Mykorhizní symbióza u druhu \kur{Plantago lanceolata} na stanovištích s různou vlhkostí a nabídkou živin / Mycorrhizal symbiosis of \kur{Plantago lanceolata} at locations with differing moisture and nutrient availability

LOKVENCOVÁ, Martina

January 2010

arbuscular mycorrhizal infection of seedlings and adults plants Plantago lanceolata was examined at twenty locations with differing moisture and nutrient availability. At each location two control and two fertilized plots were established. Mycorhizal infection of seedlings was higher on control plots but the symbiosis of adult plants degreased with increasing C/N ratio. Mycorrhizal infection was further distinquished into for morfotypes (Acaulospora, Scutellospora, Glomus, fine endophyte.

Biotransformace monepantelu u rostlin (Campanula rotundifolia, Plantago lanecolata) / Biotransformation of monepantel in plant (Campanula rotundifolia, Plantago lanceolata)

Crhová, Anna

January 2018

Charles University in Prague Faculty of Pharmacy in Hradec Králové Department of Biochemical Sciences Candidate: Bc. Anna Crhová Supervisor: RNDr. Lucie Stuchlíková Raisová, Ph.D. Title of diploma thesis: Biotransformation of monepantel in plants (Campanula rotundifolia, Plantago lanceolata) Anthelmintics are veterinary drugs used to eliminate disease caused by parasitic worms. Monepantel (MOP) is a representative of amino-acetonitrile derivatives. This relatively new group of drugs is effective on helminthic strains, which are resistant to classic therapy (benzimidazoles, makrocyklic lactones, imidazothiazoles). Due to high consuption of these drugs, it is important to find out their fate in the exposed organisms. Anthelmintics are in contact with the environment and they can affect terrestrial and aquatic organisms. Their various forms can be accumulate in plants. These plants can be eaten by the animal, which may lead to development of resistance in helminths. In addition, the physiology of plants and animals may be disrupt and, consequently, biodiversity loss may occur. The aim of this study was to determine the biotransformation processes occurring in ribwort plantain (Plantago lanceolata) and harebell (Campanula rotundifolia) after low concentrations of MOP. Suspensions of both plants cells...

A comparative study of de-icing salts (sodium chloride and calcium magnesium acetate) on the growth of some roadside plants of England

Akbar, K.F., Headley, Alistair D.D., Hale, William H.G., Athar, M.

January 2006

No

Festuca rubra

Lolium perenne

Plantago lanceolata

Trifolium repens

De-icing salts

Sodium chloride

Calcium magnesium acetate

Vliv pratotechnických postupů na uplatnění Plantago lanceolata L. v trvalých travních porostech. / The influence of grassland management on growth \kur{Plantago lanceolata} L. permanent grassland.

WORTNER, Pavel

January 2013

This thesis deals with grasslands, distribution, husbandry, nutrition and treatment. Furthermore, the botanical composition of grasslands and the most important species of weeds, application of N fixation of legumes and plants. In another part of the description and application of dicotyledonous herbs and their economic importance. Furthermore, determination and maintenance of the water system at the sites, and nutrition and fertilization dicotyledonous herbs and vegetation preservation and storage of forage. A key goal of this work is the plantain (Plantago lanceolata L.), its ecology and involvement in different vegetation types. A separate chapter is devoted to the description of the biology, pollination, phenology and agro ? technical cultivation of plantain. The last chapter describes the use of the drug substance and plantain in pharmacy. In the second part of the work to illustrate knowledge of the occurrence of Plantago lanceolata supplemented by results of our own observations (tables and graphs) showing the involvement of P. lanceolata in different types of grassland and two-year follow-up period.

Amoebae in the rhizosphere and their interactions with arbuscular mycorrhizal fungi : effects on assimilate partitioning and nitrogen availability for plants / Amibes dans la rhizosphère et leurs interactions avec les mycorhizes à arbuscules : effets sur la répartition des assimilats et sur la disponibilité en azote pour les plantes

