Shoot growth in aseptically cultivated daylily and haplopappus plantlets after a 5-day spaceflight

Plantlets of daylily (Hemerocallis cv. Autumn Blaze) regenerated from cell suspensions, and 4 clonal populations of Haplopappus gracilis were aseptically cultivated aboard the Shuttle "Discovery" during a 5-day mission within NASA's Plant Growth Unit (PGU) apparatus. Daylily was selected as a representative herbaceous perennial monocotyledon and the haplopappus clones represented an annual dicotyledon. The latter included 4 strains with different physiological and morphological characteristics: two aseptic seedling clones (each generated from a single seedling) and two tissue culture-derived lines. Mean daily growth rates for the primary shoots of all plantlets averaged 4.13 mm day-1 (SD = 2.20) for the flight experiment and 4.68 mm day-1 (SD = 2.59) for the ground control. Comparable growth rates calculated by summing both the primary and secondary shoots for all plantlets were 5.94 mm day-1 (SD = 2.89) for the flight experiment and 6.38 mm day-1 (SD = 3.71) for the control. Statistically significant differences existed between: (1) flight vs control primary shoot growth (the controls growing more than plantlets subjected to spaceflight conditions), (2) the different populations (the daylily gaining more shoot material than any of the haplopappus populations and the haplopappus seedling clones outperforming the tissue culture-derived haplopappus lines), and (3) the individual Plant Growth Chambers contained within the PGU. The data suggest that some spaceflight-associated factor(s) increased the tendency for primary shoot apices to degrade or senesce, resulting in the release of apical dominance and permitting the emergence of axillary branches, which subsequently partially compensated for the reduced primary axis growth. In addition to spaceflight-associated factors, the physiologically diverse nature of the experimental material as well as environmental heterogeneities within the culture apparatus contributed to the variation in growth results. The findings could explain some discrepancies reported from various plant culture experiments conducted in space.     

Development of leucine aminopeptidase activity during daylily flower growth and senescence

The possibility that exopeptidases, i.e. aminopeptidases and carboxypeptidases, in addition to the previously studied endopeptidase might also be developmentally regulated in daylily petals was examined. The level of leucine aminopeptidase and endopeptidase activities changed after the flower was fully open while that of carboxypeptidase activity remained relatively unchanged throughout senescence. Leucine aminopeptidase activity seemed to increase after the flower was fully open and peaked several hours earlier than endopeptidase did. Taken together, it is postulated that leucine aminopeptidase might play a role in protein turnover during flower opening and in the initiation of protein hydrolysis associated with petal senescence while the endopeptidase could be responsible for the breakdown of the bulk of proteins at the later stages. The drop in leucine aminopeptidase activity associated with the onset of daylily petal senescence was effectively halted by a cycloheximide treatment of cut daylily flowers for 24 h which was previously shown to prolong the vase life of the flowers and prevent protein loss from the petals. Apart from both being developmentally regulated in daylily petals, the leucine aminopeptidase activity and the previously studied endopeptidase are different in several aspects. They appear to have different pH optima, 8 for leucine aminopeptidase and 6.2 for endopeptidase. Unlike the endopeptidase activity, no new leucine aminopeptidase isozymes appeared during petal senescence, and the leucine aminopeptidase did not appear to belong to the cysteine class of proteolytic enzymes.     

Evaluation of genetic variation in the daylily (Hemerocallis spp.) using AFLP markers

The daylily (Hemerocallis spp.) is one of the most economically important ornamental plant species in commerce. Interestingly, it is also one of the most heavily bred crops during the past 60 years. Since the American Hemerocallis Society began acting as the official registry of daylily cultivars in 1947, more than 40 000 registrations have been processed. In order to determine the effects of intensive breeding on cultivar development, and to study relationships among different species, genetic variation in the daylily was estimated using AFLP markers. Nineteen primary genotypes (species and early cultivars) and 100 modern cultivars from different time periods were evaluated using 152 unambiguous bands (average 79% polymorphism rate) derived from three AFLP primer combinations. Overall, pairwise similarity estimates between entries ranged between 0.618 and 0.926 (average=0.800). When comparing cultivar groups from different time periods (1940–1998), genetic similarity was initially increased, compared to the primary diploid genotypes, remained constant from 1940 to 1980, and then steadily increased as breeding efforts intensified and hybridizers began focusing on a limited tetraploid germplasm pool derived by colchicine conversion. Among modern (1991–1998) daylily cultivars, genetic similarity has increased by approximately 10% compared to the primary genotypes. These data were also used to evaluate recent taxonomic classifications among daylily species which, with a few minor exceptions, were generally supported by the AFLP data. Received: 15 March 2000 / Accepted: 13 June 2000     

Lipid peroxidation inhibitory compounds from daylily (Hemerocallis fulva) leaves

Daylilies (Hemerocallis spp.) have been used as food and in traditional medicine for thousands of years in eastern Asia. The leaves of the plant are used in the treatment of inflammation and jaundice. In studies of the aqueous methanol extracts of fresh Hemerocallis fulva leaves, 1',2',3',4'-tetrahydro-5'-deoxy-pinnatanine (1), pinnatanine (2), roseoside (3), phlomuroside (4), lariciresinol (5), adenosine (6), quercetin 3-O-beta-D-glucoside (7), quercetin 3,7-O-beta-D-diglucopyranoside (8), quercetin 3-O-alpha-L-rhamnopyransol-(1-->6)-beta-D-glucopyranosol-7-O-beta-D-glucopyranoside (9), isorhamnetin-3-O-beta-D-6'-acetylglucopyranoside (10) and isorhamnetin-3-O-beta-D-6'-acetylgalactopyranoside (11) were isolated. All of these compounds were tested for their in vitro lipid peroxidation inhibitory activities. Compounds 3-5 and 7-11 were found to possess strong antioxidant properties, inhibiting lipid oxidation by 86.4, 72.7, 90.1, 79.7, 82.4, 89.3, 82.2, and 93.2%, respectively at 50 microg/mL. Compound 1 is novel and compounds 3-6 and 8-11 described here in are isolated for the first time from daylily leaves.     

黄花菜不同外植体形成的愈伤组织再生苗观察

研究了黄花菜不同外植体愈伤组织的形成与植株再生。结果表明,出愈率是花柄>花茎>叶片。愈伤组织在MS+6-BA 2mg/L的培养基上出现致密愈伤组织颗粒,经增殖→分割→增殖的程序逐渐形成“球状体”似的愈伤组织。叶片、花茎形成的球状体经20代继代培养,再生能力没有减退,苗形态正常,根尖细胞染色体数目为2n=2x=22。该球状体经秋水仙素处理获得多种形态的四倍体苗和少数重复加倍现象。花柄球状体再生苗中出现了叶片花瓣状或类似花蕾状的形态异常苗,其频率与花柄所处的花期及花蕾大小有密切关系。再生异常苗的球状体继代培养,或者由异常苗叶片重新形成的球状体仍然再生异常苗。花柄球状体经秋水仙素处理,获得的变异株其染色体数目类型较多。因而不宜用花柄作黄花菜快速繁殖的外植体。