Weapon (thorn) automimicry and mimicry of aposematic colorful thorns in plants

In order to further characterize the function of coloration in plants as defense against herbivory, two types of thorn mimicry are described: (1) A unique type of weapon (thorn) automimicry (within the same individual) that was previously known only in animals, and (2) mimicry of aposematic colorful thorns, by colorful elongated and pointed plant organs (buds, leaves and fruit) that, despite their appearance, are not sharp. Some thorny plants including dozens of species of Agave, one species of Aloe and a palm species have thorn-like imprints or colorations on their leaves, constituting thorn automimicry by giving the impression of more extensive thorns. The mimicry of aposematic colorful thorns is a typical case of Batesian mimicry, but the thorn automimicry is a special intra-organismic Batesian mimicry. I propose that both types of mimicry serve as anti-herbivore mechanisms.     

Metabolic pools associated with monoterpene biosynthesis in higher plants

Partial degradations of (+)-isothujone biosynthesised in Tanacetum vulgare after feeding IPP-[4-¹⁴C], DMAPP-[4-¹⁴C] or 3,3-dimethylacrylate-[Me-¹⁴C], and of geraniol and (+)-pulegone formed in Pelargonium graveolens and Mentha pulegium respectively after uptake of 3,3-dimethylacrylate-[Me-¹⁴C], indicated that none of these metabolites was a direct source of the part of the monoterpene skeleton derived hypothetically from DMAPP. Uptake of glucose-[U¹⁴C] into P. graveolens led, in contrast, to both IPP and DMAPP-derived moieties of geraniol being extensively labelled. Feeding of l-valine-[U-¹⁴C] and l-leucine-[U-¹⁴C] to all three plants resulted in negligible incorporation of tracer into monoterpenes. A soluble enzyme system prepared from foliage of T. vulgare that had been exposed to CO₂-[¹⁴C] for 20 days converted isotopically-normal IPP into GPP with the DMAPP-derived portion containing essentially all (>98%) of the radioactivity present. These observations and those previously obtained from feeding experiments with other [¹⁴C]-labelled precursors on the same plant species are consistent with the occurrence of two metabolic pools of intermediates for monoterpene biosynthesis, one of which is probably protein-bonded.     

高等植物花色苷在液泡中的存在状态及其着色效应

综述了花色苷被摄入液泡的原因、花色苷在液泡中的存在状态及其对植物细胞的着色效应。花色苷在植物细胞质中合成后转运到液泡里是为了解除其对蛋白质和DNA等细胞功能分子的毒性。花色苷的液泡区隔化是花色苷在植物细胞中发挥正常功能的前提。在大多数植物中,花色苷在绝大多数情况下完全溶解在液泡里。但是,花色苷也能在液泡里形成颗粒,这些颗粒可以划分为花色苷体和花色苷液泡包涵体两类。花色苷体由膜包裹,其形成是液泡中小的有色囊泡逐渐合并的结果,发育完全的花色苷体为典型的球状、具比液泡更深的红色;液泡里的花色苷体具高密度,呈现为含高浓度花色苷的不溶性小球;花色苷体的存在可导致液泡的强烈色彩。花色苷液泡包涵体可能具备蛋白质基质,既无膜包裹又无内部结构,其形成是转运进液泡的花色苷与蛋白质基质结合的结果;液泡里的花色苷液泡包涵体形状不规则,象果冻;在花色苷液泡包涵体中,花色苷可能通过氢键连接于蛋白质基质的一个有限空间位点;花色苷液泡包涵体被认为是液泡中花色苷的"陷阱",优先摄取花色素3,5-二糖苷或酰化的花色苷;花色苷液泡包涵体的存在可增加液泡色彩的强度并导致"蓝化"。     

