Are hyperhydric shoots of Prunus avium L. energy deficient?

The content of oxidized and reduced pyridine nucleotides and some enzymatic activities of the oxidative pentose phosphate and glycolytic pathways were compared in normal (NS, growing on agar) and hyperhydric (HS, growing on gelrite) shoots of Prunus aviumL. after 4 weeks of in vitro culture. The chlorophyll fluorescence from leaves and the redox capacity of the plasma membrane (reduction of exogenously added ferricyanide) of both types of shoots were recorded. The pool of oxidized and reduced pyridine nucleotides was lower in HS than in NS. These results suggested a reduced metabolism of HS in comparison to normal ones. This hypothesis was also supported by other observations. First, chlorophyll fluorescence measurements showed a lower chlorophyll content and a slight reduction of the photosynthetic capacity in HS. Second, the low activity of some enzymes of oxidative pentose phosphate pathway (OPP) and glycolysis indicated a decline of these biochemical pathways in HS with the consequence of a reduced production of chemical energy in the form of NAD(P)H and ATP. Finally, the lower reduction of ferricyanide by HS suggested a lower rate of redox reactions at the level of the plasma membrane of these shoots in comparison to NS.     

Growth Conditions in In Vitro Culture Can Induce Oxidative Stress in <Emphasis Type="Italic">Mammillaria gracilis</Emphasis> Tissues

In vitro propagated plants of Mammillaria gracilis Pfeiff. (Cactaceae) develop calli without any exogenous growth regulators. This habituated tissue spontaneously regenerates morphologically normal as well as hyperhydric shoots. In this study, a possible involvement of activated oxygen metabolism in habituation and hyperhydricity in in vitro propagated plants of Mammillaria gracilis Pfeiff. (Cactaceae) was investigated. Significantly higher malondialdehyde (MDA) and carbonyl contents as well as hydrogen peroxide (H₂O₂) production were observed in habituated callus (HC), hyperhydric regenerated shoots (HS), and tumors (TT) in comparison to normal regenerated shoots (NS). Lipoxygenase (LOX) activity showed a similar trend, with a clear increase in activity in HC and HS. The activities of antioxidative enzymes, namely, peroxidase (POX), ascorbate peroxidase (APX), and catalase (CAT), were also higher in HC, HS, and TT, whereas an increase in superoxide dismutase (SOD) activity was observed in HC and HS. The majority of antioxidative isoenzymes were common to all cactus tissues, although a few tissue-specific bands were noticed. Significant decreases in phenylalanine ammonia lyase (PAL) activity, total phenolic content, and lignification were found in HS, HC, and TT in comparison to NS. Our results showed the appearance of a prominent oxidative stress in HC, HS, and TT as well as a strong induction of the antioxidant system indicating that activated oxygen metabolism could be involved in habituation and hyperhydricity and linked to the loss of tissue organization in M. gracilis. B. Balen and M. Tkalec contributed equally to this work.     

Response of <Emphasis Type="Italic">Dionaea muscipula</Emphasis> J. Ellis to light stress in in vitro: physiological study

Hyperhydricity can cause significant economic loss for the micro-propagation industry that produces blueberry. In order to predict and control the occurrence of hyperhydricity, better understanding of the anatomical and physiological features of hyperhydric plantlets is required. In this study, we investigated the ultrastructural and physiological changes associated with hyperhydric blueberry plantlets. Compared to normal plantlets, hyperhydric plantlets exhibited reduced cell wall thickness, damaged membrane and guard cell structure, decreased number of mitochondria and starch granule, higher cell vacuolation, more intercellular spaces, and collapse of vascular tissues. In addition, excessive accumulation of reactive oxygen species (ROS) and ethylene, decreased stomatal aperture and water loss, as well as abnormity of stomatal movement were also evident in the hyperhydric plantlets. The results suggested that excessive ethylene and ROS produced in response to the stress arising from in vitro culture could lead to abnormal stomatal closure, causing the accumulation of water in the tissues. This would lead to subsequent induction of oxidative stress (due to hypoxia) and cell damage, especially guard cell structure, eventually giving rise to the symptoms of hyperhydricity. Reducing the content of ethylene and ROS, and protecting the structure and function of the stomata could be considered as potential strategies for inhibiting hyperhydricity or restoring the hyperhydric plants to their normal state.     

