The role of endogenous cytokinins in correlation between cotyledon and its axillary bud and in hypocotyl regeneration of flax

When flax seedlings are decapitated above cotyledons and three days later one of the two cotyledons is removed then the remaining cotyledon stimulates in four to five days growth of its axillary bud. It has been found that content of endogenous cytokinins was higher in the stimulated bud as compared with the other one already 12 h after the cotyledon removal. Flax seedlings decapitated under cotyledons regenerate adventitious buds on thy hypocotyl stump during 5–6 days. The endogenous fytohormonal preparation of this regeneration was investigated in the 20 mm apical part of the hypocotyl stump. Decrease in auxin and increase in gibberellins was already found during the first day after decapitation while the level of cytokinins increased as late as three days after the apex removal.     

In vitro morphogenetic response and distribution of endogenous plant hormones in hypocotyl segments of snapdragon (Antirrhinum majus L.)

Snapdragon seedlings, 20 mm in length, were cut into 5 segments from the cotyledon to the root, which were cultured in vitro on hormone-free MS medium. Adventitious shoot formation was highest in the basal hypocotyl segments with stimulation by the addition of BA. Endogenous cytokinins were higher in the basal hypocotyl segments than in the two upper hypocotyl segments, whereas auxin content was higher in the two upper than in the basal hypocotyl segments. Ratios of cytokinins to auxin were also the highest in the basal hypocotyl segment. A general principle in in vitro culture that a high concentration of cytokinin and a low concentration of auxin promotes the induction of shoot morphogenesis was confirmed from measurements of endogenous growth regulator concentrations.     

辽东栎幼苗生长对种子大小和子叶去除处理的响应

该文在温室内盆播条件下,设置不去除子叶(对照)、去除1/4子叶(轻度子叶去除)、1/2子叶(中度子叶去除)和3/4子叶(重度子叶去除) 4个处理,研究了种子大小和子叶去除处理对辽东栎幼苗生长及其形态学可塑性的影响。结果表明:(1)大种子幼苗株高、基茎、叶片数、单株叶面积、总干质量和根冠比在所有处理均大于小种子幼苗,除株高外,上述其他参数在轻度子叶去除处理的不同大小种子幼苗间均差异显著(P0.05),前者总干质量在中度子叶去除处理与后者差异也显著(P0.05)。大种子幼苗比叶面积和比根长在各处理均大于小种子幼苗,比枝长则相反。(2)随着子叶去除强度增大,大、小种子幼苗株高、基茎、叶片数、单株叶面积和总干质量等均呈减小趋势,株高、基径、叶片数和单株叶面积在重度子叶去除处理均显著小于对照和轻度子叶去除处理;小种子幼苗对子叶损失反应更为敏感,其株高、叶片数、单株叶面积和总干质量在中度子叶去除处理也显著小于对照(P0.05);小种子幼苗根冠比随子叶去除强度增大而增大,在中度和重度子叶去除处理显著大于对照和轻度子叶去除处理(P0.05)。(3)随着子叶去除强度增大,大小种子幼苗的比叶面积和比根长均逐渐增大,但大种子幼苗比枝长持续减小,轻度子叶去除处理的小种子幼苗比枝长最大。     

Influence of the Embryonic Axis on Protein Hydrolysis in Cotyledons of Cucurbita maxima