Markers and signals associated with nitrogen assimilation in higher plants

A key concept underpinning current understanding of the carbon/nitrogen (C/N) interaction in plants is that the capacity for N assimilation is aligned to nutrient availability and requirements by the integrated perception of signals from hormones, nitrate, sugars, organic acids, and amino acids. Studies on the nature and integration of these signals over the last ten years has revealed a complex network of controls brokered by an interplay of C and N signals. These controls not only act to orchestrate the relative rates of C and N assimilation and carbohydrate and amino acid production, but they also have a significant influence on plant development. Amino acids are the hub around which the processes of N assimilation, associated C metabolism, photorespiration, export of organic N from the leaf, and the synthesis of nitrogenous end-products revolve. Since specific major amino acids or their relative ratios are modulated differentially by photorespiration and N assimilation, even though these processes are tightly intermeshed, they are potentially powerful markers for metabolite profiling and metabolomics approaches to the study of plant biology. Moreover, while minor amino acids show marked diurnal rhythms, their contents fluctuate in a co-ordinated manner. It is probable that factors associated with early events and processes in C and N assimilation influence the relative composition of minor amino acids.     

Prosomes (proteasomes) of higher plants

From different plant tissues such as tobacco (Nicotiana rustica), potato (Solanum tuberosum), and mung bean (Phaseolus radiatus), ring- or cylinder-shaped particles called prosomes were isolated by either sucrose gradient centrifugation or fast protein liquid chromatography (FPLC). These particles have a diameter of 12 to 14 nm and a length of 16 to 18 nm. They migrate under conditions of nondenaturing gel electrophoresis as one distinct band. Sedimentation coefficient and buoyant density in Cs2SO4 of the plant prosomes were determined by analytical ultracentrifugation to be approximately 23S and 1.23 g/cm3, respectively. The total molecular mass was estimated by gel filtration to be 650 kDa. Plant prosomes are composed of 12 to 15 proteins with molecular masses in the range of 24 to 35 kDa with isoelectric points of pH 5 to 7 as revealed by two-dimensional gel electrophoresis. The protein patterns of prosomes from the three different plant species are very similar. Polyclonal antisera against potato prosomes reacted in Western blots with prosomal proteins of all three plant species. They also bind to some prosomal proteins of animal species. Antisera against animal prosomes react with some proteins of plant prosomes. As shown by lectin blotting, plant prosomes are glycosylated carrying glucosyl- or mannosyl, and N-acetylgalactosaminyl residues. Prosomal preparations contain non-stoichiometric amounts of small RNA of about 80 kDa. These results suggest that plant prosomes are structurally and functionally homologous to prosomes of other eukaryotic cells.     

Dimethylsulphoniopropionate (DMSP) and related compounds in higher plants

Dimethylsulphoniopropionate (DMSP) is produced in high concentrations in many marine algae, but in higher plants only in a few salt marsh grasses of the genus Spartina, in sugar canes (Saccharum spp.), and in the Pacific strand plant Wollastonia biflora (L.) DC. The high concentrations found in higher plants (up to 250 micromol g(-1) dry weight) suggest an important role, but though many functions have been suggested (including methylating agent, detoxification of excess sulphur, salt tolerance, and herbivore deterrent), its actual functions remain unclear. The fact that the ability to produce DMSP in high concentrations is found in species that have no taxonomic or ecological relationship suggests that the compound evolved independently and serves different functions in different plants. This is supported by observations that DMSP in W. biflora behaves differently from that in Spartina species. While DMSP concentrations in W. biflora have been found to increase with increasing salinity, suggesting a role in osmotic control, such a relationship has not been found for DMSP in Spartina species. Recent observations on tissue culture showed that, while undifferentiated tissue of W. biflora produced DMSP, such material of Spartina alterniflora Loisel. did not. Ongoing studies with tissue culture of both species have opened up new avenues of research on DMSP in higher plants, ultimately to elucidate the functions of this enigmatic compound.     

