The unusual sugar composition in leaves of the resurrection plant Myrothamnus flabellifolia

To understand mechanisms of osmoprotection, the composition of sugars and related compounds were analyzed in extracts of fully hydrated and desiccated leaves of the desiccation-tolerant resurrection plant Myrothamnus flabellifolia . During the dehydration process the concentrations of fructose and glucose decrease, whereas sucrose, arbutin and glucopyranosyl-β-glycerol increase. The substances were identified by GC-MS and NMR-analyses. This is the first report of large amounts of glucopyranosyl-β-glycerol in higher plants which may act as an osmoprotectant. Significant levels of the nonreducing sugar trehalose were present in all samples tested.     

Arabinose-rich polymers as an evolutionary strategy to plasticize resurrection plant cell walls against desiccation

A variety of Southern African resurrection plants were surveyed using high-throughput cell wall profiling tools. Species evaluated were the dicotyledons, Myrothamnus flabellifolia and Craterostigma plantagineum; the monocotyledons, Xerophyta viscosa, Xerophyta schlecterii, Xerophyta humilis and the resurrection grass Eragrostis nindensis, as well as a pteridophyte, the resurrection fern, Mohria caffrorum. Comparisons were made between hydrated and desiccated leaf and frond material, with respect to cell wall composition and polymer abundance, using monosaccharide composition analysis, FT-IR spectroscopy and comprehensive microarray polymer profiling in combination with multivariate data analysis. The data obtained suggest that three main functional strategies appear to have evolved to prepare plant cell walls for desiccation. Arabinan-rich pectin and arabinogalactan proteins are found in the resurrection fern M. caffrorum and the basal angiosperm M. flabellifolia where they appear to act as ‘pectic plasticizers’. Dicotyledons with pectin-rich walls, such as C. plantagineum, seem to use inducible mechanisms which consist of up-regulating wall proteins and osmoprotectants. The hemicellulose-rich walls of the grass-like Xerophyta spp. and the resurrection grass E. nindensis were found to contain highly arabinosylated xylans and arabinogalactan proteins. These data support a general mechanism of ‘plasticising’ the cell walls of resurrection plants to desiccation and implicate arabinose-rich polymers (pectin-arabinans, arabinogalactan proteins and arabinoxylans) as the major contributors in ensuring flexibility is maintained and rehydration is facilitated in these plants.     

An overview of the biology of the desiccation-tolerant resurrection plant Myrothamnus flabellifolia

BACKGROUND: Myrothamnus flabellifolia is unique as the only woody resurrection plant. It is an important plant in southern Africa because of its widespread occurrence and usage in African medicine and traditional culture. Many reports have investigated facets of its biology and the mechanisms associated with its desiccation tolerance. SCOPE: The general biology of the woody resurrection plant Myrothamnus flabellifolia is reviewed. The review focuses on the geography and ecology, systematic placement, evolution, morphology and reproductive ecology of M. flabellifolia as well as the wood anatomy and re-filling mechanism. In addition, the desiccation tolerance, ethnobotanical importance and medicinal properties of the plant are reviewed. Also, future research avenues are suggested, in particular the necessity to research the biogeography and systematics of the species and the role of the polyphenols present, as well as the molecular basis of the plant's desiccation tolerance.     

The effect of dehydration and rehydration on the nitrogen content of various fractions from resurrection plants

Nitrogen contents were determined in 20 species of “resurrection plants”,i.e. plants with leaves which are able to revive from an air-dry state (viz. Boea hygroscopica, Borya nitida, Cheilanthes sieberi, Coleochloa pallidior, C. setifera, Craterostigma plantagineum, Myrothamnus flabellifolia, Oropetium capense, Pellaea calomelanos, P. falcata, P, viridis, Polypodium polypodioides, Ramondia pyrenaica, Selaginella lepidophylla, Sporobolus stapfianus, Talbotia elegans,Tripogon loliiformis, Xerophyta retinervis, X. villosa, X. viscosa), and in three desiccation sensitive species (Eragrostis tenuifolia, Selaginella kraussiana andSporobolus pyramidalis). In a preponderance of resurrection plants insoluble nitrogen content fell during dehydration of intact plants and soluble non-protein N rose. Both changes were particularly marked in species which lose chlorophyll and thylakoid structure during drying. These trends were usually only partially reversed after 24 h rehydration. Recovery of¹⁴C-leucine incorporation in rehydrating leaves was slow. Leaves of desiccation sensitive vascular plants tended on the average to lose soluble protein rather than insoluble N during drying, and tended to have higher soluble non-protein N contents than tolerant plants. However, similarity in the changes in N-contents inXerophyta villosa leaves killed by airdrying compared to leaves surviving air-drying, opposes the view that death was due to excessive loss of protein.     

