Photoperiodic control of growth, development and phytohormone balance in Solanum tuberosum

Some lines of Solanum tuberosum ssp. andigena are strictly photoperiodic, forming tubers only in short days and flowers only in long days. We used this advantageous phenomenon to study phytohormone involvement in the development of the plants, mainly that of tuber formation. Plants grown for 2 months under short days (SD) of 14 h darkness, night break (1 h white light in the middle of the 14‐h dark period) and continuous light (LD) were compared. Short day‐grown plants formed tubers, while plants in LD flowered. Night break prevented tuber formation, but caused flowering, although it was weaker than in LD. Plants grown under night break displayed many growth characteristics intermediate between SD and LD. Under LD and night break regimes ABA levels in all organs were about one‐fourth of those under SD. An opposite trend was found for gibberellin content: it was very low in SD‐grown plants and 4‐10 times higher under both other conditions with the exception of roots and stolons in night break. Thus, the ratio of ABA/GA, known to be important for tuber formation, was high in SD and low in night break and LD. The level of free indoleacetic acid (IAA) was high in LD‐ and night break‐grown plants and it was much lower in SD‐grown plants, including tubers. Cytokinin (CK) levels were also high in LD‐ and night break‐grown plants. In SD, leaves had slightly decreased and stems and roots + stolons had more pronouncedly decreased cytokinin levels. The CK/IAA ratio was thus higher in SD in stems and roots + stolons; it was also high in tubers and no difference was found in leaves. These results indicate that the effect of photoperiod on tuber formation and development may be mediated by photoperiod‐induced changes in hormone levels.     

激素对贯叶连翘器官分化的影响

贯叶连翘 (ＨｙｐｅｒｉｃｕｍｐｅｒｆｏｒａｔｕｍＬ .)为多年生草本 ,中国民间主要用于止血、抗炎、妇科病等[1] ,欧洲民间用于治疗创伤也有相当长的历史。近年来 ,欧、美等国家和地区将其应用于抑郁症的治疗 ,取得了很好的疗效。 80年代后期 ,由于发现该植物体内含有显著抗     

Exogenous fibronectin is not required for organogenesis in vitro

Summary The biological effect of plasma fibronectin on the differentiation of embryonic mouse kidney and tooth was studied in organ cultures. Transferrin (50μg/ml) was a strong mitogen for kidney cells, whereas, the addition of soluble fibronectin (50 to 250 μg/ml) had no detectable effect on differentiation or proliferation. The same serum-free, transferrin-containing medium did not support tooth differentiation. however, fibronectin was not a necessary serum component because fibronectin-free serum supported tooth development. It was demonstrated with antibodies specific for human fibronectin that the exogenously added human fibronectin at 50 μg/ml did not become incorporated to the cultured organs. Only minimal incorporation to the kidney basement membrane area was observed when fibronectin concentration was 250μg/ml. The mesenchymal stroma and the basement membranes of the kidney and tooth rudiments cultured in fibronectin-free media stained intensely with conventional fibronectin antibodies, indicating endogenous production of fibronectin. Outgrowing epithelial cells from isolated kidney tubules produced fibronectin as well as laminin. The results suggest that the fibronectin found in the stroma and basement membranes is an endogenous product of the developing tissues and that plasma fibronectin is not required for in vitro organogenesis. The results also indicate that it is difficult to study the effect of fibronectin on morphogenetic processes because it may not penetrate the organ explants in vitro. This work was supported by grants from the Sigrid Jusélius Foundation, Finska L?kares?llskapet, Finnish Life Insurance Companies and Grant CA 28896 and Cancer Center Support Grant CA 30199 from the National Cancer Institute, Department of Health and Human Services, Washington, D.C.     

Hormonal requirement and tissue competency for shoot organogenesis in two cultivars of Brassica napus

An investigation of the regeneration ability of explants taken from the floral stem of Brassica napus var. oleifera was performed in the winter cultivars Darmor and Bienvenu. Our purpose was to compare the regeneration ability of the two genotypes, to compare the competence of the different tissues of the stem and then to study histologically the regeneration of shoots. A strong genotypic effect was observed between the two cvs; Bienvenu had a poorer ability to produce shoots when cultured in the presence of benzyladenine: regeneration commenced later; the percentage of explants producing shoots and the number of shoots per regenerating explant were much lower. The comparison between the regeneration ability of different explants, i.e stem segments, internal stem segments, thin cell layer and peels, showed that the superficial tissues were able to regenerate roots but not shoots. Contrariwise, internal stem segments regenerated only shoots. The origin of shoots was investigated in stem segments of cv. Darmor. A kinetic histological analysis showed the basic role played by phloem and phloem-associated cells in shoot formation.     

