances on the assembly of stream communities

Sarremejane, R. (Romain)

17 April 2018

Abstract Community assembly results from a combination of deterministic and stochastic mechanisms, whose relative effects can vary in response to environmental heterogeneity, connectivity, disturbance regimes and anthropogenic stressors. Understanding how community assembly mechanisms vary in response to environmental changes and connectivity is crucial for the management and conservation of river ecosystems. In this thesis, I tested the effects of connectivity and natural flow disturbances on riverine invertebrate communities by assessing assembly mechanism changes in response to (I) habitat connectivity, (II) seasonal flow intermittency and (III) inter–annual hydrological variability. I also conducted a field experiment to test for (IV) the effects of human–induced nutrient enrichment on community assembly of microorganisms (diatoms and aquatic fungi) and stream ecosystem functioning under different environmental settings. Invertebrate community assembly changed gradually with habitat connectivity. While limited dispersal resulted in higher community variability in the most isolated streams, mass effects caused community homogenization in the most connected ones. Natural and human induced disturbances lead to changes in the relative importance of deterministic and stochastic factors but often through different, or even opposite, mechanisms depending on the natural background of the ecosystem and organism type considered. For instance, seasonal drying and high–flow periods in intermittent Mediterranean rivers promoted deterministic and stochastic assembly processes respectively, whereas environmental sorting and stochastic processes respectively dominated during high and low flow years in boreal streams. Diatom and fungal communities responded differently to nutrient enrichment, with detrital processes and fungal communities responding more in naturally acidic than in circumneutral streams. The results of this thesis highlight the complexity of community assembly mechanisms: they tend to be highly context dependent and temporally variable. Therefore, stream bioassessment and conservation will benefit from explicitly incorporating connectivity and natural disturbance regimes. Assessing the interactive effects of connectivity and disturbances at the river network scale would provide a greater understanding of community assembly mechanisms and river ecosystem functioning. / Tiivistelmä Eliöyhteisöjen koostumus heijastelee determinististen ja stokastisten mekanismien vuorovaikutusta. Niiden suhteellinen merkitys vaihtelee suhteessa yhteisöjen kytkeytyneisyyteen sekä luontaisiin ja ihmisen aiheuttamiin häiriöihin. Yhteisöjen säätelymekanismit vaihtelevat jokiverkoston eri osissa ja tietoa tästä vaihtelusta tarvitaan jokiekosysteemien hoidon kehittämiseksi. Tässä tutkielmassa testasin elinympäristöjen kytkeytyneisyyden ja luontaisten häiriöiden (virtaamavaihtelut) vaikutuksia jokien selkärangatonyhteisöihin. Suoritin myös kenttäkokeen, jossa testattiin ihmisen aiheuttaman rehevöitymisen vaikutuksia mikro–organismeihin (piilevät, mikrobit) ja ekosysteemitoimintoihin erilaisissa ympäristöoloissa (luontaisesti happamat vs. neutraalit purot). Selkärangattomien yhteisökoostumus muuttui asteittain jokiverkostossa. Yhteisökoostumuksen vaihtelu oli suurinta eristäytyneimmissä latvapuroissa, kun taas isommissa, uomaston keskivaiheilla sijaitsevissa koskissa voimakas levittäytyminen eri suunnista (ns. massatekijät) aiheutti yhteisöjen rakenteen homogenisoitumista. Kuivuusjaksot ja niitä seuraavat korkean virtaaman jaksot edistivät determinististen prosessien merkitystä Välimeren alueen joissa, kun taas boreaalisissa puroissa Pohjois–Suomessa äärevät virtaamaolot, erityisesti poikkeuksellisen kuivat kesät, edistivät satunnaismekanismien vaikutusta. Perustuottajat (piilevät) ja hajottajat (akvaattiset sienet) vastasivat eri tavoin ravinnelisäykseen. Sienten hajotustoiminta nopeutui ravinnelisäyksen myötä, mutta vain luontaisesti happamissa puroissa. Tämän opinnäytetyön tulokset korostavat yhteisön kokoonpanomekanismien monimutkaisuutta: ne ovat usein erittäin tilanneriippuvaisia ja ajallisesti vaihtelevia. Siksi jokien ekologisen tilan arvioinnissa tulisi huomioida tutkimuspaikkojen kytkeytyneisyys jokimaisemassa.