Koller, Robert

14 November 2008

Les interactions entre les végétaux et les organismes telluriques sont déterminantes pour la décomposition des matières organiques et la nutrition minérale des plantes. L’objectif général de la thèse était de comprendre comment les interactions multi-trophiques dans la rhizosphere agissent sur la disponibilité en azote minéral et l’allocation en carbone dans la plante. Nous avons mis au point des dispositifs de culture de plante, permettant de contrôler l’environnement biotique des racines (inoculation par des espèces symbiotiques modèles : un protozoaire bactériophage et/ou une espèce mycorhizienne à arbuscules). Nous avons utilisé l’azote 15N et le carbone 13C pour tracer le cheminement de l’azote du sol vers la plante et le carbone assimilé par photosynthèse, de la plante vers le sol et les microorganismes du sol. L’allocation de C vers les racines et la rhizosphère est dépendante de la qualité de la litière foliaire enfouie. La structure de la communauté microbienne déterminée par l’analyse des profils d’acides gras (PLFA) est modifiée par la présence de protozoaires pour la litière à C/N élevé. Les mycorhizes à arbuscules et les protozoaires présentent une complémentarité pour l’acquisition du C et de N par la plante. Les protozoaires remobilisent l’azote de la biomasse microbienne par leur activité de prédation. Les hyphes fongiques transportent du C récent issu de la plante vers des sites riches en matière organique non accessibles aux racines. Ainsi, l’activité de la communauté microbienne est stimulée et la disponibilité en N augmentée lorsque des protozoaires sont présents. Les perspectives de ce travail sont de déterminer si (i) les interactions étudiées dans ce dispositif modèle peuvent être généralisées à d’autres interactions impliquant d’autres espèces de champignons mycorhiziens et de protozoaires (ii) la phénologie de la plante et la composition des communautés végétales influence la nature et l’intensité des réponses obtenues / Plants interact with multiple root symbionts for fostering uptake of growth-limiting nutrients. In turn, plants allocate a variety of organic resources in form of energy-rich rhizodeposits into the rhizosphere, stimulating activity, growth and modifying diversity of microorganisms. The aim of my study was to understand how multitrophic rhizosphere interactions feed back to plant N nutrition, assimilate partitioning and growth. Multitrophic interactions were assessed in a single-plant microcosm approach, with arbuscular mycorrhizal fungi (Glomus intraradices) and bacterial feeding protozoa (Acanthamoeba castellanii) as model root symbionts. Stable isotopes enabled tracing C (13C) and N (15N) allocation in the plant and into the rhizosphere. Plant species identity is a major factor affecting plant-protozoa interactions in terms of N uptake and roots and shoot morphology. Plants adjusted C allocation to roots and into the rhizosphere depending on litter quality and the presence of bacterial grazers for increasing plant growth. The effect of protozoa on the structure of microbial community supplied with both, plant C and litter N, varied with litter quality added to soil. AM-fungi and protozoa interact to complement each other for plant benefit in C and N acquisition. Protozoa re-mobilized N from fast growing rhizobacteria and by enhancing microbial activity. Hyphae of AM fungi acted as pipe system, translocating plant derived C and protozoan remobilized N from source to sink regions. Major perspectives of this work will be to investigate whether (i) multitrophic interactions in our model system can be generalized to other protozoa-mycorrhiza-plant interactions (ii) these interactions are depending on plant phenology and plant community composition

Rhizosphère

Azote

Carbone

Isotope stable

Plantago lanceolata

Holcus lanatus

Boucle microbienne

Interactions multitrophiques

Protozoaires

Acanthamoeba castellanii

Champignon mycorhizien à arbuscules

Glomus intraradices

Rhizosphere

Holcus lanatus

Zea mays

Carbon

Nitrogen

Stable isotope

13C

15N

Microbial loop

Multitrophic interactions

Protozoa

Acanthamoeba castellanii

Arbuscular mycorrhizal fungi

Glomus intraradices

Microbial community

Plantago lanceolata

Litter quality

PFLA

Antioxidative, analgesic and anti-inflammatory activities of Acokanthera oppositifolia, Plantago lanceolata, Conyza canadensis, and Artemisia vulgaris

Ondua, Moise

02 1900

The anti-inflammatory properties of four medicinal plants were investigated. These plant extracts were subjected to screening for their possible effects as antioxidative, analgesic, and anti-inflammatory agents. In the antioxidant activity, the Plantago lancelota extracts resulted in an IC50 value of 0.4 mg/mL compared to the positive control quecertin with IC50 0.04 mg/mL Plantago lanceolata inhibited COX-2 activity with IC50 values of 0.41 mg/mL. However, the COX-1 inhibition indicated an IC50 of 68.99 mg/mL. The lipoxygenase assay indicated that Plantago lanceolata was the most active plant species with an IC50 value of 4.86 mg/mL compared to the positive control (quecertin) with an IC50<2mg/mL. The nitric oxide assay of the plant extracts indicates a dose-dependent activity of our plant extracts. Likewise the cell viability result indicated a good activity at dose 100 mg/mL. / Life and Consumer Sciences / M. Sc. (Life Sciences)