The "resurrection method" for modification of specific proteins in higher plants

We describe a new method designated "the resurrection method" by which a modified protein is expressed in higher plants in place of the original protein. The modified gene constructed by introducing synonymous codon substitutions throughout the original gene to prevent the sequence-specific degradation of its mRNA during RNA silencing is expressed while the expression of the original gene is suppressed. Here, we report the successful alteration of the biochemical properties of green fluorescent protein expressed in transgenic Nicotiana benthamiana, suggesting that this method could be useful for gene control in living plants.     

Water transport at the extreme – restoring the hydraulic system in a resurrection plant

Resurrection plants are a perennial fascination to botanists. The transformation, within a few hours (or even minutes) of supplying them with water, from a plant that has all the appearances of being dead – dry, brown, crisp and shrivelled – to a plant that is obviously living and functioning – turgid, green, pliable and growing – suggests the miraculous. Studies of the complex processes of restoration and repair have been made on a number of resurrection plants, and at many levels of organization from molecules through membranes, organelles and cells to the whole plant (Gaff, 1989). The woody South African shrub Myrothamnus is the most extreme example of such plants, in that it has the highest level of organization to be repaired. It is transformed from lifeless-looking sticks with a water content below 5% to a flourishing bush in a day after its roots receive water. Two papers in this issue from Ulrich Zimmermann's group in Würzburg concentrate on the restoration of the functioning hydraulic systems of the stems (see pp. 221–238, and 239–255).     

Dynamics of Endogenous Phytohormones during Desiccation and Recovery of the Resurrection Plant Species Haberlea rhodopensis

Drought is one of the most significant threats to world agriculture and hampers the supply of food and energy. The mechanisms of drought responses can be studied using resurrection plants that are able to survive extreme dehydration. As plant hormones function in an intensive cross-talk, playing important regulatory roles in the perception and response to unfavorable environments, the dynamics of phytohormones was followed in the resurrection plant Haberlea rhodopensis Friv. during desiccation and subsequent recovery. Analysis of both leaves and roots revealed that jasmonic acid, along with and even earlier than abscisic acid, serves as a signal triggering the response of the resurrection plants to desiccation. The steady high levels of salicylic acid could be considered an integral part of the specific set of parameters that prime H. rhodopensis desiccation tolerance. The dynamic changes of cytokinins and auxins suggest that these hormones actively participate in the dehydration response and development of desiccation tolerance in the resurrection plants. Our data contribute to the elucidation of a global complex picture of the resurrection plant’s ability to withstand desiccation, which might be successfully utilized in crop improvement.     

Inclusion of polyvinylpyrrolidone in the polymerase chain reaction reverses the inhibitory effects of polyphenolic contamination of RNA.

Polysaccharides, secondary metabolites and poly-phenolics are known to co-isolate with nucleic acids from plant tissues resulting in inhibition of molecular manipulations. RNA isolated from the polyphenolic-rich resurrection plant, Myrothamnus flabellifolius, was demonstrated to inhibit a standard polymerase chain reaction used as an assay despite the inclusion of the polyphenolic-binding compound poly(1-vinylpyrrolidone-2) (PVP) into the RNA isolation medium. This inhibition was, however, reversed by the addition of PVP into the PCR mixture itself. Confirmation of the inhibitory effect of polyphenolics on PCR was obtained by addition of green tea polyphenolics to the standard PCR assay. This inhibition was also reversed by the simultaneous inclusion of PVP.     

更苏被子植物的光合作用

更苏植物是一类在极度干燥条件下组织会迅速脱水后遇水又能很快复苏的植物.极少数被子植物有这种能力,在双子叶植物中尤其罕见,而且脱水时叶绿素含量和叶绿体完整性变化较少,称为叶绿素保持型(HDT).该类植物的复苏机理简单,研究方便,因而得到更广泛注意.更苏被子植物光合作用的最新研究进展说明,光化学活性是研究更苏植物脱水复苏生理状态的灵敏指标.和普通植物一样,在光下,更苏被子植物的光化学活性随着叶片失水而受到抑制,但奇怪的是在失去95%以上的水分后复水仍可迅速复活.在脱水过程中叶黄素循环和抗氧化系统的上调以及光合膜完整性和稳定性的保持,可能对更苏被子植物的耐脱水性起非常重要的作用.磷酸盐对复苏的影响也表现在复水阶段而且与上述两种保护机理关系不大,因此应该加强更苏被子植物复水阶段的研究.     