Mediterranean rivers

aquatic fungi

boreal streams

decomposition

diatoms

dispersal

hydrological variability

intermittent rivers

macroinvertebrates

metacommunity

microbial communities

nutrient enrichment

temporal change

ajallinen muutos

ajoittainen kuivuminen

akvaattiset sienet

hajoaminen

hydrologinen vaihtelu

metayhteisö

piilevät

rehevöityminen

vesiselkärangattomat

Ecological gradients caused by land-use change and land management alter soil microbial biomass and community functioning in a tropical mountain rainforest region of southern Ecuador

Tischer, Alexander

11 January 2016

Global change phenomena, such as forest disturbance and land-use change significantly affect elemental balances as well as the structure and function of terrestrial ecosystems. Inappropriate land management often causes nutrient losses and finally soil degradation and loss of soil functioning. Especially in tropical ecoregions, soil degradation by nutrient losses is widely abundant. Soil microorganisms are the proximate agents of many processes performed in soils and are regarded as sensitive bio-indicators. However, the incorporation of microbial responses to the definition of critical soil conditions is not intensively developed. In the present thesis, several data analyses of the relationships between ecosystem disturbance and land-use change (natural forest, pastures of different ages, secondary succession) and a diverse set of soil ecological characteristics in the tropical mountain rainforest region of southern Ecuador were compiled. In particular, it was tested whether soil microbial biomass and community functioning were sensitive to land-use change effects. Furthermore, an information-theoretic approach was applied to find the factors that regulate soil microbial biomass and community function. Finally, in a nutrient enrichment experiment the above- and belowground responses to N and P additions were examined. The tested research questions and results were linked to the theory of ecological stoichiometry in order to connect the research to a sound and unifying scientific basis. Soil and microbial stoichiometry were affected by both land-use change and soil depth. After forest disturbance, significant decreases of soil C:N:P ratios at the pastures were fol-lowed by increases during secondary succession. Microbial C:N ratios varied slightly in response to land-use change, whereas no fixed microbial C:P and N:P ratios were observed. Shifts in microbial community composition were associated with soil and microbial stoichiometry. Strong positive relationships between PLFA-markers 18:2n6,9c (saprotrophic fungi) and 20:4 (animals) and negative associations between 20:4 and microbial N:P point to land-use change affecting the structure of soil food webs. Significant deviations from global soil and microbial C:N:P ratios indicated a major force of land-use change to alter stoichiometric relationships and to structure biological systems. Data analysis reveals a strong impact of land-use change on soil microbial biomass, C-mineralization, gross-NH4-consumption and –production rates. According to the results of the IT-approach, combined models better describe effects of land-use change on soil microorganisms than single explanation models. Microbial resources and soil chemical environment were important pre-dictors for soil microbial biomass and community functioning. Little is known about the environmental drivers of the catalytic properties of EHEs (e.g., pH, nutrients) and their functional link to the structure of soil microbial communities. The activities of the six hydrolytic enzymes were tested. Microbial production of AP responded to the low P status of the sites by a higher investment in the acquisition of P compared to C. Three major drivers of enzyme activities were found to be significant for enzyme production: 1.) Microbial demand for P regulated the production of AP, provided that N and C were available. At the natural forest site the two-fold higher specific activity of AP pointed to a high microbial P-demand, whereas the production of AP was constrained by the availability of N and DOC after pasture abandonment. 2.) Microbial biomass that was controlled by pH and resource availability was the main driver for CBH, BG and NAG activities. 