Changes of axillary meristem localization in relation to flowering ofRaphanus sativus L. after GA treatment

Two phases of radish ontogenesis (I-when the plant had produced 3 –5 nodes and II-when the plant had produced 8 –10 nodes) were established on the basis of axillary, meristem localization. Flowering of the plants in response to GA treatment depends on the phases in which they were treated and on growth correlations in the apical meristem. The results obtained suggest that the reaction ofRaphanus sativus (LDP) to GA treatment is parallel to that ofChenopodium rubrum (SDP), and that the response of radish plants also depends on changes in growth correlations in the shoot apical meristem at the time of treatment.     

Reactions and resistance ofChenopodium species to tobacco mosaic virus

Chenopodium species react on infection with tobacco mosaic virus by the formation of chlorotic or necrotic lesions and later by the abscission of infected leaves. A transition of local infection into the stem has been observed exceptionally inChenopodium quinoa, C. hybridum, andC. rubrum, but no systemic infection of the leaves followed. Systemic infection was demonstrated only inC. polyspermum andC. murale. The recovery of new sprouts was demonstrated in C.murale in the late chronic phase of infection.     

Ethylene production and metabolism of 1-aminocyclopropane-1-carboxylic acid in a long-day plant,Chenopodium murale L., as influenced by photoperiodic flower induction

Chenopodium murale plants, induced to flower by 5 days of continuous light, produced 43% more ethylene than vegetative plants kept under short days (16 h darkness, 8 h light). The 1-aminocyclopropane-1-carboxylic acid (ACC)-induced ethylene production, using saturating ACC concentration (10 mol·m⁻³) was also 55% higher in induced plants. Their ACC and N-malonyl-ACC (MACC) levels were also higher, the former increasing by 56% in both shoots and roots, the latter by 288% and 108% in shoots and roots, respectively. Administration of labeled [2,3-¹⁴C]ACC produced a very similar relative content of ACC and MACC in both treatments. The only process influenced by flower induction was ACC conversion to ethylene. Induced plants converted 66% more ACC than the vegetative ones. The effects of photoperiod on ethylene formation and metabolism in a long-day plant (LDP)C. murale and a short-day plant (SDP)C. rubrum are compared. Ethylene formation seems to be under photoperiodic control in both species, but its role in flower induction remains obscure.     

Differential in vitro development of inflorescences in long and short day Lemna spp.: involvement of ethylene and polyamines

In vitro-development of Lemna inflorescences on minimal medium is known to differ in long day (LDP) and short day (SDP) plants (Z. Pfl, physiol. 77, 395). In LDP pistil growth predominates, while in SDP stamen growth predominates. This indicates that LDP and SDP inflorescences differ in endogenous hormones and depend for a balanced male-female development on different plant-supplied factors (Z. Pfl. physiol. 80, 283 and 298). Here inflorescences of the LDP L. gibba and the SDP L. aequinoctialis were tested for differences in ethylene-polyamine (PA) relations, as ethylene and PAs are inversely related (shared precursor, mutual inhibition of synthesis), and exogenous ethylene has been shown previously to restore male-female balance in SDP inflorescences (Z. Pfl. physiol. 80, 283). Promotion of pistil or stamen growth indicates a predominance of ethylene and PAs in LDP and SDP, respectively. Hence, in LDP, exogenous PAs and inhibitors of ethylene synthesis, and in SDP, an inhibitor of PA-synthesis, were applied to restore the male-female balance in vitro. In L. aequinoctialis (SDP), application of methylglyoxal-bis(guanylhydrazone) (MGBG), an inhibitor of spermidine (SD) synthesis, resulted in near normal development via stamen inhibition and/or pistil promotion. In L. gibba (LDP), ethylene inhibition was effective, especially by aminoethoxyvinylglycine (AVG), which reduced pistil growth. Effects of alpha-aminooxyacetic acid (AOA) were less clear. Putrescine (PUT) promoted stamen growth under certain circumstances, perhaps acting as a precursor for the more active SD. SD effects were concentration-dependent for pistil and stamen. Most importantly, increases in SD turned pistil promotion into inhibition and almost normalised floral development. Spermine (SM) enhanced stamen growth. Results are conclusive that PA-ethylene relationships are involved in inflorescence development in a contrasting manner in LDP and SDP. It is apparent that in whole plants the LDP supplies the inflorescences with factors inhibiting ethylene and/or stimulating PA-synthesis. In SDP the converse is true.     

