Analyse von Biotransformationen und Naturstoffsynthesen in pflanzlichen Zellkulturen unter Anwendung der In-vivo-NMR-Spektroskopie ohne Markierung

Hinse, Christiane.

January 2003

Mainz, Universiẗat, Diss., 2003.

Rauwolfia serpentina

Rauwolfia serpentina L. Pharmakologie und Toxikologie einer Heilpflanze /

Kleining, Christiane,

January 1986

Thesis (doctoral)--Köln, 1986.

Pharmakologie. Rauwolfia serpentina.

Reinigung der Vinorin-Synthase aus Zellkulturen von Rauvolfia serpentina

Goldhammer, Annette.

January 2001

Mainz, Univ., Diss., 2001.

Molecular cloning, heterologous expression and characterization of strictosidine glucosidase from Rauvolfia serpentina cell suspension cultures

Gerasymenko, Iryna.

January 2002

Mainz, Univ., Diss., 2002.

Rauwolfia serpentina. Enzym.

Orientation and survival of hatchlings and reproductive ecology of the common snapping turtle (Chelydra serpentina) in southern Quebec

Robinson, Candace

January 1989

The orientation and survival of neonate snapping turtles (Chelydra serpentina) were studied in 1986 and 1987. Orientation mechanisms were tested in an outdoor parabolic arena. These experiments suggested that positive geotaxis was a dominant cue directing neonate snapping turtles to water. / Hatchling survival and movement from nest to water were studied in Calumet, Quebec using isotope tagging. / A highly significant number of hatchlings (95%) released on sloped nest sites were positively geotactic. Hatchlings released on level ground moved in random directions. / Eighty-two percent of hatchlings from nests within 18 m of the shoreline were successful in reaching water. Incidence of mortality was greatest for hatchlings from nests between 121 and 165 m from water. Mortality resulted from vehicles and predation by bullfrogs (Rana catesbieana) and meadow voles (Microtus pennsylvanicus). / Female carapace length was positively correlated with clutch size and mean egg diameter. Egg diameters were positively correlated with hatchling weights. Clutch sizes of nests more than 100 m from water were larger than those closer to water.

Chelydra serpentina -- Reproduction.

Turtles -- Québec (Province)

The role of the vagi and carotid sinus mechanisms in Rauwolfia serpentina hypotension in dogs /

Schlagel, Carl Alvin

January 1955

No description available.

Health Sciences

Dogs

Hypotension

Rauvolfia serpentina

Orientation and survival of hatchlings and reproductive ecology of the common snapping turtle (Chelydra serpentina) in southern Quebec

Robinson, Candace

January 1989

No description available.

Turtles -- Québec (Province)

Chelydra serpentina -- Reproduction.

ECOLOGICAL PHYSIOLOGY OF OVERWINTERING IN HATCHLING BLANDING’S TURTLES (Emydoidea blandingii): INSIGHTS INTO ANOXIA TOLERANCE AND FREEZE TOLERANCE

Dinkelacker, Stephen

29 July 2004

No description available.

Biology, Animal Physiology

HATCHLING

TURTLES

blandingii

ANOXIA

freezing

lactate

serpentina

Conservation Genetics of Freshwater Turtles

Davy, Christina M.

19 March 2013

Turtles have long life spans, overlapping generations and promiscuous mating systems. Thus, they are an ideal system with which to investigate the application of conservation genetics methods and assumptions to long-lived organisms. Turtles are also one of the most threatened groups of vertebrates and conservation genetics studies are essential to effective recovery of turtle species. This thesis has two main objectives: 1) to evaluate some common population genetics assumptions with respect to turtles and other long-lived organisms, and 2) to collect important information on the population genetics of threatened turtles in Ontario, which can be used to inform species recovery. In Chapters Two and Three, I describe the development of novel microsatellite markers for the snapping turtle and spiny softshell. In Chapter Four I demonstrate significant genetic structure in populations of the endangered spotted turtle in Ontario, and find that “bottleneck tests” may fail to detect recent population declines in small turtle populations. I also show that spotted turtles do not show the typical correlation between population size and genetic diversity. In Chapter Five I use microsatellite markers developed in Chapter Two and document population structure in the widespread snapping turtle for the first time. I compare these results with results from Chapter Four to test the traditionally accepted hypothesis that genetic diversity is reduced in small, isolated populations compared to large, connected populations. As in Chapter Four, my results suggest that the usual patterns of genetic structure and loss of diversity may not apply to turtles. In Chapter Six I conduct a conservation genetics study of the endangered Blanding’s turtle. Finally, in Chapter Seven I combine results from spotted, snapping and Blanding’s turtles to test whether vagility predicts population structure, genetic diversity and significant barriers to gene flow in three species sampled across a single landscape. Analyses reveal minimal congruence in barriers to gene flow and the three species show unexpected and contrasting patterns of diversity across the landscape. Discordant patterns among species highlight areas for further research and shed light on possible cryptic behaviour, and I discuss potential further directions for research in the Summary.

microsatellite

spatial genetics

Emys blandingii

Chelydra serpentina

Clemmys guttata

Apalone spinifera

0478

0472

0369

Conservation Genetics of Freshwater Turtles

Davy, Christina M.

19 March 2013

Turtles have long life spans, overlapping generations and promiscuous mating systems. Thus, they are an ideal system with which to investigate the application of conservation genetics methods and assumptions to long-lived organisms. Turtles are also one of the most threatened groups of vertebrates and conservation genetics studies are essential to effective recovery of turtle species. This thesis has two main objectives: 1) to evaluate some common population genetics assumptions with respect to turtles and other long-lived organisms, and 2) to collect important information on the population genetics of threatened turtles in Ontario, which can be used to inform species recovery. In Chapters Two and Three, I describe the development of novel microsatellite markers for the snapping turtle and spiny softshell. In Chapter Four I demonstrate significant genetic structure in populations of the endangered spotted turtle in Ontario, and find that “bottleneck tests” may fail to detect recent population declines in small turtle populations. I also show that spotted turtles do not show the typical correlation between population size and genetic diversity. In Chapter Five I use microsatellite markers developed in Chapter Two and document population structure in the widespread snapping turtle for the first time. I compare these results with results from Chapter Four to test the traditionally accepted hypothesis that genetic diversity is reduced in small, isolated populations compared to large, connected populations. As in Chapter Four, my results suggest that the usual patterns of genetic structure and loss of diversity may not apply to turtles. In Chapter Six I conduct a conservation genetics study of the endangered Blanding’s turtle. Finally, in Chapter Seven I combine results from spotted, snapping and Blanding’s turtles to test whether vagility predicts population structure, genetic diversity and significant barriers to gene flow in three species sampled across a single landscape. Analyses reveal minimal congruence in barriers to gene flow and the three species show unexpected and contrasting patterns of diversity across the landscape. Discordant patterns among species highlight areas for further research and shed light on possible cryptic behaviour, and I discuss potential further directions for research in the Summary.

microsatellite

spatial genetics

Emys blandingii

Chelydra serpentina

Clemmys guttata

Apalone spinifera

0478

0472

0369