Temporal requirement for hedgehog signaling in ventral telencephalic patterning

Hedgehog signaling is required for multiple aspects of brain development, including growth, the establishment of both dorsal and ventral midline patterning and the generation of specific cell types such as oligodendrocytes and interneurons. To identify more precisely when during development hedgehog signaling mediates these events, we directed the removal of hedgehog signaling within the brain by embryonic day 9 of development, using a FoxG1(Cre) driver line to mediate the removal of a conditional smoothened null allele. We observed a loss of ventral telencephalic patterning that appears to result from an initial lack of specification of these structures rather than by changes in proliferation or cell death. A further consequence of the removal of smoothened in these mice is the near absence of both oligodendrocytes and interneurons. Surprisingly, the dorsal midline appears to be patterned normally in these mutants. Together with previous analyses, the present results demonstrate that hedgehog signaling in the period between E9.0 and E12 is essential for the patterning of ventral regions and the generation of cell types that are thought to largely arise from them.     

Exogenous fibronectin is not required for organogenesis in vitro

The biological effect of plasma fibronectin on the differentiation of embryonic mouse kidney and tooth was studied in organ cultures. Transferrin (50 micrograms/ml) was a strong mitogen for kidney cells, whereas the addition of soluble fibronectin (50 to 250 micrograms/ml) had no detectable effect on differentiation or proliferation. The same serum-free, transferrin-containing medium did not support tooth differentiation. However, fibronectin was not a necessary serum component because fibronectin-free serum supported tooth development. It was demonstrated with antibodies specific for human fibronectin that the exogenously added human fibronectin at 50 micrograms/ml did not become incorporated to the cultured organs. Only minimal incorporation to the kidney basement membrane area was observed when fibronectin concentration was 250 micrograms/ml. The mesenchymal stroma and the basement membranes of the kidney and tooth rudiments cultured in fibronectin-free media stained intensely with conventional fibronectin antibodies, indicating endogenous production of fibronectin. Outgrowing epithelial cells from isolated kidney tubules produced fibronectin as well as laminin. The results suggest that the fibronectin found in the stroma and basement membranes is an endogenous product of the developing tissues and that plasma fibronectin is not required for in vitro organogenesis. The results also indicate that it is difficult to study the effect of fibronectin on morphogenetic processes because it may not penetrate the organ explants in vitro.     

Phenocritical times in the process of in vitro shoot organogenesis

Shoot organogenesis occurs when leaf explants of Convolvulus arvensis are cultured on Murashige and Skoog salts, sucrose, vitamins, and 0.05 mg/liter IAA with 7.0 mg/liter 2-isopentenyl adenine. Under the influence of this shoot inducing medium (SIM), the explants become competent for the organogenic effects of SIM and eventually become determined for shoot formation. The induction process includes five separate transient sensitivities to inhibitors. Such stage-specific inhibitions reflect phenocritical times in development rather than general metabolic toxicities. The phenocopying agents are tri-iodobenzoic acid (TIBA), sorbitol, ribose, ammonium ion, and acetylsalicylic acid. The process of in vitro shoot organogenesis from leaf explants is now seen to include a series of discrete steps which precede morphological differentiation. An initial dedifferentiation process results in the formation of competent callus tissue along the cut edges of the explant. Under the influence of the phytohormone balance in SIM, shoot organogenic induction proceeds. This process involves a time which is sensitive to inhibition by salicylates followed by a time sensitive to TIBA which is followed in turn by a time sensitive to sorbitol and culminates in cells or groups of cells determined for shoot formation. This process also includes a time sensitive to inhibition by ribose, although its place in the order of events is not yet firmly assigned. There is also a sensitivity to ammonium ion (or lack of nitrate) at or near the time the explant becomes determined for shoot production.     

The requirement for macrophages in the in vitro immune response

Previous work from this laboratory indicated that an adherent, light-density, radiation resistant “accessory” cell was required for an in vitro response of mouse spleen lymphocytes to sheep erythrocytes (SRC) but not to another antigen, polymerised bacterial flagellin (POL). This paper confirms this observation, and demonstrates that the “accessory cell” for a SRC response is a macrophage.     

In vitro control of organogenesis and body patterning by activin during early amphibian development

In the process of amphibian development, an embryonic body plan is established through cell division, sequential gene expression, morphogenesis and cell differentiation. The mechanism of body patterning is complex and includes multiple induction events. Activin, a TGF-beta family protein, can induce several kinds of mesodermal and endodermal tissues in animal cap explants in a dose-dependent manner. In a recent study of the role of activin in organogenesis, we succeeded in raising a beating heart by treating animal caps with a high concentration of activin. Activin also participates in kidney organogenesis in combination with retinoic acid. An embryonic kidney induced by activin and retinoic acid in vitro can function in vivo when it is transplanted into a larva in which pronephros rudiments have already been removed. Further, the activin-treated animal caps clearly show organizer actions that are closely related to body patterning along the anteroposterior axis. These experiments will help to serve as a model system for understanding organogenesis and body patterning at the cellular and molecular levels.     