Four-day time course studies of the hydrolysis of cotyledonal storage protein were conducted on intact seeds, seed cotyledons detached from their embryonic axes and on detached cotyledon pairs germinated in the presence of three excised embryonic axes of Cucurbita maxima Duch., cv. Chicago Worted Hubbard. Detached cotyledons germinated alone showed little hydrolysis of the storage protein. However, the amount of protein hydrolysis of the detached cotyledon pairs germinated in the presence of three excised embryonic axes was comparable to the amount hydrolyzed in the cotyledons of intact germinating seeds. Visual growth differences among these treatments were also evident. The size and yellow color intensity of the fourth day treatments were shown to increase in the following order: detached cotyledon pairs alone, intact seedlings, detached cotyledon pairs in the presence of three excised axes. The growth of the hypocotyl and radical was also modified by removal of the cotyledons. These findings suggest that storage protein degradation and cotyledonal growth are controled by the axis. They also indicate that the cotyledons have some influence on the growth of the axes. Time-course studies were made on the hydrolysis of storage protein in the cotyledons of squash and on the distribution of the hydrolytic products during the germination of light- and dark-grown plants. The storage protein was not hydrolyzed during the first 24 hours. It was hydrolyzed at a uniform rate from 1 to 5 days and at a slightly decreased rate from 5 to 7 days. Most of the hydrolytic products were transported to the axial tissue. Proteinase activity in the cotyledons rapidly increased during germination to a maximum level at 2 to 3 days. This was followed by a decline to about the initial value after 7 days.     

Effect of excess boron supply on germination and seedling growth of groundnut (Arachis Hypogaea Linn.)

Summary Groundnut (TMV-2) seeds treated with 25 ppm boron solution germinated more quickly than the seeds supplied with deionized water. The borontreated seedlings also elongated rapidly in the initial phase of the growth even though all their different organs contained excess boron contents (with chlorosis in the leaves) than those of the control seedlings. However, the accentuation in the growth of treated seedlings was proceeded only upto a certain period (12 days after treatment); but further stimulation in the later phase of the growth was almost inhibited with ever increasing amounts of boron in the hypocotyl, plumule and leaves (which were severely chlorotic) and even brought about a deleterious effect on the total growth at the end of 21 days when compared to the controls.     

Effects of temperature, light, storage conditions, sowing time, and burial depth on the seed germination of Cardiocrinum cordatum var. glehnii (Liliaceae)

In this study, we conducted experiments to accumulate practical information on the propagation and establishment of a population of Cardiocrinum cordatum var. glehnii by seed sowing. C. cordatum var. glehnii seeds require approximately 19 months from seed dispersal to cotyledon emergence in the field. However, the period from seed dispersal to radicle emergence was shortened to approximately 7–8 months by the temperature transition of 25/15°C (60 days) → 15/5°C (30 days) → 0°C (120 days) → 15/5°C (i.e., 15/5°C represents alternating temperature treatment wherein the seeds were placed at 15°C for 12 h during the day and then at 5°C for 12 h during the night). More than 90% of the seeds, which were stored dry at 5°C for 12 months and sown in pots in the field, showed cotyledon emergence, whereas in seeds stored dry at 25°C, dry at room temperature, and non-dry at room temperature, cotyledon emergence was decreased by less than 1%. More than 88% of the seeds that were stored dry at 5°C and sown in the field in October 2002 immediately after collecting, November, and from April to July 2003 showed cotyledon emergence in spring 2004. However, seeds sown in August, September, and October 2003 showed cotyledon emergences of 57.6%, 0%, and 0% in spring 2004, respectively. Seeds collected in October 2002 and sown until July 2003 in the field received adequate high temperature in summer, moderate temperature in autumn, and cold temperature in winter; therefore, the percentage of cotyledon emergence was high in spring 2004. On the other hand, seeds sown in August 2003 or later could not receive enough high temperature; thus, cotyledons emerged from only a few seeds.     

Seed germination time course and seedling development of Clintonia udensis Trautv. et Mey. (Uvulariaceae): a typical cool temperate woodland perennial in Japan

Seed germination time course and seedling development mechanisms of Clintonia udensis Trautv. et Mey. (Uvulariaceae) were investigated under experimental condition. Seed germination tests were carried out under four thermal regimes, i. e. 10, 15, 20, and 25°C, after seeds were harvested, and stored at 5°C in wet conditions for 6 months under light‐exposed or shaded conditions. Approximately 63% of all seeds produced had the potential to germinate beyond 4 years and 6 months. The developmental process after germination continued for over 2 years. Phase I: the radicle first breaks through the seed coat 2 years after fructification. Phase II: the radicle becomes much larger with a hypocotyle. Phase III: part of the cotyledon elongates over 20 mm. Phase IV: the plumule further develops in two steps, i. e. the plumule is first formed, while cotyledon is disappearing, and then the plumule appears with second and third radicles, growing with cotyledon.     