Promotive effect of abscisic acid in flowering ofChenopodium rubrum as the result of decreasing apical dominance

Abscisic acid (ABA) was applied in a concentration of 1. 10^?3 M and 1. 10^?4 M to the quantitative SD plantChenopodium rubrum under various light regimes. ABA did not influence flowering in plants under continuous illumination, enhanced flowering in plants subjected to long days and inhibited it in plants induced by short days. It was concluded that ABA can not substitute for inductive treatment but its action may be additive to initial stages of reproductive morphogenesis (enhanced growth rate and branching of the apical meristem) as evoked by long days.     

Exoamylase activity in vacuoles isolated from pea and wheat leaf protoplasts

Vacuoles isolated from pea (Pisum sativum), and wheat (Triticum aestivum) leaf protoplasts contained considerable activities of electrophoretically highly mobile exoamylases. Vacuoles from spinach (Spinacia oleracea) leaf and photoautotrophic Chenopodium rubrum suspension culture cell protoplasts were devoid of amylolytic activity. Endoamylase activity was in all cases associated primarily with the chloroplast.     

Antioxidative and cytotoxic potential of some Chenopodium L. species growing in Poland

The cytotoxic and antioxidant properties of lipophilic compounds extracted from different parts of four Chenopodium L. (Chenopodium album, Chenopodium hybridum, Chenopodium rubrum and Chenopodium urbicum) species were evaluated. The highest phenolic content was found in herb and seeds of all examined plants. Large amounts of free polyphenols were observed in herb extracts of C. album (3.36 mg/g DW), seeds of C. urbicum (3.87 mg/g DW) and roots of C. urbicum (1.52 mg/g DW). The cytotoxic activities of the extracts were assessed against human lung carcinoma A-549 and ovarian carcinoma TOV-112D and normal human fibroblast cell lines. Our study demonstrated that the extracts from the herb of C. rubrum and C. urbicum had the best antioxidant effect of all the extracts analyzed. Most of the extracts tested exhibited low cytotoxicity. However, the extracts from herb and seeds of C. album and C. hybridum showed the significant antiproliferative effect on the TOV-112 cell line.It can be concluded that antioxidant activity and phenolic composition differ mainly between plant parts and are quite similar between the plants, when the same plant part is analyzed. Thus, the Chenopodium extracts could be used as a readily accessible source of natural antioxidants, and may be used in the pharmaceutical industry and for food supplements production.     

The incorporation of uridine-3H into the shoot apices of photoperiodically induced and non-induced plants ofChenopodium rubrum L.

The influence of photoperiodic induction on the incorporation of uridine-³H into the shoot apices ofChenopodium rubrum was studied using the technique of autoradiography. No increase in uridine incorporation was detected either during induction lasting three days or immediately after its termination. Pyroninophylia likewise did not rise. However, changes in uridine incorporation related to morphogenetic activity during leaf formation and later during differentiation of inflorescences were well marked. The distribution of label in the nucleus immediately after three inductive cycles shows the ratio of extranucleolar to nucleolar incorporation to be higher in non-induced control plants than in induced ones. Data from literature pointing to an activation of RNA synthesis during transition to flowering are discussed and compared with other systems where ontogenetic changes are accompanied by marked changes in RNA synthesis. It is assumed that the activation of RNA synthesis after induction is connected mainly with the activation of growth. However, inChenopodium rubrum photoperiodic induction proceeds together with limited growth and without activation of RNA synthesis.     

The effects of hormones and saccharides on growth and flowering of green and herbicides-treatedChenopodium rubrum L. plants

The medium forin vitro culture of green and SANDOZ herbicides-treatedChenopodium rubrum L. plants contained saccharides and hormones in different concentrations. Five days after sowing, the plants were exposed to non-inductive (15 long days—LD) or inductive (6 short days—SD + 9 LD) photoperiodic conditions. The length of hypocotyl and cotyledon blade were measured and percentage of flowering was scored. Gibberellic acid (GA₃) stimulated hypocotyl growth of green and photobleached plants under SD and inhibited under LD conditions. Indole-3-acetic acid (IAA) slightly stimulated hypocotyl growth of green plants only under LD conditions. Benzylaminopurine (BAP) inhibited hypocotyl growth regardless of photoperiodic regime. The optimal concentration of glucose or saccharose for flowering in green and SANDOZ-treated plants was 5%. In green SAN 9785-treated plants exogenous saccharides compensated lack of photosynthates to bring about full flowering, but SAN 9789-treated plants needed in addition GA₃.     