Analysis of ultrastructure and reactive oxygen species of hyperhydric garlic (Allium sativum L.) shoots

Hyperhydricity is a physiological disorder frequently affecting shoots propagated in vitro. Since it negatively affects shoot multiplication vigor, and impedes the successful transfer of micropropagated plants to in vivo conditions, hyperhydricity is a major problem in plant tissue culture. In commercial plant micropropagation, there are reports of up to 60% of cultured shoots or plantlets which demonstrate hyperhydricity, which reflects the pervasiveness of this problem. The phenomenon has been correlated to water availability, microelements, and/or hormonal imbalance in the tissue culture. In this study, the ultrastructure and the characteristics of reactive oxygen species between hyperhydric and normal shoots of garlic were studied. We observed that in some cells of hyperhydric tissues, the intranuclear inclusion was separated, the mitochondrion was swollen and its intracristae had splits, the organelles were compressed against the cell wall, and the chloroplasts and intergranal thylakoids were also compressed. Additionally, the content of chlorophyll and soluble protein in hyperhydric shoots decreased significantly. For instance, chlorophyll a decreased 43.61%, chlorophyll b decreased 49.29%, chlorophyll a+b decreased 48.10%, and soluble protein dropped 47.36%. In contrast, the O₂ generation rate and H₂O₂ level increased 45.36% and 63.98%, respectively, obviously higher than the normal shoots. Lipoxygenase activity and malondialdehyde content in the hyperhydric shoots increased significantly, while the electrolyte leakage rose, indicating a serious membrane lipid peroxidatic reaction. Superoxide dismutase, peroxidase, catalase, glutathione peroxidase, and ascorbate peroxidase activities in hyperhydric tissue were all significantly higher than in normal leaf tissue. The antioxidant metabolism demostrated a close connection between hyperhydricity and reactivated oxygen species.     

Lipid peroxidation and antioxidant enzyme activities of Euphorbia millii hyperhydric shoots

A large number of micropropagated Euphorbia millii shoots from temporary immersion bioreactor showed thick broad leaves that were translucent, wrinkled and/or curled and brittle, symptoms of hyperhydricity. The environment inside bioreactor normally used in plant micropropagation is characterised by high relative humidity, poor gaseous exchange between the internal atmosphere of the bioreactor and its surrounding environment, and the accumulation of ethylene, conditions that may induce physiological disorders. A comparison of hyperhydric shoots (HS) with normal plants shows marked increase in malondialdehyde (MDA) content in HS plants. MDA, a decomposition product of polyunsaturated fatty acids hydroperoxides, has been utilized very often as a suitable biomarker for lipid peroxidation, which is an effect of oxidative damage. This hypothesis is also confirmed by the higher lipoxygenase (LOX) activity in HS plants. The potential role of antioxidant enzymes in protecting hyperhydric shoots from oxidative injury was examined by analyzing enzyme activities and isozyme profiles of hyperhydric and non-hyperhydric leaves of E. millii. Superoxide dismutase (SOD), peroxidase (POD) and catalase (CAT) activity were significantly higher in hyperhydric tissue as compared to non-hyperhydric normal leaf tissue. After native polyacrylamide gel electrophoresis (PAGE) analysis, seven SOD isoenzymes were detected and the increase in SOD activity observed in hyperhydric tissue seemed to be mainly due to Mn-SOD and Cu/Zn-SOD. The activity of ascorbate peroxidase (APX), glutathione reductase (GR), monodehydroascorbate reductase (MDHAR) and dehydroascorbate reductase (DHAR) was proportionally increased in HS tissue compared to normal leaves indicating a crucial role in eliminating toxic H₂O₂ from plant cells. The depletion of GSH and total glutathione in spite of higher GR activities observed in HS tissue indicates that mechanism of antioxidant defense was by enhanced oxidation of GSH to GSSG by DHAR yielding ascorbate (AA). The antioxidant metabolism has been shown to be important in determining the ability of plants to survive in hyperhydric stress and the up regulation of these enzymes would help to reduce the build up of ROS.     

