A Complex Sub-cellular Component of Widespread Occurrence in Plant Latices

A survey of exudates from a number of latex-bearing plants revealsthe wide-spread occurrence of a complex subcellular componentapparently analogous to the ‘lutoid’ of Hevea brasiliensislatex. Under the conditions of our experiments this componentis usually associated with thread-like material.     

Localization and Behaviour of Actin Microfilaments in Laticiferous Cells of Hevea brasiliensis in Latex Exploitation

Actin microfilaments of laticiferous cells and bark wounds in Hevea brasiliensis were studied using TRITC-phalloidin fluorescent microscopy. Actin in latex from mature rubber trees was also investigated using SDS-PAGE and western-boltting. TRITC-fluorescent substance plugged the end of laticifers when latex flow stopped. Actin was detected only in C serum among the four latex fractions. Higher actin content was found in the latex collected at the beginning of tapping than in that collected just before latex flow stopped. Lower actin content was detected in the latex from rubber trees with more intensive exploitation. The present study indicated that actin microfilaments might play an important role in regulation of latex flow and plugging of the laticifers wounds.     

Polyphenoloxidase Silencing Affects Latex Coagulation in Taraxacum Species

Latex is the milky sap that is found in many different plants. It is produced by specialized cells known as laticifers and can comprise a mixture of proteins, carbohydrates, oils, secondary metabolites, and rubber that may help to prevent herbivory and protect wound sites against infection. The wound-induced browning of latex suggests that it contains one or more phenol-oxidizing enzymes. Here, we present a comprehensive analysis of the major latex proteins from two dandelion species, Taraxacum officinale and Taraxacum kok-saghyz, and enzymatic studies showing that polyphenoloxidase (PPO) is responsible for latex browning. Electrophoretic analysis and amino-terminal sequencing of the most abundant proteins in the aqueous latex fraction revealed the presence of three PPO-related proteins generated by the proteolytic cleavage of a single precursor (pre-PPO). The laticifer-specific pre-PPO protein contains a transit peptide that can target reporter proteins into chloroplasts when constitutively expressed in dandelion protoplasts, perhaps indicating the presence of structures similar to plastids in laticifers, which lack genuine chloroplasts. Silencing the PPO gene by constitutive RNA interference in transgenic plants reduced PPO activity compared with wild-type controls, allowing T. kok-saghyz RNA interference lines to expel four to five times more latex than controls. Latex fluidity analysis in silenced plants showed a strong correlation between residual PPO activity and the coagulation rate, indicating that laticifer-specific PPO plays a major role in latex coagulation and wound sealing in dandelions. In contrast, very little PPO activity is found in the latex of the rubber tree Hevea brasiliensis, suggesting functional divergence of latex proteins during plant evolution.Latex is a milky sap produced by more than 12,500 plant species spanning 20 families (Metcalfe, 1966). It is often white or colorless but can range from yellow to scarlet (e.g. in some members of the poppy family [Papaveraceae]). Latex coagulates when exposed to air and consists of an emulsion of polymers and metabolites that are often bitter or toxic. Therefore, it is proposed that natural latex has a protective function, sealing wounds, acting as a barrier to microorganisms, and discouraging herbivory (El Moussaoui et al., 2001). In addition to a wide range of low-molecular-weight polypeptides (Nessler and Burnett, 1992; Azarkan et al., 2004), several other proteins and enzymes have been identified in the latices of laticiferous plants. These include the wound-induced proteins trypsin inhibitor, class II chitinase, and glutaminyl cyclase in the latex of papaya (Carica papaya; Azarkan et al., 2004) as well as chitinases and β-1,3-glucanase in the latex of the rubber tree Hevea brasiliensis (Martin, 1991; Subroto et al., 1996). The latex from some plants is a good source of natural rubber, and H. brasiliensis is widely cultivated for this purpose.Latex is produced in specialized cells known as laticifers, which arise in two distinct ways depending on the species (Evert, 2006). Articulated laticifers (found in the Papaveraceae, Asteraceae, and in H. brasiliensis) are organized in longitudinal chains originally laid down in the meristem, and the cell walls become perforated or completely degraded during development to form continuous channels called latex vessels. In contrast, nonarticulated laticifers (found in milkweeds [Asclepias spp.]) are organized in a branching system originating from a single precursor cell in the embryo that divides rapidly and spreads invasively during development. These are multinucleate cells that tend not to fuse into vessels (Serpe et al., 2002).Taraxacum officinale (common dandelion) and Taraxacum kok-saghyz (Russian dandelion) are members of the Asteraceae and therefore possess articulated laticifers (Esau, 1965; Evert, 2006) that secrete a latex rich in polyphenols (Schütz et al., 2005; C. Schulze Gronover, unpublished data). T. kok-saghyz latex is a good source of high-molecular-weight rubber (Mooibroek and Cornish, 2000; Bushman et al., 2006) and was investigated as an alternative to H. brasiliensis during World War II, when rubber supplies to Europe and the United States were interrupted. Unfortunately, the extraction of rubber from Russian dandelion latex is laborious and expensive because of rapid coagulation, and further development was abandoned when Hevea rubber became available. Coagulation of H. brasiliensis latex is caused by the major latex proteins (MLPs), which include hevein, the hevein receptor, and chitinase (Gidrol et al., 1994; Chrestin et al., 1997). A similar role has been proposed for the polyphenoloxidases (PPOs) present in the latex of certain Hevea spp. (Hanower and Brzozowska, 1977), although our data indicate that this is not the case.PPOs are found throughout the plant kingdom (Mayer and Harel, 1979; Vaughn and Duke, 1984; Mayer, 1987; Vaughn et al., 1988; Sherman et al., 1991), and they probably play a role in defense against pathogens and herbivores (Vörös et al., 1957; Felton et al., 1989; Duffey and Felton, 1991; Constabel and Ryan, 1998; Stout et al., 1999; Gatehouse, 2002). They are plastid-localized copper metalloenzymes that catalyze the oxidation of o-diphenols to o-diquinones (diphenolase activity; EC 1.10.3.2) and, in some species, also the o-hydroxylation of monophenols (monophenolase activity; EC 1.14.18.1; Vaughn et al., 1988; Mayer, 2006). Quinones are highly reactive electrophiles responsible for much of the oxidative browning in fruits and vegetables after wounding (Yoruk and Marshall, 2003). The wound-inducible expression of PPOs has been reported in apple (Malus domestica; Boss et al., 1995), tomato (Solanum lycopersicum; Constabel et al., 1995; Thipyapong and Steffens 1997), potato (Solanum tuberosum; Thipyapong et al., 1995), and hybrid poplar (Populus spp.; Constabel et al., 2000). In addition, the down-regulation of PPO activity by antisense RNA in tomato confers hypersusceptibility to pathogens (Thipyapong et al., 2004), whereas PPO overexpression confers enhanced resistance to bacterial diseases (Li and Steffens, 2002). It has also been suggested that PPOs evolved to protect plants against photochemical oxidation, since most PPOs characterized thus far appear to be localized in the plastids of photosynthetic cells (Sherman et al., 1995).The rapid wound-induced browning of dandelion latex suggests the presence of significant PPO activity in the laticifers. Here, we show that the PPO is the major component of the latex proteome in Taraxacum spp. and that the down-regulation of PPO activity by RNA interference (RNAi) in transgenic T. officinale and T. kok-saghyz plants inhibits browning and coagulation. This suggests that PPO may be a key factor controlling the coagulation of dandelion latex and thus its protective role. This contrasts to the situation in H. brasiliensis, where we show that PPO appears to have a negligible effect on latex coagulation.     