Competence and determination in the process of in vitro shoot organogenesis

Leaf explants of Convolvulus arvensis produce shoots when cultured on Murashige and Skoog salts, sucrose, vitamins and 0.05 mg/liter IAA plus 7.0 mg/liter 2-isopentenyl adenine. Shoot-inducing, root-inducing, or callus-inducing medium (SIM, RIM, or CIM) will cause small amounts of callus to form at the cut edges of the explant. This first-formed callus is developmentally interchangeable: SIM induces shoots in callus formed on CIM or SIM with equal effect and efficiency. Once induction begins in competent callus, the callus is no longer interchangeable. Under the continued influence of SIM, cells, or groups of cells become determined for shoot formation. This determination is strongly canalized for shoot formation: subsequent transfer to root-inducing medium does not affect the formation of shoots by the explant. The control of organogenesis by the auxin/cytokinin balance must occur between the time the tissue becomes competent and the time it is determined for shoot (or root) development. It is not known whether this control is a single or multiple phenomenon.     

Cell fate switch during in vitro plant organogenesis

Plant mature cells have the capability to reverse their state of differenUation and produce new organs under cultured conditions. Two phases, dedifferentiation and redifferentiation, are commonly characterized during in vitro organogenesis.In these processes, cells undergo fate switch several times regulated by both extrinsic and intrinsic factors, which are associated with reentry to the cell cycle, the balance between euchromatin and heterochromatin, reprogramming of gene expression, and so forth. This short article reviews the advances in the mechanism of organ regeneration from plant somatic cells in molecular, genomic and epigenetic aspects, aiming to provide important information on the mechanism underlying cell fate switch during in vitro plant organogenesis.     

Effect of serum on organogenesis of the rat testis in vitro

Summary It was observed previously that primordia of fetal rat testes when explanted in vitro in a synthetic medium at the outset of sexual differentiation differentiate seminiferous cords during the following days, but that the addition of 15% fetal bovine serum prevents this morphogenesis. In the present study, human, horse, bovine calf, and rat sera were shown to exert the same effect. Very low concentrations of human or fetal bovine serum (0.5 or 1%) were sufficient to produce the serum effect, which was only slightly reduced when the serum was heated. The serum activity was not removed by dialysis (membrane cut-off 15 000), but it disappeared after treatment with trichloroacetic or perchloric acids or after trypsin digestion. Partial purification of the active factor(s) from human serum was achieved by successive gel filtration, affinity chromatography, and ion exchange chromatography. Analysis of the active fractions by electrofocusing and immunoelectrophoresis placed the activity within the α globulin group. Among a series of purified serum proteins tested, α₂-HS-glycoprotein was found to exhibit the serum effect, though this activity was heat labile.     

Energy requirement of bovine spermatozoa for in vitro capacitation

The oxidative energy requirements of bovine spermatozoa capacitated with dilauroil-phosphatidylcholine liposomes (PC 12) and the effect of these liposomes on acrosome reaction necessary for in vitro fertilization were studied. Mitochondrial respiration was measured using 3 different substrates (pyruvate-lactate-glucose) and endogenous substrates. The samples were either treated with PC 12 or were left untreated and used as the control. A 2.8-fold increase in the consumption of oxygen was observed in the PC 12 treated spermatozoa in the presence of the 3 combined substrates (pyruvate-lactate-glucose). Respiration changes were not observed when the spermatozoa were capacitated with only 2 of the 3 substrates or with glucose alone. When endogenous substrates were used, the consumption of oxygen increased 1.7 times, and mitochondrial uncoupling was observed in the treated samples. The hypermotility characteristic of the capacitation process was not observed when glucose or endogenous substrates were used. When the percentage of intact acrosomes was determined using differential-interferential contrast (DIC) microscopy, it was found that in the presence of oxidative substrates there was a 26% decrease compared with that of the control sample. The proportion of reacted acrosomes was in the range of 41.3 to 49.6%, as measured by the chlortetracycline epifluorescence method in the presence of calcium ionophore A23187. Only 4% of the spermatozoa showed acrosome reaction with endogenous substrates. A higher percentage of fertilized oocytes were observed when the spermatozoa were capacitated in the presence of the 3 substrates (pyruvate-lactate-glucose), confirming that the success of in vitro fertilization depends on the energy conditions associated with the capacitation process. The results of these experiments indicate that the presence of oxidative energy is necessary to produce capacitation and the hyperactivation characteristic in frozen-thawed bovine spermatozoa treated with liposomes.     

