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31	Patrones de estructuración y flujo genético en cuatro taxa del género Eriosyce (Cactaceae) en el sitio prioritario para la conservación Los Molles – Pichidangui Tamburrino Widner, Ítalo Francisco 01 1900 (has links) Título de Biólogo Ambiental / Las herramientas moleculares han permitido analizar la estructura y diversidad genética en especies de las que se tiene poca información previa, y a detectar procesos como la pérdida de variabilidad genética y estimar flujo genético entre taxa. Estos análisis cobran especial relevancia en especies de distribución restringida, las cuales son más susceptibles a efectos de la deriva génica y la depresión por consanguinidad. En la familia Cactaceae es frecuente la hibridación interespecífica y este proceso ha sido propuesto como parte del mecanismo que da origen a algunas especies pertenecientes a este linaje. En el en el Sitio Prioritario para la Conservación Los Molles – Pichidangui de Chile central cohabitan Eriosyce chilensis y Eriosyce chilensis var. albidiflora, dos cactáceas endémicas exclusivamente de esa zona. En base a evidencias moleculares y a sus características morfológicas se ha propuesto un origen híbrido a partir del entrecruzamiento entre E. subgibbosa y E. curvispina var. mutabilis, taxa con los que crecen en simpatría. El objetivo de esta tesis es analizar la diversidad y estructura genética y el flujo genético entre E. chilensis, E. chilensis var. albidiflora, E. subgibbosa y E. curvispina var. mutabilis mediante el uso de AFLP. Los resultados principales indican niveles similares de diversidad genética en E. chilensis, E. chilensis var. albidiflora, E. subgibbosa y E. curvispina var. mutabilis, además baja estructuración entre E. chilensis y E. chilensis var. albidiflora; y la existencia de flujo genético (hibridación) entre E. chilensis y E. subgibbosa. Por otro lado, E. curvispina var. mutabilis posee la mayor diferenciación genética con el resto de los taxa. Solo se encuentran patrones de aislamiento genético por distancia en E. chilensis. Los niveles de diversidad genética en E. chilensis y E. chilensis var. albidiflora pueden ser explicados por el efecto de la polinización biótica y la longevidad de estos xii taxa, como también por el flujo genético con E. subgibbosa. La tendencia a la exogamia, el ámbito de hogar de los polinizadores y la dimensión del hábitat de los taxa estudiados daría cuenta de la carencia de estructuración intrapoblacional en el complejo E. chilensis-E. chilensis var. albidiflora y de los patrones de aislamiento genético por distancia. Solo se encuentra mezcla genética de E. subgibbosa en E. chilensis y E. chilensis var. albidiflora, por lo que en base a la evidencia obtenida en este trabajo y otros, se apoya parcialmente la hipótesis del origen híbrido y se propone un escenario que explica el origen de estos taxa. La técnica de AFLP muestra efectividad para el cumplimiento de los objetivos planteados en esta tesis, aunque se sugiere ampliar el muestreo y el número de partidores utilizados para mayor resolución en los resultados. / Molecular tools have allowed analyzing the genetic structure and diversity of species with low information available, detecting processes as genetic variability loss, and estimating genetic flux between taxa. These analysis may be particularly relevant in narrowly distributed species, which are more susceptible to the effect of genetic drive and inbreeding. Interspecific hybridization is frequent in the Cactaceae family and this process has been proposed as part of the mechanism that originates some species in this lineage. Eriosyce chilensis and Eriosyce chilensis var. albidiflora, two endemic cacti, cohabitate exclusively in central Chile’s Priority Site for Conservation Los Molles – Pichidangui. Based on molecular evidence and morphological characterization, an hybrid origin of these taxa has been proposed, from the cross between E. subgibbosa and E. curvispina var. mutabilis, with whom they grow in sympatry. The aim of this thesis is to analyze the genetic structure, genetic diversity and the genetic flux between E. chilensis, E. chilensis var. albidiflora, E. subgibbosa and E. curvispina var. mutabilis using the AFLP technique. Principal results indicate similar levels of genetic diversity between E. chilensis, E. chilensis var. albidiflora, E. subgibbosa and E. curvispina var. mutabilis, and low genetic structuration between E. chilensis and E. chilensis var. albidiflora; besides the existence of genetic flux (hybridization) between E. chilensis and E. subgibbosa. On the other side, E. curvispina var. mutabilis is genetically isolated from the other taxa. Genetic isolation by distance is only found in E. chilensis. Eriosyce chilensis and E. chilensis var. albidiflora’s genetic diversity levels may be explained by the effect of biotic pollination and the longevity of these taxa, as by the genetic flux with E. subgibbosa. Tendency to outcrossing, pollinator’s home range and xiv habitat dimension of the studied taxa may account for the lack of intrapoblational substructuration in the E. chilensis – E. chilensis var. albidiflora complex and for the genetic isolation by distance patterns. Genetic admixture only of E. subgibbosa is found in E. chilensis and E. chilensis var. albidiflora, thus, based on evidence found on this study and others, the hybrid origin hypothesis is partially supported, and an explicative scenario of the taxa’s origin is proposed. AFLP technique shows effectiveness on the accomplishment of the objectives of this thesis, although it is suggested to expand the sampling and the number of primers for a better resolution in the results. Cactus,Genetica Eriosyce Biología ambiental
32	The influence of polyploidy on the morphology, physiology, and breeding behavior of Hatiora x graeseri (Cactaceae) / Karle, Renate 01 January 1996 (has links) (PDF) No description available. Cactus Genetics Chimeras Botany Polyploidy.