Seed germination and seedling growth of Zostera marina L. (eelgrass) in the chesapeake bay

Seed germination and seedling growth of Zostera marina L. were monitored in the Chesapeake Bay in 1979 and 1980. Harvested seeds were placed in small acrylic tubes at several sites representing the salinity range of Z. marina distribution. Seed germination was observed first in late September and continued through May, with peaks in the fall and spring. The majority of seeds that germinated (66%) did so between December and March when water temperatures ranged from 0–10°C. There was no correlation between sites (different salinity regimes) and frequency of germination rates, indicating that salinity was not a major factor in the germination process in this study. Additional information on seed germination was available for seeds collected in 1977 and 1980 and subsequently monitored for germination at only one site. These data were similar to germination frequency recorded in 1979–1980.Seedling growth was measured from individuals collected from an existing Zostera marina bed. Seedlings were collected from November through May, at which time we could no longer distinguish seedlings from existing vegetative stock. Growth was characterized by the increased length of the primary shoot, number of leaves per shoot and numbers of shoots per plant. Seedling growth was slow during the winter months (water temperature ? 10°C) but rapidly increased in the spring (temperatures > 10°C). The size range of the harvested seedlings indicated that seed germination in the field probably occurred from October through April, corroborating evidence from the seed germination experiments.     

Involvement of the Cotyledon in Adventitious Root Initiation in Impatiens balsamina L. Seedlings

Adventitious root primordia are found in the pre-hypocotyl tissueof developing seeds of Impatiens balsamina L. by the third weekafter petal drop, and are present in the mature seed. Aftergermination, the adventitious roots emerge from a collet swellingon the hypocotyl of the young seedlings. Removal of the colletduring the first five days results in the formation of anotherat the base of the remaining hypocotyl. Older seedlings respondto the excision of the collet by producing one or more rootsnear the cut end, unless the cut is made close to the cotyledon,when, even in nine-day seedlings, a reduced collet is formedassociated with four or fewer roots. The influence of the cotyledonon collet/root regeneration diminishes in older seedlings andin these is manifested only in hypocotyl tissue adjacent tothat organ. Impatiens balsamina, balsam, cotyledon, adventitious roots, collet     

GERMINATION ECOPHYSIOLOGY OF THE WOODLAND HERB OSMORHIZA LONGISTYLIS (UMBELLIFERAE)

Osmorhiza longistylis is an herbaceous perennial that grows in woodlands of eastern and central North America. In northcentral Kentucky seeds ripen in early to mid July, and dispersal begins in September and October. Although most of the seeds are shed during late autumn and winter, some remain on the dead shoots for up to 18 months. Seeds are dormant at maturity due to an underdeveloped embryo. Embryos grew at low (5 C) temperatures, but only after seeds were given a period of warm (30/15 C) stratification. With an increase in the length of the warm treatment, there was an increase in the number of embryos that grew to full length during a 12-wk period at 5 C and an increase in the percentage of seeds that germinated. Seeds given 12 wk of warm stratification required more than 8 wk at 5 C to overcome dormancy. Embryos in freshly-matured seeds averaged 0.60 mm long, but those in seeds given 12 wk warm plus 12 wk cold stratification averaged 8.86 mm. Lengths of embryos of seeds kept moist at 30/15 and 5 C for 24 wk averaged 0.63 and 0.89 mm, respectively. Regardless of age and dispersal time, imbibed seeds must be exposed to high (i.e., summer or autumn) and then to low (i.e., winter) temperatures before they will germinate. Consequently, germination occurs only in spring.     