Marginal and laminar hydathode-like structures in the leaves of the desiccation-tolerant angiosperm Myrothamnus flabellifolius Welw.

The fan-shaped leaves of the resurrection plant Myrothamnus flabellifolius Welw. fold during episodes of drought and consequent desiccation of the tissue. The leaf teeth of M. flabellifolius have several features characteristic of hydathodes. Tracheary elements from the three vein endings that converge in each leaf tooth subtend and extend into a cluster of cells significantly smaller than those of the adjacent mesophyll. The stomata overlying this putative epithem are larger than the other stomata on the leaf surface. Crystal violet is absorbed via these stomata in non-transpiring leaves, suggesting that they are water pores. Two to four such water pores occur per hydathode and are readily distinguished in desiccated leaves. Laminar hydathodes apparently also occur in the leaves of M. flabellifolius. Branched vein endings that terminate in short, wide tracheary elements subtend the outer edges of the abaxial leaf ridge, which otherwise lack stomata, and coincide with regions of crystal violet uptake. Guttation could not be induced in M. flabellifolius. However, desiccated leaves readily absorb liquid water through the leaf surface. The use of Calcafluor White to trace the pathway of apoplastic water movement suggests a role for both types of hydathode in foliar water uptake during rehydration while the accumulation of Sulphorhodamine G (indicating solute retrieval from the apoplast) in the epithem of transpiring plants suggests the hydathodes may be a pathway of water loss in the desiccating leaf.     

更苏被子植物的光合作用

更苏植物是一类在极度干燥条件下组织会迅速脱水后遇水又能很快复苏的植物。极少数被子植物有这种能力,在双子叶植物中尤其罕见,而且脱水时叶绿素含量和叶绿体完整性变化较少,称为叶绿素保持型(HDT)。该类植物的复苏机理简单,研究方便,因而得到更广泛注意。更苏被子植物光合作用的最新研究进展说明,光化学活性是研究更苏植物脱水复苏生理状态的灵敏指标。和普通植物一样,在光下,更苏被子植物的光化学活性随着叶片失水而受到抑制,但奇怪的是在失去95％以上的水分后复水仍可迅速复活。在脱水过程中叶黄素循环和抗氧化系统的上调以及光合膜完整性和稳定性的保持,可能对更苏被子植物的耐脱水性起非常重要的作用。磷酸盐对复苏的影响也表现在复水阶段而且与上述两种保护机理关系不大,因此应该加强更苏被子植物复水阶段的研究。     

Essential‐Oil Polymorphism in the ‘Resurrection Plant’ Myrothamnus moschatus and Associated Ethnobotanical Knowledge

Gas chromatography/mass spectroscopy analysis (GC/MS) of essential oils obtained from populations of the resurrection plant Myrothamnus moschatus, growing in different areas of Madagascar, allowed identification of three main chemotypes in the species. The first one was provided by plants with a high content of trans‐pinocarveol and pinocarvone; the second one involved plants with high percentages of limonene, cis‐ and trans‐p‐mentha‐1(7),8‐dien‐2‐ol, and β‐selinene; and the third chemotype was characterized by plants with high levels of oxygenated sesquiterpenes such as caryophyllene oxide and α‐ and β‐isomers of caryophylla‐4(12),8(13)‐dien‐5‐ol. Chemical data were supported by chemometric technique as the principal component analysis. Furthermore, the relationship between the dioecy and phytochemistry within one population was also considered. Finally, correlations between chemical variations and ethnobotanical data were assessed.     

<Emphasis Type="Italic">In vitro</Emphasis> culture of the resurrection plant <Emphasis Type="Italic">Haberlea rhodopensis</Emphasis>

The small group of resurrection plants is a unique model which could help us in further understanding of abiotic stress tolerance. The most frequently used approach for investigations on gene functions in plant systems is genetic transformation. In this respect, the establishment of in vitro systems for regeneration and micro propagation is necessary. On the other hand, in vitro cultures of such rare plants could preserve their natural populations. Here, we present our procedure for in vitro regeneration and propagation of Haberlea rhodopensis – a resurrection plant species, endemic for the Balkan region.     