Dimorphism in trichome production of <Emphasis Type="Italic">Persicaria lapathifolia</Emphasis> var. <Emphasis Type="Italic">lapathifolia</Emphasis> and Its multiple effects on a leaf beetle

Polymorphisms in plants are main factors that determine the diversity of associated animal communities and their population dynamics. Typically, Persicaria lapathifolia var. lapathifolia (Polygonaceae) has no trichomes on leaf surfaces (glabrous type), but a hairy type does sometimes occur. Based on a cultivation experiment, the presence or absence of trichomes is clarified to be under genetic control. To reveal the defensive function of trichomes against herbivores, laboratory experiments were conducted using a major herbivore, Galerucella grisescens (Coleoptera: Chrysomelidae). In both choice and no-choice feeding tests, the glabrous type was significantly more consumed by G. grisescens adults, while the hairy type was not consumed. In the hairy leaf treatment, larval duration tended to become longer, the adult body weight became significantly lower, and adults laid significantly more eggs than in the glabrous leaf treatment. Hairy leaves contained significantly more total phenolics and condensed tannins than glabrous leaves, suggesting that the hairy type allocates more resources for physical and chemical defence. Because no significant differences in leaf consumption were detected in the feeding experiment using powdered host leaves, G. grisescens seems to have adapted to the chemical defences of P. lapathifolia var. lapathifolia. These results clearly indicate that leaf trichomes of P. lapathifolia var. lapathifolia effectively act as a physical defence against G. grisescens.     

Characterization of intermediate biotypes in atrazine-susceptible populations of Chenopodium polyspermum L. and Amaranthus bouchonii thell. in Hungary

Intermediate biotypes for atrazine herbicide resistance in Chenopodium polyspermum and Amaranthus bouchonii were characterized by a peculiar chlorophyll fluorescence induction curve. The intermediate biotypes were isolated from progenies of susceptible plants in maize grown in alternate years without atrazine. The lethal dose in seedling treatments was lower than that of the resistant plants but higher than for susceptible plants. Atrazine at 10 μM was near the I₅₀-value for in vivo nitrite reductase activity in both intermediate biotypes. The activity of nitrite reducttase in the intermediate biotypes was about 75% of that of susceptible biotypes. These characteristics of intermediate biotypes were maternally inherited in crosses.     

The changes in the growth pattern of organs ofChenopodium rubrum photoperiodically induced to flowering

The relationship between photoperiodically changed growth of leaves, cotyledons, hypocotyl, roots and flowering has been investigated inChenopodium rubrum. It was found that all the growth characteristics recorded in leaves and cotyledons,i.e. length, area, dry weight and chlorophyll content, were inhibited during three inductive photoperiods (16 h darkness, 8 h light-SD) as compared with control plants grown under continuous illumination. Similarly, the cessation of root elongation and a decrease in root dry weight were observed. On the contrary, the elongation and dry weight of hypocotyl are stimulated by SD. The degree of the effect exerted by SD on the growth of different organs depends both on actual growth stage and the number of SD photoperiods. Increased relative rate of growth of roots and cotyledons was recorded in plants transferred after SD treatment to continuous illumination. However, this rise possesses only transitional character and the relative growth rate of treated plants equals that of control ones afterwards. The above growth changes are discussed as a possible modifying factor of floral differentiation.     

Organ correlations and flowering in chenopodium rubrum L.

Correlations within a shoot ofChenopodium rubrum L. ecotype 374 grown under continuous light or photoperiodic flower induction were studied using surgical treatments. Removal of a single pair of shoot organs had a variety of effects depending on position: significant changes in the number of leaf pair on the main axis or in axillary buds and in the height of shoot apices; or no effect on the parameters scored. Flowering was not affected by any of the treatments carried out. Decapitation brought about a significant increase in the number of leaf pairs in axillary buds and flowering was inhibited in 8- and 9-d old plants. Flowering was not affected in 21-d old plants. The role of shoot organ correlations, especially that of apical dominance, in regulation of flowering inC.rubrum is discussed.     

Somatic embryogenesis in Chenopodium rubrum and Chenopodium murale in vitro

In order to establish an efficient system for in vitro plant regeneration of a short day plant Chenopodium rubrum L. and a long day plant Chenopodium murale L., optimum culture conditions for somatic embryogenesis were investigated. The effects of different growth regulators, their combination and their concentrations on somatic embryos induction in different explant types (root, hypocotyl, cotyledon and leaf) were tested. Somatic embryogenesis was induced in both plants on Murashige and Skoog (MS) medium supplemented with sucrose (3 %), agar (0.7 %) and 1 - 10 M 2,4-dichlorophenoxyacetic acid (2,4-D) as the sole growth regulator. The largest embryogenic capacity was found in root explants of Chenopodium rubrum on 1 M 2,4-D and in basal parts of cotyledons in C. murale plants on 10 M 2,4-D.     