A Cellulase in Hevea Latex

Using a viscometric method the latex of Hevea brasiliensis was found to contain a highly active cellulase capable of hydrolysing carboxymethyl cellulose. The enzyme has a pH optimum of around 6.3. It is present in the serum of the latex and is not membrane-bound to any significant extent. Similar cellulase activities were detected in latex from old and new latex vessel rings and also in latex from regularly tapped vessels and newly tapped vessels. The possible role of the enzyme in the removal of cell wall material during the differentiation of latex vessels is discussed.     

Ethylene stimulation of latex production in Hevea brasiliensis

Rubber tree (Hevea brasiliensis) is an important industrial crop for natural rubber production. Ethylene, as a stimulant of latex production in H. brasiliensis, has been widely used in commercial latex production. However, the mechanism of ethylene action are not completely elucidated, especially in molecular aspect. Here, we focus on the molecular biological progression of ethylene stimulation of latex production. Our data and all previous information showed ethylene had little direct effect on accelerating rubber biosynthesis. The prolonged latex flow and acceleration of sucrose metabolism by ethylene may be the main reasons for the stimulation of latex yield by ethylene.Key words: Hevea brasiliensis, ethylene, rubber production, gene, sucrose     

Phospholipid composition of the membrane of lutoids from Hevea brasiliensis latex

Intact lutoids were isolated from the latex of Hevea brasiliensis and purified on a sucrose density gradient. Lutoid membranes prepared by osmotic lysis are characterized by a high content of phosphatidic acid in which unsaturated and saturated fatty acids are present in equal proportions. Linolenic acid is absent. The results are discussed in relation to the biological role of lutoids in the latex vessels of Hevea brasiliensis.     

