Phenology and common garden and reciprocal transplant studies of Polymnia canadensis (Asteraceae), a monocarpic species of the North American Temperate Deciduous Forest

Polymnia canadensis, an herbaceous plant species ofthe North American Temperate Deciduous Forest heretofore reported as beingperennial, is shown to be primarily monocarpic. In common garden experiments,the majority of plants grown from seeds or seedlings collected in Kentucky,Alabama, Virginia, Ohio, and Missouri were monocarpic, but some were dicarpic,tricarpic or polycarpic. Observations in natural populations of P.canadensis suggested that there is variation in the life history ofthis species throughout its geographic range. Anthesis date and height ofplantsat anthesis were significantly different between mesic and dry field sites incentral Kentucky populations, but common garden and reciprocal transplantexperiments showed that these were due mainly to environmental (and not togenetic) effects. The latter was also true for age of maturity and rate ofchange in plant height. Lack of significant site × source interaction forthese characters indicated that plants did not differ in their plasticresponsesbetween sources at each site. Winter annual, biennial, triennial, and dicarpicand tricarpic perennial life histories occurred within populations in bothcommon garden and reciprocal transplant experiments. In the latter experiments,most matured plants were either biennials (most common) or winter annuals(second most common), with the order reversed in the former experiments due toamore benign environment favoring earlier maturity. The extensive phenotypicplasticity displayed by P. canadensis for phenology andlife history enables the species to inhabit a wide range of environments.     

Immunocytochemistry and laser capture microdissection for real-time quantitative PCR identify hindbrain neurons activated by interaction between leptin and cholecystokinin.

Current evidence suggests that leptin reduces food intake in part by enhancing the hindbrain neuronal response to meal-related gastrointestinal signals, including cholecystokinin (CCK), but the phenotypes of the relevant cells are not known. To identify neurons that participate in this interaction in the rat nucleus of the solitary tract (NTS), we induced c-Fos gene expression in NTS neurons with leptin and CCK. We focused on NTS catecholamine neurons because these cells have been implicated in the feeding response to CCK. Hindbrain sections from rats that received CCK with or without leptin pretreatment were immunostained for c-Fos and tyrosine hydroxylase (TH) by a double immunofluorescence procedure. Leptin pretreatment increased the number of NTS cells expressing c-Fos-like immunoreactivity (cFLI) 3-fold relative to CCK alone, but the number of TH-positive cells with cFLI was increased 6-fold. Next, cells detected by immunofluorescence for TH were collected by laser capture microdissection and pooled for real-time quantitative PCR of c-Fos mRNA. Here, neither le0ptin nor CCK alone affected the relative amount of mRNA in the TH cell-enriched samples, but leptin plus CCK substantially increased c-Fos mRNA content. These histochemical findings identify hindbrain catecholamine cells as potential mediators of the interaction between leptin and CCK.     

Serologic evidence of Encephalitozoon cuniculi infection in a colony of squirrel monkeys (Saimiri sciureus)

Five hundred seventeen serum samples obtained during 3 years from a collection of 250 squirrel monkeys were examined by indirect immunofluorescence and dot-ELISA for antibodies to Encephalitozoon cuniculi. One hundred seventy-nine monkeys were positive at least once and fifty six monkeys were positive three or more times. Older animals were more likely to be positive than young animals, but the proportion of serologically positive monkeys did not change appreciably over the 3 years. As judged by the serological evidence, infection with E. cuniculi is distributed widely in this collection of squirrel monkeys.     

Cross-linking of the (Ca2+ + Mg2+)-ATPase protein.

The addition of cupric-1,10,-phenanthroline, a cross-linking catalyst, to sarcoplasmic reticulum membranes caused protein sulfhydryl groups to form disulfide bridges. Following a short exposure to the catalyst (15 s, 22 degrees C) most of the protein was in a dimeric form (Mr = 248 000). Longer exposure times resulted in the formation of trimers, tetramers and other oligomers too large to enter the gel. At low temperatures (4 degrees C) dimer formation predominates even for exposure times as long as 5 min. Cross-linking in the presence of 7.5 mM Triton X-100 (a concentration that resulted in clearing of the membrane suspension and thus solubilization of the membrane components) showed the appearance of a considerable dimer fraction, however, most of the (Ca2+ + Mg2+)-ATPase protein appeared as a monomer. Following 1 min of cross-linking at 22 degrees C, freeze-etched membranes showed no alteration in the number or appearance of 80 A intramembranous particles. Thus extensive cross-linking of the (Ca2+ + Mg2+)-ATPase protein can occur without disruption of the normal position of the intramembrane portion of the molecule.     