SEASONAL TRENDS IN RATES OF PHOTOSYNTHESIS AND RESPIRATION OF LOBLOLLY PINE AND WHITE PINE SEEDLINGS

Mc Gregor , William H. Davis (Clemson Coll., Clemson, S.C.), and Paul J. Kramer . Seasonal trends in rates of photosynthesis and respiration of loblolly pine and white pine seedlings. Amer. Jour. Bot. 50(8): 760–765. Illus. 1963.—Seasonal trends in the rates of photosynthesis and respiration of potted loblolly and white pine seedlings were studied by measuring CO₂ exchange with an infra-red gas analyzer at intervals during a year. The seedlings were kept out-of-doors, but measurements were made indoors at 25 C and 4000 ft-c of light. Beginning in February, the rate of photosynthesis per plant of both species increased, reaching a peak in mid-September for loblolly pine and in mid-July for white pine and then declining rapidly after mid-September for both species. The spring increase began before new needles emerged and the autumn decline was not accompanied by appreciable loss of foliage. The respiration rate of loblolly pine increased steadily throughout the year. Respiration of white pine increased until mid-May and then remained fairly constant through the remainder of the year. Maximum rate of photosynthesis per unit of fascicle length occurred in July for the white pine and in May for the loblolly pine, and rates declined after September in both species. Respiration rate per unit of fascicle length showed a marked increase as spring growth began in April, then decreased to a minimum in September and increased during the winter in both species. Total chlorophyll per seedling reached a maximum in September for both species and declined slightly during winter. Total chlorophyll per unit of fascicle length increased in the spring, declined slightly in midseason, and increased again in September. Photosynthesis per unit of chlorophyll reached a maximum in May for loblolly pine and in July for white pine. Stem elongation of white pine was 88% completed by May 15. On the same date, stem elongation of loblolly pine was only 42% completed.     

Cytopathology of Lettuce Mosaic Virus-infected Lettuce Seeds and Seedlings

The ultrastructure of lettuce mosaic potyvirus (LMV)-infected lettuce seeds and seedlings was studied by transmission electron microscopy. Conventional thin-section electron microscopy and immunogold cytochemistry were both successfully employed to study the location of LMV in embryonic and non-embryonic seed parts. LMV particle aggregates and cytoplasmic “pinwheel” inclusions characteristic of potyviruses were observed throughout the embryonic tissues (radicle, hypocotyl and cotyledon) of infected lettuce seeds and seedlings, and also in the non-embryonic endosperm layer. LMV particles, but not inclusions, were also located in the non-embryonic pericarp layer.     

Potent endogenous allelopathic compounds in Lepidium sativum seed exudate: effects on epidermal cell growth in Amaranthus caudatus seedlings

Many plants exude allelochemicals--compounds that affect the growth of neighbouring plants. This study reports further studies of the reported effect of cress (Lepidium sativum) seed(ling) exudates on seedling growth in Amaranthus caudatus and Lactuca sativa. In the presence of live cress seedlings, both species grew longer hypocotyls and shorter roots than cress-free controls. The effects of cress seedlings were allelopathic and not due to competition for resources. Amaranthus seedlings grown in the presence of cress allelochemical(s) had longer, thinner hypocotyls and shorter, thicker roots--effects previously attributed to lepidimoide. The active principle was more abundant in cress seed exudate than in seedling (root) exudates. It was present in non-imbibed seeds and releasable from heat-killed seeds. Release from live seeds was biphasic, starting rapidly but then continuing gradually for 24 h. The active principle was generated by aseptic cress tissue and was not a microbial digestion product or seed-treatment chemical. Crude seed exudate affected hypocotyl and root growth at ~25 and ~450 μg ml(-1) respectively. The exudate slightly (28%) increased epidermal cell number along the length of the Amaranthus hypocotyl but increased total hypocotyl elongation by 129%; it resulted in a 26% smaller hypocotyl circumference but a 55% greater epidermal cell number counted round the circumference. Therefore, the effect of the allelochemical(s) on organ morphology was imposed primarily by regulation of cell expansion, not cell division. It is concluded that cress seeds exude endogenous substances, probably including lepidimoide, that principally regulate cell expansion in receiver plants.     