Ultrastructure of Laticifers Modifications in Hevea brasiliensis Infected with Root Rot Fungi

This paper presents some aspects of latex coagulation inside latice vessels of roots of Hevea brasiliensis infected by two fungi: Rigidoporus lignosus and Phellinus noxius. Three stages are described in latex coagulation: the phase of latex destabilisation characterized by the bursting of vacuoles and lysosomes membranes; the phase of latex coagulation characterized by the fusion of rubber particles and the disorganization of the cytoplasm; the formation of shots of rubber clumps indicating the final stage of coagulation.     

The Role of Lipids and Proteins in the Mechanism of Latex Vessel Plugging in Hevea brasiliensis

The phospholipid content of the bottom fraction of latex as well as the neutral lipids of rubber particles were determined in thirty-one clonal mother trees of RRII clones of Hevea brasiliensis Muell. Arg. Ratios between cationic proteins and anionic proteins in the B-sera, which is the sera contained in the lutoid particles in latex, obtained from clones RRIM-501, PB 6/9, RRII-105 and Tjir-l were determined by electrophoresis. The influence of these factors on plugging index (a measure of the magnitude of latex vessel plugging) was investigated. Lutoid instability, as indicated by bursting index, is negatively ocrrelated with the phospholipid content of the bottom fraction of latex. The neutral lipid content of rubber particles is positively correlated with the colloidal stability of latex. The latex vessel plugging during latex flow is found to be negatively correlated with both the lutoid stability and the neutral lipids in the rubber particle. A high ratio of cationic and anionic proteins in B-serum may also enhance the process of plugging.     

The leaf, inner bark and latex cyanide potential of Hevea brasiliensis: Evidence for involvement of cyanogenic glucosides in rubber yield

The latex of Hevea brasiliensis, expelled upon bark tapping, is the cytoplasm of anastomosed latex cells in the inner bark of the rubber tree. Latex regeneration between two tappings is one of the major limiting factors of rubber yield. Hevea species contain high amounts of cyanogenic glucosides from which cyanide is released when the plant is damaged providing an efficient defense mechanism against herbivores. In H. brasiliensis, the cyanogenic glucosides mainly consist of the monoglucoside linamarin (synthesized in the leaves), and its diglucoside transport-form, linustatin. Variations in leaf cyanide potential (CNp) were studied using various parameters. Results showed that the younger the leaf, the higher the CNp. Leaf CNp greatly decreased when leaves were directly exposed to sunlight. These results allowed us to determine the best leaf sampling conditions for the comparison of leaf CNp. Under these conditions, leaf CNp was found to vary from less than 25 mM to more than 60 mM. The rubber clones containing the highest leaf CNp were those with the highest yield potential. In mature virgin trees, the CNp of the trunk inner bark was shown to be proportional to leaf CNp and to decrease on tapping. However, the latex itself exhibited very low (if any) CNp, while harboring all the enzymes (β-d-diglucosidase, linamarase and β-cyanoalanine synthase) necessary to metabolize cyanogenic glucosides to generate non-cyanogenic compounds, such as asparagine. This suggests that in the rubber tree bark, cyanogenic glucosides may be a source of buffering nitrogen and glucose, thereby contributing to latex regeneration/production.     

Micro‐organisms in latex and natural rubber coagula of Hevea brasiliensis and their impact on rubber composition,structure and properties

Natural rubber, produced by coagulation of the latex from the tree Hevea brasiliensis, is an important biopolymer used in many applications for its outstanding properties. Besides polyisoprene, latex is rich in many nonisoprene components such as carbohydrates, proteins and lipids and thereby constitutes a favourable medium for the development of micro‐organisms. The fresh rubber coagula obtained by latex coagulation are not immediately processed, allowing the development of various microbial communities. The time period between tree tapping and coagula processing is called maturation, during which an evolution of the properties of the corresponding dry natural rubber occurs. This evolution is partly related to the activity of micro‐organisms and to the modification of the biochemical composition. This review synthesizes the current knowledge on microbial populations in latex and natural rubber coagula of H. brasiliensis and the changes they induce on the biochemistry and technical properties of natural rubber during maturation.     

Early Activation by Ethylene of the Tonoplast H-Pumping ATPase in the Latex from Hevea brasiliensis

The treatment of Hevea brasiliensis (rubber tree) bark by chloro-2-ethyl phosphonic acid (ethrel), an ethylene-producing compound, induces a significant increase in the tonoplast H⁺-translocating ATPase activity in the latex during the first 24 hours after the application of the stimulating agent. Moreover, the tonoplast-bound ATPase is highly activated when vacuoles (lutoids) are resuspended in ultrafiltrated cytosol. This effect is amplified during ethrel stimulation. Preliminary assays to characterize the endogenous effector(s) suggest that the activator(s) could be a heat-resistant compound with a low molecular weight, most likely an anion. The activation of the tonoplast-bound ATPase and the associated activation of the protons translocation across the lutoid membrane, could explain the cytosolic alkalinization observed in latex following the ethrel treatment of Hevea bark, which results in an enhanced rubber production.     