3.) Substrate induction due to increased litter inputs of herbaceous plant species seemed to regulate AG and XYL activities during secondary succession. The enzymes’ affinity to substrate, as a potentially critically enzyme kinetic parameter is understudied. The data analysis suggests that microbial communities adapted to environmental changes, demonstrated high flexibility of extracellular enzyme systems and selected for enzymes with higher catalytic efficiency compared with pure cultures. Under in situ conditions, enzyme-specific environmental drivers of the Km, e.g., the pH for XYL, the C:N ratio for AP, and the C availability for NAG were found. The data demonstrated that the higher substrate affinity of XYL and AP was associated with more abundance of Gram(-) bacteria. The catalytic efficiency of enzymes decomposing cellulose, hemicellulose, and starch positively correlated with the relative abundance of Gram(-) bacteria. The turnover rate of the tested substrates was three to four times faster at the young pasture site compared with the longterm pasture and secondary succession sites. Nutrient inputs by atmospheric deposition are known to affect terrestrial ecosystems. However, little is known about how N and P co-limited ecosystems respond to single nutrient enrichment. In this work the susceptibility of above- and belowground ecosystem compo-nents and of their linkages in an N and P co-limited pasture to N- and P-enrichment was assessed. It was tested if the plants´responses can be explained by the concept of serially linked nutrients introduced by Ågren (2004). In this concept, the control of the growth rate by one nutrient is assumed to depend on the control of a different cellular process by another nutrient. The responses of shoot and root biomass and C:N:P stoichiometry of the grass Setaria sphacelata (Schumach.) to moderate N, P, and N+P application over five years were investigated. In addition, the effects of nutrient enrichment on soil nutrient pools, on arbuscular mycorrhizal fungi (AMF) as well as on microbial biomass, activity, and community structure were tested. In order to evaluate the importance of different factors explaining microbial responses, a likelihood-based information-theoretic approach was applied. The application of N+P increased aboveground grass biomass. Root biomass was stimulated by P-treatment. Grass C:N:P stoichiometry responded by altering the P-uptake or by translocating P from shoot to root. In particular, root C:N and C:P stoichiometry decreased in P- and in N-treatment. Extractable fractions of soil C, N, and P were significantly affected by nutrient enrichment. P application increased the biomass of Gram-positive bacteria and the abundance of AMF, however, results of the IT-approach suggested indirect effects of nutrient enrichment on microbes. The responses of the N and P co-limited pasture to particular nutrient enrichment support the concept of serially linked nutrients. The present study provides evidence for the fundamental importance of P for controlling resource allocation of plants in responses to nutrient enrichment. Resource allocation of the grass rather than direct effects of nutrient additions drives changes in AMF, microbial biomass, community structure, and activity. / Seit dem Übergang vom Holozän zum Anthropozän greift der Mensch immer stärker in globale und regionale Stoffkreisläufe ein. Durch die Zerstörung von Naturwäldern und Landnutzungswandel werden die Strukturen und die Funktionen der Ökosysteme stark verändert. Unangepasste Landnutzung führt zu Nährelementverlusten, die mittel- bis langfristige zur Bodendegradation und zur Reduktion von Bodenfunktionen führen. Solche Veränderungen sind insbesondere in den Tropen zu beobachten. Bodenmikroorganismen spielen in den Stoffkreisläufen eine zentrale Rolle. Zudem sind sie sensitive Bioindikatoren für den Zustand von Ökosystemen. Im Gegensatz dazu, werden die Bodenmikroorganismen noch nicht ausreichend für die Zustandsbewertung von Ökosystemen verwendet. In der vorliegenden Dissertation werden verschiedene Datenanalysen zu den Beziehungen von Landnutzungswandel (Naturwald, Weiden verschiedener Alter, sekundäre Sukzession) und den Eigenschaften der Bodenmikroorganismen in einer tropischen Bergregenwaldregion Süd-Ecuadors zusammengefasst. Ein besonderer Fokus lag darauf zu prüfen, ob die mikrobielle Biomasse und die Funktionen die von der mikrobiellen Gemeinschaft geleistet werden (z.B. Enzymaktivitäten) durch den Landnutzungswandel beeinflusst werden. Ein informations-theoretischer Ansatz wurde verwendet um verschiedene Erklärungsansätze der steuernden Faktoren vergleichend zu testen. Darüber hinaus wurden in einem Weidedüngungsexperiment die Reaktionen der ober- und der unterirdischen Ökosystemkomponenten auf die Anreicherung mit N und P getestet. Um die Ergebnisse auf eine breite wissenschaftliche Basis zu stellen wurde die Untersuchungen in den Kontext der Theorie die Ökologischen Stöchiometrie eingeordnet. Die C:N:P Stöchiometrie im Boden und in den Mikroorganismen veränderte sich durch den Landnutzungswandel und mit der Bodentiefe. Mit der Weideetablierung nahmen die C:N:P Verhältnisse im Boden deutlich ab, stiegen dann