Heterozygosity and orange coloration are associated in the guppy (Poecilia reticulata)

The good‐genes‐as‐heterozygosity hypothesis predicts that more elaborate male sexual ornaments are associated with higher levels of heterozygosity. Recent theoretical work suggests that such associations are likely to arise in finite, structured populations. We investigated the correlation between multilocus heterozygosity (MLH), which was estimated using 13 microsatellite loci, and male coloration in a wild population of guppies (Poecilia reticulata), a model species in sexual selection research. We found that MLH was a significant predictor of the relative area of orange spots, a trait that is subject to strong female preference in this species. Neither the relative area of black spots nor the number of black or orange spots was significantly correlated with MLH. We found no statistical support for local effects (i.e. strong effects of heterozygosity at specific markers), which suggests that relative orange spots area reflects genome‐wide heterozygosity.     

Global biogeography of warning coloration in the butterfly Danaus chrysippus

Warning coloration provides a textbook example of natural selection, but the frequent observation of polymorphism in aposematic species presents an evolutionary puzzle. We investigated biogeography and polymorphism of warning patterns in the widespread butterfly Danaus chrysippus using records from citizen science (n = 5467), museums (n = 8864) and fieldwork (n = 2586). We find that polymorphism in three traits controlled by known mendelian loci is extensive. Broad allele frequency clines, hundreds of kilometres wide, suggest a balance between long-range dispersal and predation of unfamiliar morphs. Mismatched clines for the white hindwing and forewing tip in East Africa are consistent with a previous finding that the black wingtip allele has spread recently in the region through hitchhiking with a heritable endosymbiont. Light/dark background coloration shows more extensive polymorphism. The darker genotype is more common in cooler regions, possibly reflecting a trade-off between thermoregulation and predator warning. Overall, our findings show how studying local adaptation at the global scale provides a more complete picture of the evolutionary forces involved.     

Diversity in warning coloration is easily recognized by avian predators

Warning coloration is a widespread strategy to alert predators about prey unprofitability. The success of this strategy partly depends on predators being able to learn and recognize certain signals as indicators of toxicity, and theory predicts that this is easier if signals converge on similar colours. However, the diversity in warning signal form is astonishing, contradicting predictions. Here, we quantified ladybird signal diversity with respect to avian vision, measuring how unique and discernible each signal is from one another. In addition, we measured signal conspicuousness against a series of backgrounds, namely an average green, average brown, and where we collected each species, to determine whether signals are more contrasting against the ladybirds’ local substrates than compared to average ones. This allowed us to establish whether there are local adaptations in conspicuousness that promote signal diversity. We found that while ladybird signals are unique and recognizable, specialist species are more contrasting against the background they are most commonly found on. However, overall our study suggests that warning signals have evolved to be effective against a wide range of natural backgrounds, partly explaining the success of this strategy in nature.     

Linking the evolution and form of warning coloration in nature

Many animals are toxic or unpalatable and signal this to predators with warning signals (aposematism). Aposematic appearance has long been a classical system to study predator–prey interactions, communication and signalling, and animal behaviour and learning. The area has received considerable empirical and theoretical investigation. However, most research has centred on understanding the initial evolution of aposematism, despite the fact that these studies often tell us little about the form and diversity of real warning signals in nature. In contrast, less attention has been given to the mechanistic basis of aposematic markings; that is, ‘what makes an effective warning signal?’, and the efficacy of warning signals has been neglected. Furthermore, unlike other areas of adaptive coloration research (such as camouflage and mate choice), studies of warning coloration have often been slow to address predator vision and psychology. Here, we review the current understanding of warning signal form, with an aim to comprehend the diversity of warning signals in nature. We present hypotheses and suggestions for future work regarding our current understanding of several inter-related questions covering the form of warning signals and their relationship with predator vision, learning, and links to broader issues in evolutionary ecology such as mate choice and speciation.     