33	The Isolation and Identification of Flavonoids in ZYGOCACTUS Wade, Jacqueline M. 01 January 1984 (has links) (PDF) No description available. Botanical chemistry Cactus Flavonoids Biology
34	A revision of Neobesseya in the United States and Cuba Abel, Arlene Edith. January 1963 (has links) Call number: LD2668 .T4 1963 A25 / Master of Science Plants--Classification. Cactus. Neobesseya. Masters theses
35	Population biology and ecology of the critically endangered succulent adenium swazicum Van der Walt, Karin 22 January 2016 (has links) A dissertation submitted to the Faculty of Science, University of the Witwatersrand, Johannesburg, in fulfilment of the requirements for the degree of Masters of Science June 2015 / Adenium swazicum is currently listed as Critically Endangered due to past and future population declines, which have been estimated to be 80% over three generations. Although 10-20% of the population is present in formal protected areas, no studies have been published on the species population biology and ecology, which are essential to ensure its effective conservation. The broad aim of this research was to investigate the population biology and ecology of Adenium swazicum by investigating factors such as current distribution, population structure, reproductive characteristics, germination, herbivory and current threats. The current distribution of Adenium swazicum was determined by searching all herbarium records on the National Herbarium Pretoria Computerised Information System as well as additional suitable habitat through fieldwork, conducted during the flowering period (October to April) between 2009 and 2011. The current Extent of Occurrence (EOO) and Area of Occupancy (AOO) were determined by incorporating all confirmed localities of Adenium swazicum. To determine the population biology of Adenium swazicum, fifty plants in four representative populations were studied with regards to plant size, extent and intensity of herbivory, flower production as well as follicle and seed production. The reproduction of Adenium swazicum was determined through pollinator observations while the number of flowers and fruit (follicles) produced, as well as fruit and seed set were compared in the four representative populations. Seed viability was determined through tetrazolium staining, while germination experiments were used to determine minimum, maximum and optimum temperature ranges as well as mean germination time. Seedling emergence and establishment were determined for various soil media, depth of seed planting, watering regimes and shading. The current distribution of A. swazicum included 23 localities in South Africa, Swaziland and Mozambique, while the Extent of Occurrence (EOO) was approximately 8 392km² (839 246 ha) and the Area of Occupancy (AOO) was estimated to be 8.5km² (850ha). Although this indicates that A. swazicum might be more widespread than previously believed, the population sizes were all small (between 1 and 141) and most of the populations were still threatened, mostly by habitat destruction and harvesting for medicinal purposes. The research found that adult A. swazicum plants were found to have a high tolerance to natural disturbance (fire, herbivory) and resprout from the underground tuber even if all above ground parts were destroyed. It is however unlikely that seedlings and juveniles will be able to withstand significant impact on the above ground parts since the underground tuber only develops in plants older than 24 months. Despite big and bright floral displays which should attract insect pollinators, low diurnal insect activity was observed around A. swazicum. However, a fast flying Sphingidae (Hawk Moth), which is most likely a pollinator, was observed at A. swazicum flowers at dusk. Small population size and isolation might have been the cause of no reproduction (very few follicles and no seed) in at least one population in 2010. Continued reproduction failure as well as destruction of remaining adult plants by housing developments and collection for medicinal purposes might lead to the local extinction of this population. With sufficient available moisture, high germination success (82 to 90%) for A. swazicum was achieved at temperatures between 20°C and 35°C, without any pre-treatment, and ‘maximum’ germination was reached in less than 90 hours. The cultivation of A. swazicum from seed is highly successful, with different soil media having no apparent influence on seedling emergence and establishment. Seedling emergence was highly dependent on water, and although shading did not influence seedling