nach dem Verlassen der Weiden im Zuge der sekundären Sukzession wieder an. Das mikrobielle C:N Verhältnis variierte nur leicht, dagegen zeigten das C:P und N:P Verhältnis deutliche Veränderungen durch den Landnutzungswandel. Mit diesen Veränderungen in der Boden- und Organismenstöchiometrie waren auch Veränderungen in der Struktur der mikrobiellen Gemeinschaften verbunden. Deutliche positive Beziehungen existierten zwischen den saprotrophen Pilzen und den Protozoen. Die steigenden Mengen von Protozoen waren wiederrum mit sinkendem mikrobiellen N:P verbunden. Diese Muster weisen auf Veränderungen in den Bodennahrungsnetzten durch Landnutzungsänderungen hin. Sehr deutliche Abweichungen von globalen Mustern der C:N:P Stöchiometrie deuten darauf hin, dass der Landnutzungswandel signifikanten Einfluss auf die C:N:P Stöchiometrie ausübt. Der Landnutzungswandel beeinflusste auch die mikrobielle Biomasse, die Basalatmung, sowie die mikrobielle Aufnahme und Produktion von NH4-N im Boden. Dabei zeigten kombinierte Erklärungsansätze die adäquateren Beschreibungen der Muster. In den kombinierten Modellen zur Erklärung der mikrobiellen Biomasse und der mikrobiellen Leistungen überwogen Prädiktoren der mikrobiellen Ressourcen und der bodenchemischen Umwelt. Ein weiterer Schwerpunkt der Untersuchungen lag auf der Erfassung der Effekte des Land-nutzungswandels auf die Aktivität von extrazellulären Bodenenzymen. Bisher ist wenig darüber bekannt, welche Faktoren die katalytischen Eigenschaften steuern und beispielsweise, ob es Zusammenhänge zur mikrobiellen Gemeinschaftsstruktur gibt. Um diese Fragen näher zu beleuchten wurden sechs hydrolytische Enzyme basierend auf MUF-Substraten untersucht. Die mikrobielle Produktion von AP stand dabei in Zusammenhang mit dem niedrigen P-Status der untersuchten Böden. Das wurde besonders durch die hohe AP Produktion im Vergleich zu BG belegt. Im Allgemeinen konnten drei verschiedene Mechanismen festgestellt werden, die die Produktion der untersuchten EHEs vermutlich steuerten. 1.) Der P-Bedarf der Mikroorganismen regulierte die Produktion von AP, vorausgesetzt, dass ausreichend N und C zur Enzymsynthese zur Verfügung standen. 2.) Die Höhe der mikrobiellen Biomasse hat sich als wichtiger Faktor für die Produktion von CBH, BG und NAG gezeigt. Das deutet auf die konstitutive Produktion dieser Enzyme hin. 3.) Die substratinduzierte Produktion von Enzymen ist vermutlich entscheidend für die Aktivität von AG und XYL. Die Berücksichtigung der Enzymkinetiken, insbesondere der Michaelis-Menten-Konstante lieferte weitere Aufschlüsse über relevante Faktoren. Im Allgemeinen so scheint es, haben sich die mikrobiellen Gemeinschaften an die starken Umweltgradienten, die durch den Landnutzungswandel erzeugt worden angepasst. Im Vergleich zu den verfügbaren Daten aus Reinkulturen, wiesen die mikrobiellen Gemeinschaften der untersuchten Böden in der Regel eine deutlich höhere katalytische Effizienz auf. Auch für die Michaelis-Menten-Konstante sind die Faktoren enzymspezifisch. So ist für die Km von XYL der Boden-pH-Wert, für AP das C:N Verhältnis und für NAG die DOC-Menge entscheidend. Darüber hinaus haben sich deutliche Beziehungen zwischen der Menge an Gram(-)-Bakterien und der Substrataffinitäten von XYL und AP ergeben. Je höher die Gram(-)-Abundanz, desto höher war die Substrataffinität der Enzymsysteme. Gegenüber alter und degradierter Weiden, war der Umsatz der untersuchten Substrate im Oberboden der aktiv genutzten Weide drei- bis vierfach erhöht. In einem 5-jährigen Düngeexperiment in der Bergregenwaldregion der Anden Süd-Ecuadors wurden die Reaktionen des auf dieser Fläche N/P co-limitierten Grases (Setaria sphacelata), der Arbuskulären Mykorrhiza (AMF) sowie der Bodenmikroorganismen auf moderate N, P und N+P-Düngung untersucht. Die Zugabe von N+P erhöhte die oberirdische Biomasse (+61%) wohingegen die Wurzelbiomasse durch die Zugabe von P (+45%) anstieg. Die C:N:P Verhältnisse weisen auf veränderte P-Aufnahme oder Translokation von P in die Wurzeln hin. Im Besonderen verengte sich das Wurzel C:N and C:P in der P- und der N-Zugabe. Die aus dem Boden extrahierbaren C, N und P-Fraktionen wurden deutlich beeinflusst. Die Zugabe von P stimulierte die Biomasse Gram-(+)-Bakterien (+22%), die Abundanz der AMF (+46%) und die Brutto-N-Mineralisierung. Die Auswertungen deuten darauf hin, dass die Nährstoffanreicherung indirekt über die Veränderungen der Graswurzeln auf die Bodenorganismen wirkte. Die Ergebnisse bestätigen, dass N und P in den Reaktionen von co-limitierten Pflanzen eng miteinander verbunden sind. Vor allem aber steuert P grundlegend die Allokation von Ressourcen und wirkt damit auf andere Ökosystem-komponenten, z.B. auf die Struktur und Aktivität der Bodenmikroorganismen.