Seed germination characteristics of Maianthemum dilatatum (Wood) Nels. et Macbr. (Asparagaceae)

The seed germination characteristics of Maianthemum dilatatum were investigated in a laboratory experiment and the results compared with those of other species in the subfamily Asparagoideae, LILIACEAE (Engler's system). M. dilatatum seeds mature in late September to October in montane to subalpine areas across Japan. Germination percentages and rates were low for fresh seeds at 10 to 30°C. Seeds cold stratified for 4 months or longer showed increased germination percentages and rates. The seeds lost germinability with decreasing moisture content. The seeds germinated well in dark conditions. The process of germination from the cotyledonary sheath/petiole breaking through the seed coat to the appearance of the first and second leaves was examined. After emergence of the cotyledonary sheath/petiole, a root emerged from it, and additional roots appeared after 1–2 months. The plumule emerged from the cotyledonary sheath/petiole after the seedling had three roots. Seeds dispersed in autumn, and germinate slowly in the next spring after exposure to low temperature even though dark condition as buried seed. We compared the seed germination characteristics among species in the Asparagoideae or with other recent taxonomy, and found that seedlings of Paris verticillate and Trillium apetalon, which belong to Melanthiaceae, and Streptopus streptopoides Var. japonica and Clintonia udensis, which belong to Liliaceae (linear cotyledon), were different from Asparagaceae, showing a globose cotyledon in the APG II.     

Changes in the content and distribution, in different organs, of the flavour precursors, the S-alk(en)yl-L-cysteine sulphoxides, during seedling development of onions (Allium cepa) grown under light and dark regimes

Flavour precursors accumulated rapidly in onion seedlings ( Allium cepa L. cv. Pukekohe Longkeeper, May and Ryan) after emergence of the cotyledon. (±)-S-1-Propyl-L-cysteine sulphoxide, found mainly in the shoots, was the predominant flavour precursor. (±) Trans -S-1-propenyl-L-cysteine sulphoxide was important during very early seedling growth when very high concentrations were reported in the root and hypocotyl. (±)-S-1-Methyl-L-cysteine sulphoxide, a minor component in seedlings grown under a normal light regime, was significant during early cotyledon development in seedlings grown in the dark. It is concluded that onion seedlings would be a suitable tissue in which to investigate the biosynthetic pathways of the S-alk(en)yl-L-cysteine sulphoxides.     

Early life history timings in marbled rockcod (Notothenia rossii) fingerlings from the South Shetland Islands as revealed by otolith microincrement

Although it has been reported that Notothenia rossii elsewhere hatches in spring, our daily increment back-counting from the capture date in otoliths of fingerlings caught in Potter Cove, South Shetland Islands, in the 2000s, showed two main periods of larval hatching, one in summer (February–March) and another in winter (July). In concordance, the simultaneous presence of two cohorts born the same year was identified in the age/length frequency distribution of fish sampled in spring 2010, which belonged to biological ages 0+ and 1+ and hatched, respectively, in summer and winter–spring. Maximum and minimum ages of pelagic blue-phase and demersal brown-phase fingerlings were, respectively, 227 and 240 days, indicating a demersal settlement after about 8 months from hatching. The estimated growth rate was 0.23–0.33 mm/day, equivalent to that of South Georgia fingerlings and higher than those of other nototheniids of similar size range. Based on early life events associated with the hatching periods, two types of life cycles are hypothesised for South Shetland fingerlings. The pelagic blue-phase fingerlings (6.5–7.6 cm TL, age group 0+) hatched in July (winter cohort), entering in Potter Cove in February–March. The brown-phase fingerlings (6.3–10.6 cm, mostly of age group 0+) hatched in February–March (summer cohort) and were collected in the cove in spring (the smaller specimens) or in summer (the larger ones). Finally, early juveniles (10.7–15.5 cm, age group 1+) hatched in winter, mainly in July (winter cohort), entering in the cove the following year to spend the second winter inshore.     