In vitro conditions affect photosynthetic performance and crassulacean acid metabolism in Mammillaria gracilis Pfeiff. tissues

Mammillaria gracilis Pfeiff. plants cultivated in the pot (pot plants, PP), as well as in vitro-grown normal shoots (NS), habituated callus (HC), hyperhydric shoots (HS), and tumour tissue (TT) were investigated in order to reveal the influence of in vitro culture on functionality of the photosynthetic apparatus and CAM photosynthesis in cactus M. gracilis Pfeiff. Photosynthetic pigments content as well as maximum (F _v/F _m) and effective (??_PSII) quantum yield of photosystem II (PSII) decreased in all in vitro-grown tissues in comparison to PP. The decrease observed in hyperhydric HC, HS and TT correlated with a low expression of Rubisco large subunit (RbcL) and ?? subunit of ATP synthase (?? ATP synt) and almost undetectable levels of protein D1, light-harvesting chlorophyll a/b-binding protein (LHCII) and cytochrome f protein of thylakoid Cyt b ₆ /f-complex (Cyt f) found in these tissues. As for crassulacean acid metabolism (CAM) pattern, PP and NS expressed diurnal acid fluctuation, while HC, HS and TT failed to show it. Nevertheless, all M. gracilis tissues exhibited diurnal changes of phosphoenolpyruvate carboxylase (PEPC) activity indicating the typical CAM physiology. In conclusion, the photosynthesis was down-regulated in all in vitro-grown tissues. NS maintained typical CAM photosynthesis, while HC, HS and TT withheld PEPC activity, but not acid accumulation specific for CAM. Minor changes observed in NS in comparison to PP could be attributed to the sugar supplementation while the more prominent deviations found in HC, HS and TT could be correlated with hyperhydricity and the loss of characteristic tissue organisation pattern.     

Proteomic and Antioxidant Analysis Elucidates the Underlying Mechanism of Tolerance to Hyperhydricity Stress in In Vitro Shoot Cultures of <Emphasis Type="Italic">Dianthus caryophyllus</Emphasis>

Hyperhydric disorders occur frequently in plant tissues cultured in vitro and cause several morphological and physiological abnormalities. However, a systematic defense response is triggered by hyperhydric conditions. The accumulation of reactive oxygen species (ROS), activities of antioxidant enzymes and their immunoblots, and the proteome-level changes in normal versus hyperhydric shoots of carnation (Dianthus caryophyllus) cultured in vitro were investigated. Total proteins were also extracted from the shoot and analyzed by two-dimensional electrophoresis. Among a total of 700 spots detected, only 40 had significant changes in abundance in the hyperhydric compared to the normal shoots, which were further identified by a mass spectrometer (MALDI-TOF MS). Most of them were involved in photosynthesis, RNA processing, and general metabolisms, while the rest were involved in secondary metabolic processes. These identified proteins in carnation shoots may provide novel evidences for stress tolerance against hyperhydricity.     

Endogenous cytokinins in shoots of Aloe polyphylla cultured in vitro in relation to hyperhydricity, exogenous cytokinins and gelling agents

The process of hyperhydricity in tissue cultured plants of Aloe polyphylla is affected by both applied cytokinins (CKs) and the type of gelling agent used to solidify the medium. Shoots were grown on media with agar or gelrite and supplemented with different concentrations of N⁶-benzyladenine (BA) or zeatin (0, 5 and 15 μM). Endogenous CKs were measured in in vitro regenerants after an 8-weeks cycle to examine whether the hyperhydricity-inducing effect of exogenous CKs and gelling agents is associated with changes in the endogenous CK content. On media with agar a reduction in hyperhydricity occurred, while the gelrite treatment produced both normal and hyperhydric shoots (HS). The content of endogenous CKs, determined by HPLC-mass spectrometry, in the shoots grown on CK-free media comprised isopentenyladenine-, trans-zeatin- and cis-zeatin-type CKs. The application of exogenous CKs resulted in an increase in the CK content of the shoots. Following application of zeatin, dihydrozeatin-type CKs were also detected in the newly-formed shoots. Application of BA to the media led to a transition from isoprenoid CKs to aromatic CKs in the shoots. Shoots grown on gelrite media contained higher levels of endogenous CKs compared to those on agar media. Total CK content of HS was higher than that of normal shoots grown on the same medium. We suggest that the ability of exogenous CKs and gelrite to induce hyperhydricity in shoots of Aloe polyphylla is at least partially due to up-regulation of endogenous CK levels. However, hyperhydricity is a multifactor process in which different factors intervene.     