Ökosystemzerstörung

Ökologische Stöchiometrie

Enzymaktivitäten

Enzymkinetiken

mikrobielle Biomasse

Nährstoffanreicherung

Nährstofffreisetzung

PLFA

seriell-verbundene Nährstoffe

Boden

ecosystem distrubance

ecological stoichiometry

enzyme activities

enzyme kinetics

microbial biomassn

nutrient enrichment

nutrient mineralization

PLFA

serially linked nutrients

soil

ddc:630

rvk:ZC 73588

rvk:ZC 72400

Ecological gradients caused by land-use change and land management alter soil microbial biomass and community functioning in a tropical mountain rainforest region of southern Ecuador

Tischer, Alexander

02 October 2015

Global change phenomena, such as forest disturbance and land-use change significantly affect elemental balances as well as the structure and function of terrestrial ecosystems. Inappropriate land management often causes nutrient losses and finally soil degradation and loss of soil functioning. Especially in tropical ecoregions, soil degradation by nutrient losses is widely abundant. Soil microorganisms are the proximate agents of many processes performed in soils and are regarded as sensitive bio-indicators. However, the incorporation of microbial responses to the definition of critical soil conditions is not intensively developed. In the present thesis, several data analyses of the relationships between ecosystem disturbance and land-use change (natural forest, pastures of different ages, secondary succession) and a diverse set of soil ecological characteristics in the tropical mountain rainforest region of southern Ecuador were compiled. In particular, it was tested whether soil microbial biomass and community functioning were sensitive to land-use change effects. Furthermore, an information-theoretic approach was applied to find the factors that regulate soil microbial biomass and community function. Finally, in a nutrient enrichment experiment the above- and belowground responses to N and P additions were examined. The tested research questions and results were linked to the theory of ecological stoichiometry in order to connect the research to a sound and unifying scientific basis. Soil and microbial stoichiometry were affected by both land-use change and soil depth. After forest disturbance, significant decreases of soil C:N:P ratios at the pastures were fol-lowed by increases during secondary succession. Microbial C:N ratios varied slightly in response to land-use change, whereas no fixed microbial C:P and N:P ratios were observed. Shifts in microbial community composition were associated with soil and microbial stoichiometry. Strong positive relationships between PLFA-markers 18:2n6,9c (saprotrophic fungi) and 20:4 (animals) and negative associations between 20:4 and microbial N:P point to land-use change affecting the structure of soil food webs. Significant deviations from global soil and microbial C:N:P ratios indicated a major force of land-use change to alter stoichiometric relationships and to structure biological systems. Data analysis reveals a strong impact of land-use change on soil microbial biomass, C-mineralization, gross-NH4-consumption and –production rates. According to the results of the IT-approach, combined models better describe effects of land-use change on soil microorganisms than single explanation models. Microbial resources and soil chemical environment were important pre-dictors for soil microbial biomass and community functioning. Little is known about the environmental drivers of the catalytic properties of EHEs (e.g., pH, nutrients) and their functional link to the structure of soil microbial communities. The activities of the six hydrolytic enzymes were tested. Microbial production of AP responded to the low P status of the sites by a higher investment in the acquisition of P compared to C. Three major drivers of enzyme activities were found to be significant for enzyme production: 1.) Microbial demand for P regulated the production of AP, provided that N and C were available. At the natural forest site the two-fold higher specific activity of AP pointed to a high microbial P-demand, whereas the production of AP was constrained by the availability of N and DOC after pasture abandonment. 