黑果枸杞种子萌发及幼苗生长对盐胁迫的响应

研究不同浓度(0、1、2、3、6、9、14、18g.L-1)的盐溶液(NaCl、MgSO4、盐渍土壤)对河西走廊中部荒漠边缘的黑果枸杞种子吸胀、萌发和幼苗生长的影响,并观察胁迫解除后种子的反应。结果表明:黑果枸杞种子吸胀速率随NaCl、MgSO4和土壤溶液浓度的增大呈先升后降的趋势,吸水速度随胁迫时间的延长而减慢;种子萌发率随3种盐浓度的增大而降低,盐胁迫解除后种子仍具有较高的萌发率;发芽指数、活力指数、根长、下胚轴随3种盐浓度的增大而降低或先升后降,根轴比随盐胁迫的增强先升后降;随3种盐浓度的增大,种苗损害率增大,3种盐的胁迫效应依次NaCl>MgSO4>盐渍土壤溶液。黑果枸杞种子萌发和幼苗生长对NaCl胁迫较为敏感,其耐受的临界阈值是6g.L-1;种子萌发能耐受较高浓度的MgSO4的胁迫,幼苗生长对MgSO4胁迫较敏感,其耐受的临界阈值是9g.L-1;种子萌发和幼苗生长对生境盐渍土壤具有较强的耐受能力和适应性。     

Morphological Response of Witchweed (Striga asiatica) to In Vitro Culture

Excised sorghum root segments (5–10 mm in length) werecultured for 50 d in four different liquid media containingmineral salts, vitamins, amino acids, glucose, and IAA. Theroots were removed and the remaining medium was solidified withan equal volume of warm 1–6% water agar. Dry unconditionedor conditioned Striga asiatica seeds were transferred to themedium. Some of the seeds germinated and developed into parasitic-typeseedlings. These seedlings had haustoria, tubercles, dense roothairs, branched shoots, and multiple shoot-borne adventitiousroots. The plumule pole developed into a shoot, but the radiclepole displayed only rudimentary development. On the same media,but which had not previously been used to grow sorghum roots,the seedlings displayed a well-developed radicle-derived rootsystem, but the plumule did not grow. Shoots began to appearon the roots only after 35–50 d of culture. These seedlingshad no haustoria, no tubercles, few or scattered root hairs,no shoot-borne adventitious roots and few shoot branches, andappeared to be non-parasitic-type seedlings. Shoots grew ina medium supplemented with IAA and kinetin, but did not in amedium containing NAA plus IBA. On replacement of glucose andIAA with sucrose and 2,4-D, respectively, Striga seeds germinated,and the heart-shaped embryos dedifferentiated into calli. Thecalli have been maintained by subculturing for over 9 months.The results demonstrated that a host signal, in addition tothose for germination and haustorium formation, is requiredfor further development. Moreover, morphogenesis of culturedS. asiatica is influenced by exogenous growth regulators. Key words: Striga asiatica, parasitic weeds, haustoria, Sorghum bicolor, in vitro culture     

Genetic Variation of Hypocotyl Length in the Brussels Sprout

A study was made of variation in the hypocotyl length of twoinbred lines of Brassica oleracea gemmifera (Brussels sprout).The pattern of means and variances obtained from parental, F₁,F₂ and backcross generations suggested polygenic control ofhypocotyl length. Measurements of parental seed weights, embryocell numbers, and the growth of seedlings from seeds of knownweight support the view that variation between the lines inhypocotyl length, when the seedlings were exposed to light,was determined by differential extension rather than by initialdifferences in seed weight. The effect of reduction in lightintensity on hypocotyl extension was studied and the differencesbetween the lines was maintained under all light intensities.Differential reaction of the lines was only observed when theperiod allowed for growth was short. The inbred line with thelonger hypocotyl was shown to suppress the other under competitiveconditions.