Structural differences between hyperhydric and normal in vitro shoots of <Emphasis Type="Italic">Handroanthus impetiginosus</Emphasis> (Mart. ex DC) Mattos (Bignoniaceae)

The anatomy of normal and hyperhydric shoots (leaves and stems) of in vitro Handroanthus impetiginosus was compared using light microscopy, scanning electron microscopy, and transmission electron microscopy. In contrast to normal shoots, hyperhydric shoots presented numerous anatomical abnormalities at the proliferation stage. Disorganized cortex, epidermal holes, epidermal discontinuity, collapsed cells, and other structural characteristics were observed in hyperhydric shoots. So, by using anatomical analysis of in vitro H. impetiginosus shoots at the proliferation stage, we can predict which plants will survive the rhizogenesis and acclimatization stages.     

Influence of ventilation closure, gelling agent and explant type on shoot bud proliferation and hyperhydricity in Scrophularia yoshimurae—A medicinal plant

Summary We report an improved procedure of in vitro propagation of Scrophularia yoshimurae&#x2014;a medicinally important plant species indigenous to Taiwan. Induction of maximum shoot buds (22.75 per explant) was obtained with shoot tip explant cultured on Murashige and Skoog medium supplemented with 1.0mgl^&#x2212;1 benzyladenine (BA) and 0.2mgl^&#x2212;1 &#x03B1;-naphthaleneacetic acid and gelrite using dispense paper (DP) for ventilation closure of culture vessels. The type of gelling agents (agar and Gelrite) affected both quantity and quality of the shoots induced. Using aluminum foil for ventilation closure resulted in a higher number of hyperhydric shoots. Hyperhydricity was reduced by culturing shoots on a medium devoid of plant growth regulators in conjunction with the use of DP. Plantlet growth in vessels using DP was healthier and all plantlets survived after being transplanted to soil.     

Hyperhydricity in micropropagated carnation shoots: the role of oxidative stress

The physiology of hyperhydricity in relation to oxidative stress, mineral nutrients, antioxidant enzymes and ethylene has been studied in three micropropagated carnation cultivars under experimentally induced hyperhydricity. A marked increase in Fe content in comparison with normal tissues was observed in the hyperhydric tissues from the three cultivars. The levels of ethylene, solute leakage and malondialdehyde content were also significantly higher in the hyperhydric tissues. In relation to the time course of H₂O₂ production measured by fluorescence quenching, a similar trend could be observed for the three cultivars, with a clear increase in the generation of hydrogen peroxide in hyperhydric tissues. The activities of all the antioxidative enzymes studied, except lipoxygenase, were higher in the hyperhydric shoots. Phenylalanine ammonia-lyase (PAL) showed a significant decrease in activity in the hyperhydric tissues in comparison with the controls for the three cultivars. Soluble guaiacol peroxidase had a strong increase in activity in hyperhydric shoots of the three cultivars. These results provide, for the first time, direct evidence of H₂O₂ generation in hyperhydric tissues, characterize the response of the antioxidant system to an oxidative stress during hyperhydricity in carnation leaves and point to the accumulation of toxic forms of oxygen as the inducer of some of the abnormalities observed.     