2.) Microbial biomass that was controlled by pH and resource availability was the main driver for CBH, BG and NAG activities. 3.) Substrate induction due to increased litter inputs of herbaceous plant species seemed to regulate AG and XYL activities during secondary succession. The enzymes’ affinity to substrate, as a potentially critically enzyme kinetic parameter is understudied. The data analysis suggests that microbial communities adapted to environmental changes, demonstrated high flexibility of extracellular enzyme systems and selected for enzymes with higher catalytic efficiency compared with pure cultures. Under in situ conditions, enzyme-specific environmental drivers of the Km, e.g., the pH for XYL, the C:N ratio for AP, and the C availability for NAG were found. The data demonstrated that the higher substrate affinity of XYL and AP was associated with more abundance of Gram(-) bacteria. The catalytic efficiency of enzymes decomposing cellulose, hemicellulose, and starch positively correlated with the relative abundance of Gram(-) bacteria. The turnover rate of the tested substrates was three to four times faster at the young pasture site compared with the longterm pasture and secondary succession sites. Nutrient inputs by atmospheric deposition are known to affect terrestrial ecosystems. However, little is known about how N and P co-limited ecosystems respond to single nutrient enrichment. In this work the susceptibility of above- and belowground ecosystem compo-nents and of their linkages in an N and P co-limited pasture to N- and P-enrichment was assessed. It was tested if the plants´responses can be explained by the concept of serially linked nutrients introduced by Ågren (2004). In this concept, the control of the growth rate by one nutrient is assumed to depend on the control of a different cellular process by another nutrient. The responses of shoot and root biomass and C:N:P stoichiometry of the grass Setaria sphacelata (Schumach.) to moderate N, P, and N+P application over five years were investigated. In addition, the effects of nutrient enrichment on soil nutrient pools, on arbuscular mycorrhizal fungi (AMF) as well as on microbial biomass, activity, and community structure were tested. In order to evaluate the importance of different factors explaining microbial responses, a likelihood-based information-theoretic approach was applied. The application of N+P increased aboveground grass biomass. Root biomass was stimulated by P-treatment. Grass C:N:P stoichiometry responded by altering the P-uptake or by translocating P from shoot to root. In particular, root C:N and C:P stoichiometry decreased in P- and in N-treatment. Extractable fractions of soil C, N, and P were significantly affected by nutrient enrichment. P application increased the biomass of Gram-positive bacteria and the abundance of AMF, however, results of the IT-approach suggested indirect effects of nutrient enrichment on microbes. The responses of the N and P co-limited pasture to particular nutrient enrichment support the concept of serially linked nutrients. The present study provides evidence for the fundamental importance of P for controlling resource allocation of plants in responses to