Prompt response of superoxide dismutase and peroxidase to dehydration and rehydration of the resurrection plant <Emphasis Type="Italic">Haberlea rhodopensis</Emphasis>

The relic endemic nature of Haberlea rhodopensis, which grows in Balkan Peninsula, in combination with its high vegetative desiccation-tolerance, makes this species a good model to study mechanisms behind plant adaptation to severe drought stress. The aim of this study was to evaluate the antioxidant protection provided by Superoxide dismutase (SOD) and Peroxidase (PO) in H. rhodopensis after exposure to and recovery from dehydration at different developmental stages. During dehydration the electrolyte leakage from leaf tissue increased more significantly in post-flowering plants than in flowering plants, while upon subsequent rehydration this parameter showed a very fast decrease to the basic value of fresh leaves and did not depend on developmental stage. Like other higher plant species, SOD and PO demonstrated in H. rhodopensis an ability to adjust their activity very promptly to changing water supply. In addition, the leaves of this resurrection species retained significant activities of SOD and PO even in air-dried state, considered as the most severe form of water stress. The enhanced activity of antioxidant enzymes may either enable the scavenging of the active oxygen species produced at very severe water deficit, and/or carry a potential for resurrection on subsequent rehydration. Upon stress treatment total activities of both enzymes were higher in flowering than post-flowering plants which reveals that developmental stage might be a factor affecting plant stress tolerance. This work identified for the first time SOD isoforms of H. rhodopensis. Native PAGE showed at least six multiple isoforms in the protein extract from leaf tissue of flowering plants, and the differential visualization revealed that four of them were Cu, Zn-SOD isoforms, one was Mn-SOD and one Fe-SOD. These findings provide a good starting point for future study of the SOD gene family of this rare resurrection plant at the molecular level.     

干燥密罗木复水过程中光诱导蒸腾拉力变化与复水时间的关系

该文探讨了干燥脱水后的复苏植物密罗木(Myrothamnus flabellifolia)的复水速度和复水后不同时间下的木质部压力与植物对光-暗反应的关系。研究结果表明, 密罗木整株植物和离体枝条复水时水分在茎内的上升速度都很快, 10小时左右水分即可接近枝条的顶端。在植物复水初期, 木质部压力反应随着复水时间的延长不断增加, 3周后达到正常值。这种木质部压力的调节能力可能与气孔功能的恢复程度有关。同时, 密罗木在整个复水恢复过程中受到光照时木质部压力下降的弛豫时间都明显大于植物在光源关闭时木质部压力上升的弛豫时间。表明密罗木对蒸腾速率上升过程的调节速度明显低于对蒸腾速率下降过程的调节速度。     

An ultrastructural investigation of the surface microbiota present on the leaves and reproductive structures of the resurrection plant Myrothamnus flabellifolia

The leaves, flower and stems of the southern African angiosperm resurrection plant Myrothamnus flabellifolia were investigated at the ultrastructural level to determine the source of previously reported fungal contamination. Fungal mycelia and hyphae of the genera Aspergillus and Penicillium were found localized to the hydathodes of the leaves and stigmatic surfaces of the female flowers in both desiccated and hydrated specimens. A waxy bacterium of the genus Bacillus was found to colonise the waxy epidermal surfaces of the leaves and flowers which was also where fungal cells were found to be absent. It is suggested that the wax like deposits within the leaves and stems as well as over the epidermal surface prevent the growth of the fungal organisms. These fungi opportunistically invade moist surfaces, such as the floral stigmas, during periods of moisture availability and may thus negatively impact plant development.     