Centrin homologues in higher plants are prominently associated with the developing cell plate

Summary Centrin and calmodulin are members of the EF-hand calcium-binding superfamily of proteins. In this study we compared localisation and immunoblotting of centrin with calmodulin in several monocot (onion and wheat) and dicot (mung bean andArabidopsis) plants. We confirmed that an anti-calmodulin antibody recognised a 17 kDa protein in all species tested and localises to the cytoplasm, mitotic matrix and with microtubules of the preprophase band and phragmoplast. In contrast, immunoblotting using anti-centrin antibodies shows that plant centrins vary from 17 to 20 kDa. Immunofluorescence microscopy with anti-centrin antibodies revealed only weak centrin immunoreactivity in the cytoplasm, nucleus, nuclear envelope, phragmoplast and mitotic matrix in meristematic cells. There was a slightly more intense perinuclear labelling in large differentiating onion cells and between separating anaphase chromosomes. While centrin is known to localise to the mitotic spindle poles in animal and algal cells, there was no appreciable immunoreactivity at the spindle poles in higher plants. In contrast, there was an intense immunofluorescence signal with anti-centrin antibodies in the developing cell plate. Further characterisation of the cell plate labelling by immunogold electron microscopy shows centrin immunoreactivity was closely associated with vesicles in the cell plate. Our observations suggest that centrin may play a role in cell plate formation.Abbreviations BSA bovine serum albumin - MTs microtubules - MTOCs microtubule organising centres - PBS phosphate buffered saline - PBST phosphate buffered saline with Tween-20     

Carotenoids and abscisic acid (ABA) biosynthesis in higher plants

Recent research has revealed that abscisic acid (ABA), synthesised in response to water stress, is an apo-carotenoid. Two potential carotenoid precursors, 9'- cis -neoxanthin and 9- cis -violaxanthin, have been identified in light-grown and etiolated leaves, and in roots of a variety of species. Experiments utilizing etiolated Phaseolus vulgaris leaves and deuterium oxide strongly suggest that 9'- cis -neoxanthin, synthesised from all- trans -violaxanthin, is the immediate pre-cleavage precursor of ABA. The cleavage of 9'- cis -neoxanthin, performed by an inducible and specific dioxygenase, is likely to be the rate-limiting step in ABA biosynthesis. Any apocarotenoids formed as by-products of cleavage are probably rapidly degraded by lipoxygenase or related enzymes. After cleavage xanthoxin is converted via ABA-aldehyde to ABA by constitutive enzymes in the cytosol.     

The shared and separate roles of aposematic (warning) coloration and the co-evolution hypothesis in defending autumn leaves

The potential anti-herbivory functions of colorful (red and yellow) autumn leaves received considerable attention in the last decade. The most studied and discussed is the co-evolutionary hypothesis, according to which autumn coloration signals the quality of defense to insects that migrate to the trees in autumn. In addition to classic aposematism (repellency due to signaling unpalatability, non profitability of consumption, or danger for whatever reasons) that operates immediately, this hypothesis also proposes that the reduced fitness of the insects is in their next generation hatching in the spring from eggs laid on the trees in autumn. Supporters of the co-evolutionary hypothesis either posited that this hypothesis differs from visual aposematism or ignored the issue of aposematism. Interestingly, other authors that cited their papers considered the co-evolutionary hypothesis as visual aposematism. Recently, the overlap between the co-evolutionary hypothesis and visual aposematism was finally recognized, with the exception of yellow autumn leaves not signaling defense to aphids, which are known to be attracted to yellow leaves. However, the detailed relationships between these two hypotheses have not been discussed yet. Here I propose that the co-evolutionary hypothesis generally equals visual aposematism in red and yellow autumn leaves towards all herbivores except for yellow not operating with aphids. The co-evolutionary signaling extends beyond classic aposematism because it may operate later and not only immediately. The possibility that for yellow autumn leaves the co-evolutionary hypothesis may also operate via olfactory aposematism should not be dismissed.Key words: aposematic, autumn coloration, co-evolution, defense, evolution, herbivory, treesColorful (red and yellow) autumn leaves dominate large areas of America, Asia and Europe, expressed by thousands of tree, shrub and climber species.^1–5 In the last decade, this phenomenon received considerable scientific attention. For a long time it was a common belief that this coloration is the by-product of the cessation of masking by chlorophylls that degrade in autumn. However, two key theoretical and experimental developments stimulated the recent wave of study of autumn leaf coloration. The first was the recognition that anthocyanins are synthesized de novo in red autumn leaves,^1,2 and the second was the formulation of the anti-herbivory co-evolutionary hypothesis.^6–8The updated version of the co-evolutionary hypothesis⁹ posits that red autumn coloration signals to all types of insects (including aphids) that migrate to the trees in autumn about their chemical defense, lower nutritional quality or imminent leaf fall, or any other characteristic that would induce a lower fitness in the insects. In addition, yellow leaves signals the same to all herbivores except aphids. A special aspect of the co-evolutionary hypothesis is that the reduced fitness of the insects is not only immediate, reducing insect feeding in autumn, but also related to the reduced development of the next generation that hatches in the following spring from eggs laid on the trees in the autumn.⁹ Originally, the co-evolutionary hypothesis addressed both red and yellow autumn leaves.^6–8 However, with the later understanding that yellow leaves usually attract rather than repel aphids,^9–13 the co-evolutionary hypothesis was later restricted to red leaves when aphids are concerned.⁹In addition to other various potential anti-herbivory roles,^14,15 red autumn leaf coloration has several potential physiological functions, such as protection from photoinhibition and photo oxidation, and other physiological functions have been proposed but not agreed upon.^{1,2,9,16–21}     