Transgenic watermelon lines expressing the nucleocapsid gene of <Emphasis Type="Italic">Watermelon silver mottle virus</Emphasis> and the role of thiamine in reducing hyperhydricity in regenerated shoots

Viral diseases are very detrimental to watermelon production. Watermelon silver mottle virus (WSMoV) is a major limiting factor for the production of watermelon and other cucurbit fruits. There are no effective natural sources of resistance to WSMoV, making transgenic resistance an appropriate solution for attenuating virus infection. Hyperhydricity is an important problem in watermelon culture in vitro, resulting from lower multiplication rates, poor quality shoots and tissue necrosis. In this study, we report an Agrobacterium-mediated genetic transfer protocol for commercial watermelon cultivars expressing the nucleocapsid (N) gene of WSMoV and a suitable approach to overcome hyperhydricity in watermelon culture in vitro. Murashige and Skoog (MS) salts containing Schenk and Hildebrandt (SH) vitamins + 50 mg l⁻¹ thiamine HCl could diminish the hyperhydric phenotype. The proximal halves of cotyledons from 3-day-old seedlings were cut into 1.5 × 1.5 mm segments as explants. Four days after co-cultivation, the explants were transferred to a selection medium for shoot regeneration. The putative transgenic shoots developed within 6 weeks of culture and were then transferred to stringent medium for 8 weeks to eliminate ‘escape type’ shoots. Fifty putative transgenic watermelon lines were obtained from three cultivars. PCR and Southern blot analysis confirmed that the foreign gene was incorporated into the genomic DNA of the transgenic lines.     

Shoot multiplication kinetics and hyperhydric status of regenerated shoots of gladiolus in agar-solidified and matrix-supported liquid cultures

In vitro shoot regeneration of gladiolus in three different culture systems, viz., semi-solid agar (AS), membrane raft (MR), and duroplast foam liquid (DF) cultures was evaluated following the kinetics of shoot multiplication and hyperhydricity at optimized growth regulator combinations. Compared to the AS system, matrix-supported liquid cultures enhanced shoot multiplication. The peak of shoot multiplication rate was attained at 18 days of incubation in the MR and DF systems, whereas the maximum rate in the AS system was attained at 21 days. An early decline in acceleration trend was observed in liquid cultures than the AS culture. The hyperhydric status of the regenerated shoots in the different culture systems was assessed in terms of stomatal attributes and antioxidative status. Stomatal behavior appeared to be normal in the AS and MR systems. However, structural anomaly of stomata such as large, round shaped guard cells with damage in bordering regions of stomatal pores was pronounced in the DF system along with a relatively higher K⁺ ion concentration than in the AS and MR systems. Antioxidative status of regenerated shoots was comparable in the AS and MR systems, while a higher incidence of oxidative damages of lipid membrane as evidenced from malondialdehyde and ascorbate content was observed in the DF system. Higher oxidative stress in the DF system was also apparent by elevated activities of superoxide dismutase, ascorbate peroxidase, and catalase. Among the three culture systems, liquid culture with MR resulted in maximum shoot multiplication with little or no symptoms of hyperhydricity. Shoots in the DF system were more prone to hyperhydricity than those in the AS and MR systems. The use of matrix support such as membrane raft as an interface between liquid medium and propagating tissue could be an effective means for rapid and efficient mass propagation with little or no symptoms of hyperhydricity.     

A Study on Comparative Morphology of Normal and Hyperhydric Stems and leaves from Sophora japonica Plantlets Cultured in Vitro

A large numar of plantlets were obtained from cotyledon explants of Sophom japonica L. cultured in vitro. They could be classified into 3 kinds according to their morphological characteristics, viz. the normal plantlets, the hyperhydric planfiets,and the intermediate state between the two or the sub-hyperhydric type. The free water content was more than 79% in the hyperhydric shoots,and 70% in the sub-hyperhydric shoots,while less than 50% in the normal shoots. The surface anatomy of normal, sub-hyperhydric and hyperhydric stems and leaves of the plantlets were compared by scanning electron microscopy. The surface structure of the normal plantlets was similar to those found in field-grown plants,but great change occurred in that of hyperhydric and the sub-hyperhydric plantlets. The stems and leaves surface of the hyperhydric and sub-hyperhydric plantlets appeared to be uneven, wrinkled, brittle and translucent and besides the leaves were thick, curled with a reduced surface area. There was little or no epicuticular wax on the surface of epidermal cells which had irregular shapes and patterns. All leaves were amphistomatic and the stomatal density, size and degree of opening were obviously bigger in the sub-hyperhydric and hyperhydric leaves than in the normal ones. Normal stomata had kidney-shaped guard cells and resembled closely those found in the feild-grown plants, whereas abnormal stomata had deformed guard cells. All of the morphological characteristics mentioned above indicated that the sub-hyperhydric and hyperhydric shoots bended to lose their water easily and resulted in desiccation, which might be one of the major causes of failure to transfer sub-hyperhydric and hyperhydric plantlets to soil.     