emergence, seedling establishment/survival was highly dependent on shading. Since seed release from A. swazicum coincides with the start of the rainy season (October), as well as short germination responses, it is highly unlikely that A. swazicum forms persistent soil seed banks. The uncomplicated propagation of A. swazicum has resulted in a significant ex situ collection at the Lowveld National Botanical Garden, with more than 2000 plants (adults and seedlings) grown from seeds which were collected from four different populations over an eight year period. In addition, the Skukuza indigenous nursery in Kruger National Park has more than 250 plants (adults and seedlings) all of which were grown from seed collected in the KNP. These living ex situ collections provide a valuable source of plant material for future restoration projects. Despite an increase in the number of known Adenium swazicum populations, the population sizes are small (1 to 141) and most populations are still threatened by habitat destruction and high levels of exploitation by medicinal plant harvesters. It is therefore recommended that Adenium swazicum remains listed as Critically Endangered (A4acd;B2cb). Criteria A4acd: “An observed, estimated, inferred, projected or suspected population reduction (up to a maximum of 100 years) where the time period must include both the past and future, and where the causes of reduction may not have ceased or, may not be understood, or may not be reversible based on”. This assessment was based on (a) the causes of reduction of Adenium swazicum populations have not ceased and may not be reversible, (c) there is a decline in AOO, EOO and habitat quality; and (d) there is actual, continuing exploitation of A. swazicum. Adenium swazicum also qualifies as CR under criteria B2b(iv,v): “Geographic range in the form of Area of Occupancy (AOO) of <10km² with (b) continuing decline in (iv) number of locations or subpopulations and (v) number of mature individuals”. No immediate management intervention is needed for populations which are located in formal protected areas, although it is recommended that these populations be monitored, especially with regards to reproduction to inform future management decisions. It is possible that low seed viability recorded in population C in 2009 and 2010 could be due to inbreeding depression caused by the destruction of surrounding populations due to sugarcane fields and harvesting of adult plants for medicinal uses. The Low veld National Botanical Garden had collected parental material from populations surrounding population C since 2003; it is recommended that restoration of decimated populations be conducted in secure areas on for example private land and community schools. Lastly, seed collected from various populations should be banked at the Kew Millennium Seed Bank Project, England to ensure viable ex situ collections. Population biology. Succulent plants. Cactus--Ecology.
36	Native Cacti as Emergency Forage Plants Thornber, J. J., Vinson, A. E. 20 December 1911 (has links) This item was digitized as part of the Million Books Project led by Carnegie Mellon University and supported by grants from the National Science Foundation (NSF). Cornell University coordinated the participation of land-grant and agricultural libraries in providing historical agricultural information for the digitization project; the University of Arizona Libraries, the College of Agriculture and Life Sciences, and the Office of Arid Lands Studies collaborated in the selection and provision of material for the digitization project. Agriculture -- Arizona Cactus Forage plants -- Arizona
37	STABILIZATION AND CHEMICAL PROPERTIES OF TWO RELATED ISOMETRIC CACTUS VIRUSES Zouba, Ali January 1979 (has links) No description available. Cactus -- Diseases and pests. Virus diseases of plants.
38	Perennial vegetation associated with the organpipe cactus in Organ Pipe Cactus National Monument, Arizona Mulroy, Thomas Wilkinson, 1946- January 1971 (has links) No description available. Desert plants. Cactus -- Arizona. Botany -- Arizona.
39	A BIOCHEMICAL INVESTIGATION OF CALLUS TISSUE IN THE SAGUARO CACTUS (CARNEGIEA GIGANTEA ((ENGELM.)) BRITT. & ROSE) Caldwell, Roger L. January 1966 (has links) No description available. Cactus -- Diseases and pests. Saguaro -- Diseases and pests.
40	ETIOLOGY AND EPIDEMIOLOGY OF VIRUSES OF NATIVE CACTUS SPECIES IN ARIZONA Milbrath, Gene McCoy, 1941- January 1971 (has links) No description available. Cactus -- Diseases and pests. Virus diseases of plants.

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