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291.
292.
DAVID G. JAMES 《Ecological Entomology》1984,9(4):421-428
Abstract. 1. In the Sydney area of New South Wales, dry weights of reproductive monarch butterflies averaged 156 mg and were higher during winter than in other seasons. Dry weights of non-reproductive monarchs ranged from 216 to 324 mg and declined by 15–25% during over wintering.
2. Fat in reproductive butterflies ranged from 0.009 to 0.017g/0.1g dry weight and was lower during winter than in other seasons. Fat content of non-reproductive monarchs was higher (0.019–0.037 g/0.1g) and declined by 24–51% during over wintering.
3. Lean dry weights of reproductive monarchs were lower than those of non-reproductive individuals. Lean dry weights of non-reproductive butterflies increased rapidly at the beginning of over wintering and remained high throughout the winter. Analysis of protein content indicated the higher lean weight of non-reproductive monarchs was due to greater protein levels.
4. Moisture content of monarchs did not vary with season or reproductive status and appeared to be correlated with ambient humidity.
5. Non-reproductive monarch butterflies in New South Wales adjust bio chemically during over wintering. Energy reserve dynamics of these butterflies are comparable to those that occur in non-reproductive monarchs in North America. 相似文献
2. Fat in reproductive butterflies ranged from 0.009 to 0.017g/0.1g dry weight and was lower during winter than in other seasons. Fat content of non-reproductive monarchs was higher (0.019–0.037 g/0.1g) and declined by 24–51% during over wintering.
3. Lean dry weights of reproductive monarchs were lower than those of non-reproductive individuals. Lean dry weights of non-reproductive butterflies increased rapidly at the beginning of over wintering and remained high throughout the winter. Analysis of protein content indicated the higher lean weight of non-reproductive monarchs was due to greater protein levels.
4. Moisture content of monarchs did not vary with season or reproductive status and appeared to be correlated with ambient humidity.
5. Non-reproductive monarch butterflies in New South Wales adjust bio chemically during over wintering. Energy reserve dynamics of these butterflies are comparable to those that occur in non-reproductive monarchs in North America. 相似文献
293.
Overwintering problems of newly established Miscanthus plantations can be
overcome by identifying genotypes with improved rhizome cold tolerance 总被引:2,自引:0,他引:2
Miscanthus , a perennial rhizomatous C4 grass, is a potential biomass crop in Europe, mainly because of its high yield potential and low demand for inputs. However, until recently only a single clone, M. × giganteus , was available for the extensive field trials performed across Europe and this showed poor overwintering in the first year after planting at some locations in Northern Europe. Therefore, field trials with five Miscanthus genotypes, including two acquisitions of Miscanthus × giganteus , one of M. sacchariflorus and two hybrids of M. sinensis were planted in early summer 1997 at four sites, in Sweden, Denmark, England and Germany. The field trials showed that better overwintering of newly established plants at a site was not apparently connected with size or early senescence. An artificial freezing test with rhizomes removed from the field in January 1998 showed that the lethal temperature at which 50% were killed (LT50 ) for M. × giganteus and M. sacchariflorus genotypes was −3.4 °C. However, LT50 in one of the M. sinensis hybrid genotypes tested was −6.5 °C and this genotype had the highest survival rates in the field in Sweden and Denmark. Although the carbohydrate content of rhizomes, osmotic potential of cell sap and mineral composition were not found to explain differences in frost tolerance adequately, moisture contents correlated with frost hardiness (LT50 ) in most cases. The results obtained form a basis for identifying suitable Miscanthus genotypes for biomass production in the differing climatic regions of Europe. 相似文献