Plantago lanceolata

Conyza canadensis

Acokantera oppositifolia

Artemisia vulgaris

Antioxidant

Anti-inflammatory

Nitric oxide

Cell viability

Raw 264.7 macrophages

Lypoxygenase

Cyclooxygenase-1

Cyclooxygenase-2

615.321

Antioxidants

Analgesics

Anti-inflammatory agents|

Medicinal plants

Antioxidative, analgesic and anti-inflammatory activities of Acokanthera oppositifolia, Plantago lanceolata, Conyza canadensis, and Artemisia vulgaris

Ondua, Moise

02 1900

The anti-inflammatory properties of four medicinal plants were investigated. These plant extracts were subjected to screening for their possible effects as antioxidative, analgesic, and anti-inflammatory agents. In the antioxidant activity, the Plantago lancelota extracts resulted in an IC50 value of 0.4 mg/mL compared to the positive control quecertin with IC50 0.04 mg/mL Plantago lanceolata inhibited COX-2 activity with IC50 values of 0.41 mg/mL. However, the COX-1 inhibition indicated an IC50 of 68.99 mg/mL. The lipoxygenase assay indicated that Plantago lanceolata was the most active plant species with an IC50 value of 4.86 mg/mL compared to the positive control (quecertin) with an IC50<2mg/mL. The nitric oxide assay of the plant extracts indicates a dose-dependent activity of our plant extracts. Likewise the cell viability result indicated a good activity at dose 100 mg/mL. / Life and Consumer Sciences / M. Sc. (Life Sciences)

Plantago lanceolata

Conyza canadensis

Acokantera oppositifolia

Artemisia vulgaris

Antioxidant

Anti-inflammatory

Nitric oxide

Cell viability

Raw 264.7 macrophages

Lypoxygenase

Cyclooxygenase-1

Cyclooxygenase-2

615.321

Antioxidants

Analgesics

Anti-inflammatory agents|

Medicinal plants

Fixation, Partitioning and Export of Carbon in two Species of the Plantaginaceae

Szucs, Ildiko

05 April 2013

During photosynthesis Plantaginaceae species can produce glucose derivatives such as iridoid glycosides and alcohol sugars that in addition to sucrose can be exported from leaves. Plantago lanceolata transported sorbitol in addition to sucrose especially at warmer leaf temperatures. However, two iridoids, catalpol and aucubin, found in P. lanceolata were not readily labelled from 14CO2 under any conditions examined. In contrast, in two greenhouse, cut-flower cultivars of Antirrhinum majus the iridoids, antirrhinoside and antirrhide, were readily 14C-labelled along with sucrose but little 14C was recovered in alcohol sugars (e.g., mannitol). The amount of 14C-partitioned into antirrhinoside increased at higher temperatures. Exposing leaves of P. lanceolata and A. majus to reduced-photorespiratory conditions (e.g. short-term CO2 enrichment and/or low O2) increased fixation and export. Under low O2 in P. lanceolata sorbitol 14C-labelling increased relative to sucrose and in A. majus 14C-labelling of sucrose increased relative to antirrhinoside. Also 14C-labelling of antirrhide increased more than antirrhinoside. During both short-term and long-term acclimation to high CO2, whole plant NCER, leaf photosynthesis and export increased in A. majus. Taken together the temperature and CO2 enrichment studies show plasticity in Plantaginaceae species to synthesize and transport sucrose and auxiliary glucose esters and alcohol sugars in a species-specific manner (depending on the rate of carboxylation).

Iridoid

glycoside

terpenoid

terpene

monoterpene

Antirrhinum majus

Plantago lanceolata

Plantaginaceae

whole plant

photosynthesis

reduced photorespiratory

low O2

elevated CO2

CO2

14CO2

14C-labelling

14C-partitioning

temperature

alcohol sugar

sorbitol

mannitol

snapdragon

aucubin

catalpol

antirrhide

antirrhinoside

leaf

long term

short term

export

phloem

partitioning

glucose derivative

gas exchange