IntroductionHevea brasiliensis (Wil

Introduction

Hevea brasiliensis (Willd. Ex A. Juss) Müll. Arg (rubber tree) is a tropical plant belonging to the Euphorbiaceae family, which is cultivated worldwide and especially in Southeast Asia, to produce natural rubber (NR). NR is a cis-1,4-polyisoprene biopolymer of high economic importance (for review see [1]), which is produced from the latex after tapping. Latex is a complex white cytoplasmic system produced by plant laticifers, which contains mainly rubber and non-rubber particles, organelles, proteins and cytoplasmic C-serum [2]. The hevea latex contains many proteins and at least 13 are allergens, as Hevb3 and Hevb1 [3], [4], [5], [6], [7]. Both proteins are abundant and associated with latex allergy, particularly in individuals with Spina bifida who undergo frequent surgeries [8], [9], [10]. REF and SRPP share several IgE epitopes [11], but their role in the immune mechanism leading to latex hypersensitivity has not yet been determined. They are also named Small Rubber Particle Protein (SRPP) and the Rubber Elongation Factor (REF) [8], [12], [13]. SRPP is specifically localized in the laticifer layers in the conducting phloem, whereas REF is localized in all laticifer layers [14]. Indeed, REF and SRPP have been respectively visualized by immunogold electron microscopy on the Large Rubber Particles (LRP, generally above 0.4 µM in diameter) and the Small Rubber Particles (SRP, smaller than 0.4 µM in diameter) [8], [12], [15], [16], [17]. In addition, SRPs were also described as having much higher enzymatic activity at their surface than LRPs do [16], [18].

The NR synthesis is regulated by the activity of rubber particle-associated proteins present at the surface of the membrane monolayer, which surrounds the rubber particles [19], [20], [21]. Various enzymes such as prenyl transferases or synthases have been characterized in latex and are clearly elongating the rubber polymer by condensing isopentenyldiphosphate (IPP) with dimethylallyldiphosphate (DMAPP) or isoprenyl intermediates [22], [23]. Three more proteins, SRPP, the Guayule Homologue of SRPP (GHS) and REF were also described as having a positive effect on rubber elongation [12], [13], [24], [25]. Hevea genes encoding for REF and SRPP proteins have been cloned [5], [13], [26], [27] and various isoforms identified [28], [29]. Messenger RNAs of REF and SRPP have been found to be highly expressed in the Hevea latex and laticifers [28], [30], [31], [32]. Tree tapping stimulates the gene expression of both proteins [32], [33]. REF expression is also positively correlated with latex yield in Hevea [32] and Dennis and Light [12] also showed that the amount of REF protein in the whole latex was proportional to rubber content. REF and SRPP proteins from hevea latex are acidic proteins respectively of 14.6 and 24 kDa, which were believed to not be post-translationally modified [8]. But recently, SRPP was described as a glycoprotein susceptible to interact with a hevea latex lectin present on lutoids and susceptible to play a role in latex coagulation [25]. REF was also shown as a native protein able to tetramerize as a protein of about 58 kDa [4]. However, no information is available on their respective structure.

In order to evaluate the possible functions of REF and SRPP in latex, we purified in this study both recombinant proteins and analyzed various biochemical and structural properties. As REF displayed aggregative and amyloid features, we characterized its structure by circular dichroism (CD), transmission electronic microscopy (TEM), infra-red spectroscopy (ATR-FTIR) and X-ray diffraction (WAXS). To go further in the comparison of REF and SRPP function, we also evaluated the kind of interaction that each protein could have with various lipids, using dot blots (bulk lipids) or model lipid monolayers at the air-water interface. If both proteins are really closely related in term of amino-acid sequences, we demonstrate in this study that their structure are neatly different (REF being able to switch into an amyloid form), and that their mode of interaction with the surface of the lipid monolayer (mimicking the one surrounding latex particle) is also different, which may suppose also different roles of REF and SRPP, particularly in natural rubber biosynthesis.