Warning coloration associated with nematocyst-based defences in aeolidiodean nudibranchs

This study examines the mechanisms of aposematism (unprofitabilityof prey combined with a conspicuous signal) in the aeolidioideanCratena peregrina (Gmelin, 1791). We investigated if marinefish avoid attacking aeolidioidean nudibranchs, which are anunprofitable group of prey for most predators. We analysed theinteraction between aeolids and predatory fish in laboratoryand field assays, with both live aeolids and artificial models.In the first experiment, we offered normal and blue-dyed C.peregrina to fish in the field. The number of attacks by fishwas independent of the density of the prey, albeit the normalaeolids were attacked less frequently than the blue ones. Thefact that all normal C. peregrina survived, whereas 12–20%of the blue aeolids died after fish attacks, suggests that aposematiccoloration provides a selective advantage against fish predators.Field and laboratory assays with artificial aeolids were employedto test the effects of different factors (number of cerata,colour pattern, nematocysts), or a combination of factors, onfish learning. Fish learned to avoid unpalatable models withthe colour pattern of C. peregrina. After three to four trainingsessions with unprofitable models, fish avoided profitable modelswith the same colour pattern. Our results suggest that the colourpattern of C. peregrina combined with the presence of dorsalappendages and nematocysts make fish avoid aeolids. (Received 22 January 2004; accepted 18 August 2006)     

Evidence for an intramembrane component associated with a cellulose microfibril-synthesizing complex in higher plants

Freeze-fracture of rapidly frozen, untreated plant cells reveals terminal complexes on E-fracture faces and intramembrane particle rosettes on P-fracture faces. Terminal complexes and rosettes are associated with the ends of individual microfibril impressions on the plasma membrane. In addition, terminal complexes and rosettes are associated with the impressions of new orientations of microfibrils. These structures are sparse within pit fields where few microfibril impressions are observed, but are abundant over adjacent impressions of microfibrils. It is proposed that intramembrane rosettes function in association with terminal complexes to synthesize microfibrils. The presence of a cellulosic microfibril system in Zea mays root segments is confirmed by degradation experiments with Trichoderma cellulase.     

A systematic search for positive selection in higher plants (Embryophytes)

Background  

Previously, a database characterizing examples of Embryophyte gene family lineages showing evidence of positive selection was reported. Of the gene family trees, 138 Embryophyte branches showed Ka/Ks>>1 and are candidates for functional adaptation. The database and these examples have now been studied in further detail to better understand the molecular basis for plant genome evolution.