Cell ultrastructure and chlorophyll pigments in hyperhydric and non-hyperhydric <Emphasis Type="Italic">Beta vulgaris</Emphasis> var. Conditiva plantlets,treated with deuterium depleted water

Hyperhydricity can cause significant loss in the in vitro propagated plantlets. In order to predict and control its occurrence, a better understanding of the structural aspects and physiological features of hyperhydric plantlets is required. In this study, the ultrastructural and physiological changes associated with hyperhydric red beet plantlets were investigated. Our objective was to establish a correlation between the ultrastructural aspects of Beta vulgaris var. Conditiva leaflets and hypocotyls and the content of chlorophyll pigments extracted in N,N-dimethylformamide (DMF) of two type of plantlets: hyperhydric from a basal culture medium Murashige and Skoog (JAMA 15:473–497, 1962) prepared with distilled water (DW—155 ppm Deuterium) and non-hyperhydric, cultivated on identical medium where distilled water was replaced with deuterium depleted water (DDW- 25 ppm Deuterium) as a method of preventing hyperhydricity. Cell ultrastructure in hyperhydricity, both from the leaves, but especially from hypocotyls, showed denatured chloroplasts in a myxoplasm mass formed by the damage of the tonoplast and the mixing of the cytoplasm with the vacuolar juice. The nuclei were picnotic, presenting paranucleolar corpuscles. The amount of assimilating pigments was significantly reduced in the plantlets grown on medium prepared with DW as compared to the normal, non-hyperhydric ones from medium prepared with DDW. Both evaluations showed that, in red beet, DDW also prevents the appearance of hyperhydricity.     

槐树试管正常苗与超度含水态苗茎叶的比较形态学研究

槐树(Sophora japonica L.)子叶经培养获得了大量的试管苗,依其形态正常与否可将其分为正常苗、超度含水态苗和介于二者之间的过度含水态苗。其自由水含量明显不同,正常苗低于50％,超度含水态苗高于79％,而过度含水态苗约为70％。以扫描电镜对其茎、叶的形态学结构进行了比较研究,结果表明:正常苗茎、叶表皮结构基本类似于实生苗,而过度及超度含水态苗的茎、叶表皮层结构变异较大。主要表现在其表面凹凸不平,表皮层外稀有或无蜡质存在,表皮细胞形状及排列不规则,叶片近、远轴两面气孔器密度、大小及开度均较正常苗显著增大;保卫细胞形态、结构异常。上述特征,均显示出槐树试管过度及超度含水态苗易失水干化,这可能是其在移栽过程中难以成活的主要原因之一。     

Antioxidant enzyme activities, malondialdehyde, and total phenolic content of PEG-induced hyperhydric leaves in sugar beet tissue culture

Hyperhydricity is a physiological abnormality that frequently affects shoots that are vegetatively propagated in vitro. In this study, sugar beet (Beta vulgaris L. cv. Felicita) shoot tip explants were cultured on Murashige and Skoog medium supplemented with different concentrations of polyethylene glycol (PEG) 6000. We observed that higher concentrations of PEG 6000 and longer exposure (up to 4 wk) resulted in increasing levels of hyperhydration as well as browning and/or blackening of tissues in culture. A comparison of hyperhydric shoots with controls on the 28th day showed a marked increase in the content of water, phenolics, and malondialdehyde (MDA), which was positively correlated with an increase in the accumulation of PEG 6000. Selected antioxidant enzyme activities, including superoxide dismutase (SOD), catalase (CAT), ascorbate peroxidase (APX), guaiacol peroxidase (POX), and polyphenol oxidase (PPO) also increased in hyperhydric shoots, especially at lower concentrations of PEG 6000. Regression analysis indicated that strong linear relationships exist between SOD–APX (R ²?=?0.932), SOD–CAT (R ²?=?0.753), SOD–total phenolic content (R ²?=?0.966), APX–PPO (R ²?=?0.842), APX–total phenolic content (R ²?=?0.904), POX–CAT (R ²?=?0.751), and CAT–total phenolic content (R ²?=?0.806). Despite the correlation between different antioxidant enzymes and between the antioxidant enzymes and antioxidant compounds, was not able to prevent ROS damage in hyperhydric shoots. The negative correlation between SOD–MDA, POX–MDA, CAT–MDA, and MDA–total phenolics also indicated an increase in antioxidant enzyme activities, yet the increase in these antioxidant compound contents did not prevent lipid peroxidation of in vitro propagated beet shoots.     