Comparative morphology and physiology of fruit and seed development in the two shrubs Rhus aromatica and R. glabra (Anacardiaceae)

Morphology and physiology of fruit and seed development were compared in Rhus aromatica and R. glabra (Anacardiaceae), both of which produce drupes with water-impermeable endocarps. Phenology of flowering/fruiting of the two species at the study site was separated by ∼2 mo. However, they were similar in the timetable and pattern of fruit and seed development; it took ∼2 mo and ∼1.5 mo for flowers of Rhus aromatica and R. glabra, respectively, to develop into mature drupes. The single sigmoidal growth curve for increase in fruit size and in dry mass of these two species differs from the double-sigmoidal one described for typical commercial drupes such as peach and plum. Order of attainment of maximum size was fruit and endocarp (same time), seed coat, and embryo. By the time fruits turned red, the embryo had reached full size and become germinable; moisture content of seed plus endocarp had decreased to ∼40%. The endocarp was the last fruit component to reach physiological maturity, which coincided with development of its impermeability and a seed plus endocarp moisture content of <10%. At this time, ∼50, 37, and 13% of the dry mass of the drupe was allocated to the exocarp plus mesocarp unit, endocarp, and seed, respectively. The time course of fruit and seed development in these two species is much faster than that reported for other Anacardiaceae, including Rhus lancea, Protorhus, and Pistacia.     

DORMANCY IN SEEDS OF FRASERA CAROLINIENSIS (GENTIAN ACEAE)

In freshly matured seeds of the long-lived monocarpic perennial, Frasera caroliniensis Walt., the embryos are underdeveloped and physiologically dormant. Dormancy was broken by a long period of stratification (chilling) at 5 C. Seventy six percent of the seeds germinated at 20 C (day)/10 C (night) after 98 days of chilling at 5 C, while seeds kept at 5 C germinated to 87% after 205 days. A warm, moist pretreatment was not required for subsequent breaking of dormancy at 5 C. Embryos in fresh seeds averaged 1.3 mm long, but after 12 weeks of chilling they averaged 4.1 mm. Thus, the embryos require a period of chilling to become fully developed, after which seeds can germinate at the afterripening temperatures (5 C) or at some higher temperature. Seeds of F. caroliniensis fit Nikolaeva's (1977) morpho-physiological complex dormancy type.     

Seed dormancy and germination in the giant Himalayan lily (Cardiocrinum giganteum var. giganteum): an assessment of its potential for naturalization in northern Japan

Understanding the potential for ornamental plant species to become naturalized in a nonnative habitat requires information on seed germination in order to help predict responses of the species to the natural environmental conditions of its new habitat. Cardiocrinum giganteum var. giganteum, which is native to the Himalayas, has been introduced as an ornamental plant in temperate regions of the world, and was categorized recently as invasive in New Zealand. Seed germination requirements of the species were determined under natural conditions in Hokkaido, Japan, to assess its potential to become naturalized in this region of Japan. Mature seeds were collected from its native range in the Indian Himalayas. At maturity in autumn, seeds had underdeveloped embryos, which grew in the second autumn and winter after exposure to summer temperatures. Radicles and cotyledons emerged in late winter and spring. Thus, an 18?C19?month period was required from dispersal to seed germination. Under laboratory conditions, this period could be shortened to 10?C11?months in a 25/15?°C (120?days)????15/5?°C (90?days)????0?°C (90?days)????15/5?°C (60?days) temperature sequence. GA₃ did not substitute for the above temperature requirements. These temperature requirements for seed germination of C. giganteum var. giganteum are very similar to those of its native Japanese congener C. cordatum var. glehnii. Seeds of both taxa have deep simple morphophysiological dormancy. The close similarity in the requirements for regeneration from seeds of the two taxa suggests that the seed stage of the life cycle is not an impediment to the naturalization of the giant Himalayan lily in northern Japan.     

Variation in seed dormancy and germination among populations of Silybum marianum (Asteraceae)

Milk thistle (Silybum marianum) is a medicinal plant; however, lack of consistency in past dormancy studies has hindered propagation of this species from seeds. We tested the germination responses of freshly harvested and after-ripened (stored for 2 and 7 months; 25°C at 50% relative humidity) seeds from three populations (P1, P2 and P3) in Iran at varying constant or alternating temperatures, with or without GA₃ and in light and continuous darkness. No germination occurred in freshly harvested seeds incubated at any condition without GA₃ application, indicating that all the seeds were dormant. Seeds from P1 and P2, which developed under relatively dry, warm conditions, germinated over a wider range of temperatures after 2 months of dry storage, indicating type 6 of non-deep physiological dormancy (PD). Seeds from P3, which developed under relatively wet, cool conditions, incubated at constant temperatures (especially on GA₃), exhibited an increase in maximum temperature for germination, indicating type 1 of non-deep PD. Light improved germination of after-ripened seeds, and GA₃ application substituted for the light requirement for germination. This is the first report that environmental conditions during seed development may be correlated with differences in the type of non-deep PD. We conclude that milk thistle seeds are positively photoblastic and photodormant and the germination responses of after-ripened seeds from different populations are different under darkness. Therefore, the impacts of genetic differences and maternal effects on the induction of dormancy during seed development should be considered in attempts to domesticate this medicinal plant.