红松种子休眠与种皮的关系

本文探讨红松(Pinus koraiensis)种子休眠与其种皮之间的关系。夹破中种皮后,种子萌发率很低。在离体胚培养基中外加 ABA 及经 ABA 溶液浸泡种子的萌发实验表明,ABA也不是导致休眠的关键因素。试验确认红松种子存在透气障碍,即中、内种皮对氧气的进入都有阻碍作用。经低温砂藏后,种皮的阻碍作用明显减小。种皮的透气性障碍可能是诱导休限的主导因素。     

SEED DORMANCY AND GERMINATION IN MELAMPYRUM LINEARE

Immature seeds of Melampyrum lineare Desr. have very high germination percentages and dormancy is induced in a variable fraction of the seed crop during ripening. Correlated with this is the endogenous gibberellin-like activity which is found in considerable amounts in immature seeds, less in batches of ripe seeds, and is not detectable in batches containing only dormant seeds. For germination dormant seeds require activation followed by cold storage. In the laboratory activation is produced by allowing moist, dormant seeds to respire freely for several weeks at 20 C, or by treatment with exogenous GA₃. Dormancy appears to be most directly related to inability of the embryo to hydrolyze the thickened, mannan-containing endosperm cell walls. Embryos excised from dormant seed can be grown on agar enriched with whole macerated dormant seeds or with the ethanol-extractable materials from these (mostly sucrose and a glycoside). However, dormant seed material does not support growth when extracted to remove benzene- and ethanol-soluble materials.     

MECHANISM OF SEED DORMANCY IN AMBROSIA ARTEMISIIFOLIA

Dormancy in Ambrosia artemisiifolia seeds was broken by 8 weeks of stratification. Germination of nondormant seeds was greater in light than in continuous darkness. Embryos of freshly harvested seeds were nondormant. Leaching and scarification did not stimulate germination of the dormant seeds. Exogenous gibberellin (GA₃) slightly increased germination of intact dormant seeds, and the effect was greatly increased by scarification. Germination was greater in the light in both tests. Exogenous indoleacetic acid did not stimulate germination of dormant seeds. Endogenous gibberellin and auxin content increased during stratification, and there was also a significant increase in GA during post-stratification at a favorable germination temperature. Inhibitors in the dormant seeds decreased during stratification and post-stratification. The high concentration of chlorogenic acid present in dormant seeds increased slightly during stratification. An unknown phenol very similar to chlorogenic acid in fluorescence and U.V. absorption significantly increased after 2 weeks of stratification. A significant decrease in the concentration of a second unidentified phenol occurred after 2 weeks of stratification. It is proposed that dormancy in Ambrosia artemisiifolia may be controlled by an inhibitor-promoter complex. The dormant seed is characterized by high inhibitor and low promoter levels. In the nondormant seed the balance was shifted to favor the promoter. Evidence suggests that the inhibitor involved may be abscisic acid and the promoters may be gibberellin and auxin. The content of auxin may be partially controlled by the concentration of phenols.     

SEED DORMANCY IN UNIOLA PANICULATA

Seeds of Uniola paniculata L., a sand-dune grass of the Southeast coast, showed an increasing dormancy under laboratory germination conditions that reached 98–100% six months after maturity. The embryos were viable and nondormant and the seeds absorbed water readily. Chemical treatments were only moderately effective, but leaching the seeds after cutting into the endosperm gave 100% germination. The presence of a diffusible growth inhibitor was demonstrated by this response and by tests of endosperm leachate. Temperature, particularly sand temperature above 30 C, appears to be the major factor in normal germination of the seed.     

DORMANCY AND GERMINATION IN SEEDS OF COMMON RAGWEED WITH REFERENCE TO BEAL'S BURIED SEED EXPERIMENT

Common ragweed (Ambrosia artemisiifolia L.) was one of 19 herbaceous weedy species used by Beal in his buried viable seed experiment started in 1879. No seeds germinated during the first 35 years of the experiment when germination tests were performed in late spring, summer or early autumn. Germination did occur in seeds buried for 40 years when seeds were exhumed and tested for germination in early spring. Data obtained in more recent research provide the probable explanation for these results. Seeds of common ragweed that do not germinate in spring enter secondary dormancy by mid to late spring and will not germinate until dormancy is broken the following late autumn and winter. Thus, during the first 35 years of the experiment seeds were dormant when tested for germination, whereas seeds buried for 40 years were nondormant. Seeds buried 50 years or longer did not germinate when tested in spring, probably because they had lost viability and/or seeds germinated during burial and seedlings died.     

SEED DORMANCY IN ISANTHUS BRACHIATUS (LABIATAE)

Seed dormancy and its ecological aspects were investigated in Isanthus brachiatus, a summer annual plant of limestone outcrops in southeastern United States. Freshly matured seeds are dormant and exhibit physiological polymorphism with respect to the conditions necessary to overcome dormancy. Fifteen to thirty-five percent of the seeds in a seed crop require only one stratification treatment and germinate the first spring following their dispersal in autumn. The remainder of the seeds require two, three, or more stratification treatments and thus do not germinate until after two, three, or more overwintering periods in the field. In those seeds that require more than one stratification treatment to overcome dormancy, the stratification periods must be separated by a “rest” period, which in nature corresponds to summer. The ecological significance of this type of seed dormancy mechanism in I. brachiatus is discussed in relation to adaptation to its habitat.     

国产打碗花属植物种子形态及其分类学意义

本文借助于又目解剖镜和扫描电电镜对我国打碗花属５种植物的种子进行了观察。结果表明：１、该属植物的种子可分为两类,一类为旋花型,较小,表面具疣状突起,种皮纹饰呈网状,包括打碗花、毛打碗花及旋花;另一类为藤水苗型较大,无疣状突起,种皮纹饰呈咀烂状,包括藤长苗和肾叶打碗花。２、疠状突起由数个相邻种皮细胞胞间壁强烈突出而成,呈山峰状,相连或单独存在。３、该属植物种子形态存在明显区别,可作为分种的依据。