Resurrection Plants: The Puzzle of Surviving Extreme Vegetative Desiccation

Tolerance to near complete desiccation of vegetative organs is a widespread capability in bryophytes and is also shared by a small group of vascular plants known as resurrection plants. To date more than 300 species, belonging to pteridophytes and angiosperms, have been identified that possess this kind of desiccation-tolerance. The vegetative desiccation-tolerance of resurrection plants is an inductive process displayed only under environmental stress with or without the involvement of abscisic acid as molecular signal. The different problems associated with desiccation encountered by resurrection plants render the employment of many interacting mechanisms necessary. Preservation of cell order and correct structure of membranes and macromolecules is underpinned by the synthesis of large amounts of sugars, amino acids, and small polypeptides such as late embryogenesis abundant (LEA) proteins and dehydrins. Some of these compatible solutes, such as sucrose and LEA proteins, are also involved in cytoplasm vitrification, which occurs during the last phase of desiccation. Mechanical damage due to vacuole shrinkage in dehydrating cells is avoided by cell wall folding or by replacing the water in vacuoles with nonaqueous substances. Oxidative stress, due to enhanced production of reactive oxygen species (ROS) especially by chloroplasts, is minimized through two different strategies. The homoiochlorophyllous resurrection plants, which conserve chloroplasts with chlorophylls and thylakoids upon drying, fold leaf blades and synthesize anthocyanins, as both sunscreens and free radical scavengers, and additionally increase the activity of antioxidant systems in cells. In contrast, the chloroplasts in poikilochlorophyllous species degrade chlorophylls and thylakoid membranes yielding desiccoplasts that are devoid of any internal structures. These adaptive mechanisms preserve cells from damage by desiccation and allow them to resume vital functions once rehydrated. Even if based mainly on cell protection during drying, the vegetative desiccation-tolerance of resurrection plants also relies on systems of cell recovery and repair upon rehydration. However, most of these systems are prepared during cell dehydration.     

Xylem Hydraulic Characteristics, Water Relations and Wood Anatomy of the Resurrection PlantMyrothamnus flabellifoliusWelw.

Myrothamnus flabellifoliusWelw. is a desiccation-tolerant (‘resurrection’)plant with a woody stem. Xylem vessels are narrow (14 µmmean diameter) and perforation plates are reticulate. This leadsto specific and leaf specific hydraulic conductivities thatare amongst the lowest recorded for angiosperms (k_s0.87 kg m^-1MPa^-1s^-1;k_l3.28x10^-5kg m^-1MPa^-1s^-1, stem diameter 3 mm). Hydraulic conductivitiesdecrease with increasing pressure gradient. Transpiration ratesin well watered plants were moderate to low, generating xylemwater potentials of -1 to -2 MPa. Acoustic emissions indicatedextensive cavitation events that were initiated at xylem waterpotentials of -2 to -3 MPa. The desiccation-tolerant natureof the tissue permits this species to survive this interruptionof the water supply. On rewatering the roots pressures thatwere developed were low (2.4 kPa). However capillary forceswere demonstrated to be adequate to account for the refillingof xylem vessels and re-establishment of hydraulic continuityeven when water was under a tension of -8 kPa. During dehydrationand rehydration cycles stems showed considerable shrinking andswelling. Unusual knob-like structures of unknown chemical compositionwere observed on the outer surface of xylem vessels. These maybe related to the ability of the stem to withstand the mechanicalstresses associated with this shrinkage and swelling.Copyright1998 Annals of Botany Company cavitation, desiccation, hydraulic conductivity, refilling, resurrection plant, root pressure, xylem anatomy,Myrothamnus flabellifolius     

Characterization of oxidative and antioxidative events during dehydration and rehydration of resurrection plant <Emphasis Type="Italic">Ramonda nathaliae</Emphasis>

In order to investigate changes of oxidative status in relation to the activity of the various protective mechanisms in resurrection plant Ramonda nathaliae, we have analysed time and relative water content (RWC) related changes in lipid peroxidation and ion leakage, hydrogen peroxide accumulation, changes of pigment content and antioxidative enzyme activity, together with expression of dehydrins. The results indicate that enhanced oxidative status during dehydration, not previously reported for resurrection plants, could play an active role in inducing the desiccation adaptive response in R. nathaliae. A critical phase is shown to exist during dehydration (in the range of RWC between 50 and 70%) during which a significant increase in hydrogen peroxide accumulation, lipid peroxidation and ion leakage, accompanied by a general decline in antioxidative enzyme activity, takes place. This phase is designated as a transition characterized by change in the type of stress response. The initial response, relying mainly on the enzymatic antioxidative system, is suspended but more effective, desiccation specific protective mechanisms, such as expression of dehydrins, are then switched on. The expression of dehydrins in R. nathaliae could be inducible as well as constitutive. In order to cope with the oxidative stress associated with rapid rewatering, R. nathaliae reactivated antioxidative enzymes. We propose that controlled elevation of reactive oxygen species, such as hydrogen peroxide, could be an important mechanism enabling resurrection plants to sense dehydration and to trigger an adaptive programme at an appropriate stage during the dehydration/rehydration cycle.