nutrient enrichment. Resource allocation of the grass rather than direct effects of nutrient additions drives changes in AMF, microbial biomass, community structure, and activity. / Seit dem Übergang vom Holozän zum Anthropozän greift der Mensch immer stärker in globale und regionale Stoffkreisläufe ein. Durch die Zerstörung von Naturwäldern und Landnutzungswandel werden die Strukturen und die Funktionen der Ökosysteme stark verändert. Unangepasste Landnutzung führt zu Nährelementverlusten, die mittel- bis langfristige zur Bodendegradation und zur Reduktion von Bodenfunktionen führen. Solche Veränderungen sind insbesondere in den Tropen zu beobachten. Bodenmikroorganismen spielen in den Stoffkreisläufen eine zentrale Rolle. Zudem sind sie sensitive Bioindikatoren für den Zustand von Ökosystemen. Im Gegensatz dazu, werden die Bodenmikroorganismen noch nicht ausreichend für die Zustandsbewertung von Ökosystemen verwendet. In der vorliegenden Dissertation werden verschiedene Datenanalysen zu den Beziehungen von Landnutzungswandel (Naturwald, Weiden verschiedener Alter, sekundäre Sukzession) und den Eigenschaften der Bodenmikroorganismen in einer tropischen Bergregenwaldregion Süd-Ecuadors zusammengefasst. Ein besonderer Fokus lag darauf zu prüfen, ob die mikrobielle Biomasse und die Funktionen die von der mikrobiellen Gemeinschaft geleistet werden (z.B. Enzymaktivitäten) durch den Landnutzungswandel beeinflusst werden. Ein informations-theoretischer Ansatz wurde verwendet um verschiedene Erklärungsansätze der steuernden Faktoren vergleichend zu testen. Darüber hinaus wurden in einem Weidedüngungsexperiment die Reaktionen der ober- und der unterirdischen Ökosystemkomponenten auf die Anreicherung mit N und P getestet. Um die Ergebnisse auf eine breite wissenschaftliche Basis zu stellen wurde die Untersuchungen in den Kontext der Theorie die Ökologischen Stöchiometrie eingeordnet. Die C:N:P Stöchiometrie im Boden und in den Mikroorganismen veränderte sich durch den Landnutzungswandel und mit der Bodentiefe. Mit der Weideetablierung nahmen die C:N:P Verhältnisse im Boden deutlich ab, stiegen dann nach dem Verlassen der Weiden im Zuge der sekundären Sukzession wieder an. Das mikrobielle C:N Verhältnis variierte nur leicht, dagegen zeigten das C:P und N:P Verhältnis deutliche Veränderungen durch den Landnutzungswandel. Mit diesen Veränderungen in der Boden- und Organismenstöchiometrie waren auch Veränderungen in der Struktur der mikrobiellen Gemeinschaften verbunden. Deutliche positive Beziehungen existierten zwischen den saprotrophen Pilzen und den Protozoen. Die steigenden Mengen von Protozoen waren wiederrum mit sinkendem mikrobiellen N:P verbunden. Diese Muster weisen auf Veränderungen in den Bodennahrungsnetzten durch Landnutzungsänderungen hin. Sehr deutliche Abweichungen von globalen Mustern der C:N:P Stöchiometrie deuten darauf hin, dass der Landnutzungswandel signifikanten Einfluss auf die C:N:P Stöchiometrie ausübt. Der Landnutzungswandel beeinflusste auch die mikrobielle Biomasse, die Basalatmung, sowie die mikrobielle Aufnahme und Produktion von NH4-N im Boden. Dabei zeigten kombinierte Erklärungsansätze die adäquateren Beschreibungen der Muster. In den kombinierten Modellen zur Erklärung der mikrobiellen Biomasse und der mikrobiellen Leistungen überwogen Prädiktoren der mikrobiellen Ressourcen und der bodenchemischen Umwelt. Ein weiterer Schwerpunkt der Untersuchungen lag auf der Erfassung der Effekte des Land-nutzungswandels auf die Aktivität von extrazellulären Bodenenzymen. Bisher ist wenig darüber bekannt, welche Faktoren die katalytischen Eigenschaften steuern und beispielsweise, ob es Zusammenhänge zur mikrobiellen Gemeinschaftsstruktur gibt. Um diese Fragen näher zu beleuchten wurden sechs hydrolytische Enzyme basierend auf MUF-Substraten untersucht. Die mikrobielle Produktion von AP stand dabei in Zusammenhang mit dem niedrigen P-Status der untersuchten Böden. Das wurde besonders durch die hohe AP Produktion im Vergleich zu BG belegt. Im Allgemeinen konnten drei verschiedene Mechanismen festgestellt werden, die die Produktion der untersuchten EHEs vermutlich steuerten. 