The Growth of the Shoot Apex of Chenopodium rubrum L. Treated with a Florigenic Extract from Flowering Tobacco Plants: Preliminary Anatomical Observations

Anatomical changes in the shoot apex of Chenopodium rubrum L.treated with an extract from flowering tobacco plants and cultivatedin non-inductive conditions are described. They are comparedwith the anatomy of non-treated vegetative apices and with apicesof plants induced with a short day. Treatment with the extractresulted in both activation of cell division in the upper partof the apex and in apex elongation. Acceleration of leaf primordiainitiation and stimulation of branching took place. The effectcorresponds to the sequence of changes in photoperiodically-inducedplants but is more pronounced. Elongation following 10^–4M GA₃ treatment was of a differentnature; there was only a slight stimulation in the upper partof the apex in contrast with a strong stimulation of growthin length in the lower internodes. These preliminary resultssuggest a similarity between apical changes evoked by a stimulusproduced by short days and an exogenously applied floral stimulus.The changes differed from those caused by exogenous phytohormones. Key words: Chenopodium rubrum, florigen, shoot apex     

The mosaic disease of mullein,Verbascum thapsiforme Schrader,occurring in Czechoslovakia

Field infected mulleins (Verbascum thapsiforme) exhibit dark green mosaic spots or blotches in leaves, stunting and slight reduction in leaf size. The disease inducessome reduction in flower formation depending on the stage, at which infection has taken place. Authors succeeded in mechanical transmission of the virus to fourteen out of fourty-four species tested including seven scrophulariaceous species,Chenopodium quinoa, C. giganteum, C. murale and C. polyspermum. The tests indicated that the thermal inactivation point lies between 51° and 55° C. Measurement of virus particles indicated the modal length 616 nm. Possibility of infection by further viruses is discussed.     

Effect of Darkness on Growth and Flowering of Chenopodium rubrum and C. murale Plants in vitro

Chenopodium rubrum, a short-day plant, and C. murale, a long-day plant, were grown in vitro in continuous darkness. Control C. rubrum plants exposed to continuous darkness for 15 d at cotyledonary phase, did not flower, while 80 % of plants flowered on the medium with 5 % glucose and 10 mg dm⁻³ GA₃. Control C. murale plants exposed to continuous darkness for 10 d at the age of 4^th pair of leaves, did not flower, while GA₃ (1 – 5 mg dm⁻³) stimulated flowering up to 65 %. This revised version was published online in July 2006 with corrections to the Cover Date.     

Localization of starch in shoot apices of vegetative and photoperiodically induced plants ofChenopodium rubrutn

Starch was determined by means of IKI reaction in shoot apices ofChenopodium rubrum plants induced to flowering by two short days and in non-induced plants. Small starch grains were already observed in the meristematic cells at an age of four days after sowing. Larger grains were found in the subapical region of the apex. Heterogeneity increases during further growth of the plants in induced, as well as in non-induced vegetative plants. Starch disappears from the cells potentially giving rise to axillary buds, while the number and size of starch grains increase in cells from which leaf primordia will be formed. This metabolic specifity of leaf and bud primordia is preserved during morphological differentiation and applies to vegetative, as well as to prefloral apices of photoperiodically induced plants. The amount of starch in the different regions of the apex is linked rather with organogenesis than with the quantitative growth in the apex.     

5-Fluorodeoxyuridine inhibition of photoperiodically induced flowering inChenopodium rubrum L.

Flowering in the short day plantChenopodium rubrum was inhibited by 5-fluoro-deoxyuridine (FDU) at a concentration of 4×10^?6 M and higher when applied during photoperiodic induction or immediately afterwards. This inhibition is always accompanied by a general reduction of growth (e.g. a decrease in the first leaf length). The mitotic activity within the shoot apex is completely blocked by FDU application during the photoperiodic treatment. The floral induction (evocationsensu Evans) was not cancelled in this situation as was revealed when reversing the FDU effect by thymidine application. One day after the end of the photoperiodic treatment (the plants were transferred to continuous light again) the FDU inhibition becomes irreparable. The results indicate that DNA synthesis and hence the mitotic activity are not obligatory prerequisites for photoperiodic floral induction inChenopodium. Low concentrations of FDU may promote flowering under suboptimal floral induction.     

Changes in the level of endogenous cytokinins in apical buds ofChenopodium rubrum L.

CCC (2-chloroethyl)trimethylammonium chloride applied to plants ofChenopodium rubrum during floral induction led to an increase in the level of endogenous cytokinins in the apical buds. Application of gibberellic acid or indole-3-acetic acid at concentrations reversing the effect of CCC reduced the level of cytokinins. After simultaneous treatment with both CCC and one of the growth substances this reduction was less pronounced. From the comparison bf the present results, as well as of those published in previous papers it follows that in apical buds ofChenopodium rubrum there exists a mutual interaction between gibberellins and cytokinins. Under certain conditions both these groups of hormones may substitute for each other in flowering. IAA seems to affect flowering by regulating the level of both gibberellins and cytokinins.