Isoenzymes of peroxidase and esterase related to morphogenesis in Mammillaria gracillis Pfeiff. tissue culture

In vitro propagated plants of the cactus Mammillaria gracillis Pfeiff. (Cactaceae) spontaneously produced callus. The habituated callus regenerated normal and hyperhydric shoots without the addition of grown regulators. Tumours were obtained by infecting cactus explants with Agrobacterium tumefaciens; the wild strain B6S3 (tumour TW) or with the rooty mutant GV3101 (tumour TR). Both tumour lines grew vigorously, never expressing any morphogenic potential. In this study, cactus shoots, callus, normal and hyperhydric regenerants and TW and TR tumours were compared with regard to peroxidase (EC 1.11.1.7) and esterase activity, and isoenzyme patterns. Guaiacol peroxidase activity was the lowest in the cactus shoots and in the normal regenerants. Callus, hyperhydric regenerants and tumours had peroxidase activity of 6 to 7 times higher. Esterase activity was measured with 1- and 2-naphthylacetate as broad-spectrum substrates. The highest esterase activity was determined in tumours with both substrates. All tissues, except the TR tumour, had higher esterase activity for 2-compared to 1-naphtylacetate. Peroxidase and esterase isoenzyme patterns were not completely identical among the investigated tissues.     

In vivo relationship between morphonuclear parameters and hormone sensitivity of the murine MXT mammary tumor

The initially hormonosensitive (HS) MXT mouse mammary tumor spontaneously evolved to hormonoin-dependence (HI). Using a SAMBA 200 cell image processor, we compared the DNA content and the chromatin structure of HS and HI tumor cells squashed onto histologic slides; the nuclei were colored by the Feulgen reaction. We compared HI and HS nuclei by a discriminant analysis using the 15 parameters obtained on each nucleus. We show that the percentage of well-classified granulocytes (2n DNA content control) versus HS or HI nuclei exceeded 99. On the other hand, this percentage did not reach 70 when we compared HS and HI. The cell cycle analysis revealed that the percentage of cells in S and G2 + M phases were significantly higher in HI tumors than in the HS. Hence, HI and HS MXT tumor nuclei seem to be morphologically identical, but are significantly different if we refer to cell proliferation rates.     

Effects of culture medium composition and PEG on hyperhydricity in Dendrobium officinale

Hyperhydricity is a physiological disorder during plant tissue culture that seriously affects regeneration and micropropagation. In this study, Dendrobium officinale plantlets were cultured on solid Murashige and Skoog (MS) medium supplemented with plant growth regulators and various concentrations of sucrose, agar, and polyethylene glycol (PEG)-6000 to explore the effect of osmotic stress on hyperhydricity. The results show that low concentrations of sucrose or agar, as well as PEG-6000 at various concentrations, significantly increase the hyperhydric rate of D. officinale, whereas high concentrations of sucrose or agar did not. Furthermore, high concentrations of PEG-6000 significantly increase total water content, free-water content, relative electrical conductivity, and peroxidase (POD) activity of D. officinale plantlets, whereas they significantly decrease bound-water content, proline content, soluble protein content, soluble sugar content, and superoxide dismutase (SOD) activity. These results indicate that PEG-6000 disrupts the antioxidant system and water metabolism in D. officinale plantlets, as well as increases cell membrane permeability, which might be the key factors for the occurrence of hyperhydricity in this species.