1.) Der P-Bedarf der Mikroorganismen regulierte die Produktion von AP, vorausgesetzt, dass ausreichend N und C zur Enzymsynthese zur Verfügung standen. 2.) Die Höhe der mikrobiellen Biomasse hat sich als wichtiger Faktor für die Produktion von CBH, BG und NAG gezeigt. Das deutet auf die konstitutive Produktion dieser Enzyme hin. 3.) Die substratinduzierte Produktion von Enzymen ist vermutlich entscheidend für die Aktivität von AG und XYL. Die Berücksichtigung der Enzymkinetiken, insbesondere der Michaelis-Menten-Konstante lieferte weitere Aufschlüsse über relevante Faktoren. Im Allgemeinen so scheint es, haben sich die mikrobiellen Gemeinschaften an die starken Umweltgradienten, die durch den Landnutzungswandel erzeugt worden angepasst. Im Vergleich zu den verfügbaren Daten aus Reinkulturen, wiesen die mikrobiellen Gemeinschaften der untersuchten Böden in der Regel eine deutlich höhere katalytische Effizienz auf. Auch für die Michaelis-Menten-Konstante sind die Faktoren enzymspezifisch. So ist für die Km von XYL der Boden-pH-Wert, für AP das C:N Verhältnis und für NAG die DOC-Menge entscheidend. Darüber hinaus haben sich deutliche Beziehungen zwischen der Menge an Gram(-)-Bakterien und der Substrataffinitäten von XYL und AP ergeben. Je höher die Gram(-)-Abundanz, desto höher war die Substrataffinität der Enzymsysteme. Gegenüber alter und degradierter Weiden, war der Umsatz der untersuchten Substrate im Oberboden der aktiv genutzten Weide drei- bis vierfach erhöht. In einem 5-jährigen Düngeexperiment in der Bergregenwaldregion der Anden Süd-Ecuadors wurden die Reaktionen des auf dieser Fläche N/P co-limitierten Grases (Setaria sphacelata), der Arbuskulären Mykorrhiza (AMF) sowie der Bodenmikroorganismen auf moderate N, P und N+P-Düngung untersucht. Die Zugabe von N+P erhöhte die oberirdische Biomasse (+61%) wohingegen die Wurzelbiomasse durch die Zugabe von P (+45%) anstieg. Die C:N:P Verhältnisse weisen auf veränderte P-Aufnahme oder Translokation von P in die Wurzeln hin. Im Besonderen verengte sich das Wurzel C:N and C:P in der P- und der N-Zugabe. Die aus dem Boden extrahierbaren C, N und P-Fraktionen wurden deutlich beeinflusst. Die Zugabe von P stimulierte die Biomasse Gram-(+)-Bakterien (+22%), die Abundanz der AMF (+46%) und die Brutto-N-Mineralisierung. Die Auswertungen deuten darauf hin, dass die Nährstoffanreicherung indirekt über die Veränderungen der Graswurzeln auf die Bodenorganismen wirkte. Die Ergebnisse bestätigen, dass N und P in den Reaktionen von co-limitierten Pflanzen eng miteinander verbunden sind. Vor allem aber steuert P grundlegend die Allokation von Ressourcen und wirkt damit auf andere Ökosystem-komponenten, z.B. auf die Struktur und Aktivität der Bodenmikroorganismen.

info:eu-repo/classification/ddc/630

ddc:630

Environmental Change and Molluscan Death Assemblages: An Assessment of Ecological History Along a Carbonate Bank in Florida Bay

Ferguson, Chad Allen

06 November 2009

No description available.

Biology

Earth

Ecology

Environmental Science

Geology

Paleoecology

Paleontology

molluscan death assemblages

subfossil

carbonate bank

body size

sea shell

mollusk

coastal monitoring

seagrass bed

environmental change

anthropogenic

nutrient enrichment

coastal environment

Thalassia

Halodule

Cerithium

Florida Bay