In vitro organogenesis and plant formation in cucumber

In vitro organogenesis was achieved from callus derived from hypocotyl explants of Cucumis sativus L. cv. Poinsett 76. Calli were induced from hypocotyl explants excised from 7-d-old seedlings grown on Murashige and Skoog (MS) medium containing 87.64 μM sucrose, 0.8 % agar, 3.62 μM 2,4-dichlorophenoxy acetic acid and 2.22 μM 6-benzyladenine (BA). Regeneration of adventitious buds from callus (25 shoots explant⁻¹) was achieved on MS medium supplemented with 8.88 μM BA, 2.5 μM zeatin and 10 % coconut water after two subcultures in the same medium at 30-d interval. Gibberellic acid (1.75 μM) favoured shoot elongation and indole 3-butyric acid (7.36 μM) induced rooting. Rooted plants were hardened and successfully established in soil.     

In vitro regeneration through organogenesis in Egyptian chickpea

Abstract

Genetic engineering for improvement of the recalcitrant crop chickpea (Cicer arietinum L.) was largely restricted by the lack of an efficient regeneration system. In vitro regeneration in two Egyptian chickpea varieties, Giza 531 and Giza 4 was achieved by direct organogenesis. A variety of embryo explants and different types and concentrations of growth regulators were investigated for maximum efficiency of shoot and root regeneration. Embryo axes with the adjacent part of cotyledon proved to be the most promising type of explant for shooting and rooting responses. 6-Benzylaminopurine (BAP) and indole-3-butyric acid (IBA) were found to induce the highest percentages of shoot initiation and root formation, respectively. Although the Giza 531 variety produced a better response than the Giza 4 for shoot formation, it displayed lower performance for root induction. It would be rewarding if this optimized regeneration protocol paved the way toward the genetic improvement of the Egyptian chickpea.     

Effect of the application of benzyladenine pulse on organogenesis, acclimatisation and endogenous phytohormone content in kiwi explants cultured under autotrophic conditions.

In traditional in vitro culture, explants grow enclosed in a non-ventilated vessel at high relative humidity with phytohormones continuously present and sucrose as the main energy source. Under such conditions explant growth is far from normal. In this paper, explants of Actinidia deliciosa were cultured in MS medium supplemented with sucrose, benzyladenine and gibberellic acid under autotrophic conditions in glass boxes flushed with air enriched with 600 microl l(-1) CO(2) for the first 20 days and then transferred to MS medium until the end of the culture period. The effect of benzyladenine was assayed in two regimes of application: in cultures for 20 days in the medium or only 24 h in the presence of benzyladenine with the aim of improving shoot proliferation and acclimatisation. The longest explants were those grown under ventilation and pulsed for 24 h with benzyladenine. These explants also rooted spontaneously, whereas those grown with continuous benzyladenine under ventilation or without ventilation grew and rooted poorly. The highest amount of endogenous isoprenoid cytokinins were found in the longest explants grown under ventilation and pulsed for 24 h with benzyladenine; under these conditions zeatin riboside represented two thirds of the entire cytokinin pool. These explants presented the highest amount of indole-3-acetic acid, while abscisic acid content was high in explants cultured under non-ventilated conditions. No differences were observed between explants cultured under ventilation regardless of their exposure to benzyladenine. The longest explants, which also performed best in acclimatisation, also presented a high indole-3-acetic to abscisic acid ratio.     

Temporal requirement of the alternative-splicing factor Sfrs1 for the survival of retinal neurons

Alternative splicing is the primary mechanism by which a limited number of protein-coding genes can generate proteome diversity. We have investigated the role of the alternative-splicing factor Sfrs1, an arginine/serine-rich (SR) protein family member, during mouse retinal development. Loss of Sfrs1 function during embryonic retinal development had a profound effect, leading to a small retina at birth. In addition, the retina underwent further degeneration in the postnatal period. Loss of Sfrs1 function resulted in the death of retinal neurons that were born during early to mid-embryonic development. Ganglion cells, cone photoreceptors, horizontal cells and amacrine cells were produced and initiated differentiation. However, these neurons subsequently underwent cell death through apoptosis. By contrast, Sfrs1 was not required for the survival of the neurons generated later, including later-born amacrine cells, rod photoreceptors, bipolar cells and Müller glia. Our results highlight the requirement of Sfrs1-mediated alternative splicing for the survival of retinal neurons, with sensitivity defined by the window of time in which the neuron was generated.