Regulation of Natural Rubber Biosynthesis by Proteins Associated with Rubber Particles

Natural rubber, cis-1,4-polyisoprene, is an essential raw material used in thousands of products, many of which are absolutely necessary for medical purposes. Natural rubber is obtained from latex, an aqueous emulsion present in the laticiferous vessels of the natural rubber-producing plants. Hevea brasiliensis (the Brazilian rubber tree) currently is the only commercially important source of natural rubber. H. brasiliensis crops have very little genetic variability, leaving rubber plantations at risk of serious pathogenic attacks. In addition, repeated exposure to residual proteins in latex products derived from H. brasiliensis have led to serious and widespread allergic (type I) hypersensitivity. Therefore, identification of alternative sources of natural rubber is a very important biotechnological task. Potentially, Russian dandelion (Taraxacum kok-saghyz) may be such an alternative because significant amounts of natural rubber are produced in its root system. However, H. brasiliensis is a more efficient producer of natural rubber than T. kok-saghyz. Thus, improvement of rubber biosynthesis in plants is a first-priority problem of modern biotechnology. In this review, we describe proteins that may increase the concentration of natural rubber in laticiferous vessels of T. kok-saghyz and its close relative Taraxacum brevicorniculatum, when overexpressed in the plants. These proteins, cis-prenyltransferases, rubber transferase activator, and small rubber particle proteins, are directly involved in synthesis of the polyisoprene chain. We also analyze the effects of their expression levels on the production of natural rubber in vivo.     

The biosynthesis of rubber: Incorporation of isopentenyl pyrophosphate into purified rubber particles by a soluble latex serum enzyme

1. The rubber particles in Hevea brasiliensis latex have been partially purified by `washing' with buffer solution, and separated into active fractions of different particle size. 2. The enzyme responsible for incorporating isopentenyl pyrophosphate into rubber is distributed between the surface of the rubber particles and the aqueous serum phase of the latex. The enzyme at the surface can be removed or inactivated if the rubber particles are washed sufficiently with buffer solution. Enzyme in the serum phase can be concentrated by fractional precipitation with ammonium sulphate. 3. To incorporate isopentenyl pyrophosphate into rubber in vitro, active rubber particles are required as well as enzyme and soluble cofactors. The activity of the rubber particles per unit surface area increases with diminishing particle size.     

Ethylene Production by Hevea brasiliensis Tissues Treated with Latex Yield-stirnulatory Compounds

Leaflets and pieces of immature stem of Hevea brasiliensis weretreated with a range of compounds, and the subsequent ratesof release of ethylene compared with the reported efficacy ofthe individual substances as stimulants of latex yield. Themost effective ethylene inducers were also the best stimulants.Amongst the 53 compounds tested, no compound which was not ayield stimulant induced the formation of significant amountsof ethylene. Of all the known stimulants tested, only acetylenewas neither converted to, nor induced the formation of ethylene.     

Yeasts in <Emphasis Type="Italic">Hevea brasiliensis</Emphasis> latex

Yeast abundance and species diversity in the latex of rubber tree Hevea brasiliensis (Willd. ex Juss.) Müll. Arg., on its green leaves, and in soil below the plant were studied. The yeasts present in the fresh latex in numbers of up to 5.5 log(CFU/g) were almost exclusively represented by the species Candida heveicola. This species was previously isolated from Hevea latex in China. In the course of natural modification of the latex (turned from liquid to solid form), yeast diversity increased, while yeast abundance decreased. The yeasts in thickened and solidified latex were represented by typical epiphytic and ubiquitous species: Kodamea ohmeri, Debaryomyces hansenii, Rhodotorula mucilaginosa, and synanthropic species Candida parapsilosis and Cutaneotrichosporon arboriformis. The role of yeasts in latex modification at the initial stages of succession and their probable role in development of antifungal activity in the latex are discussed.     

Modification of pH of latex cytoplasm by ethylene

In the absence of glycolytic activity the pH of isolated latex cytoplasm of Hevea brasiliensis increases progressively during the first hours of incubation. This increase is greatly enhanced after bark treatment with 2-chloroethylphosphonic acid. The process of alkalization is not enzymic and is oxygen dependent. This observation is discussed in relation to the increase in latex pH in situ under hormone action.