Abstracts

Comparative analysis of leaf cell-wall polysaccharides of Dialypetalanthus fuscescens and Bathysa meridionalis: evidence of biochemical similarities between Dialypetalanthaceae and Rubiaceae-Cinchonoideae

FABIO MORAES¹ 1 . Instituto de Botânica, Seção de Fisiologia e Bioquímica de Plantas, Caixa Postal 4005, 01061-970 São Paulo, SP, Brasil. , MICHAEL G. HAHN² 1 . Instituto de Botânica, Seção de Fisiologia e Bioquímica de Plantas, Caixa Postal 4005, 01061-970 São Paulo, SP, Brasil. and MARCIA R. BRAGA¹ 1 . Instituto de Botânica, Seção de Fisiologia e Bioquímica de Plantas, Caixa Postal 4005, 01061-970 São Paulo, SP, Brasil. ,³ 1 . Instituto de Botânica, Seção de Fisiologia e Bioquímica de Plantas, Caixa Postal 4005, 01061-970 São Paulo, SP, Brasil.

(received: January 5, 2001; accepted: June 6, 2001)

ABSTRACT - (Comparative analysis of leaf cell-wall polysaccharides of Dialypetalanthus fuscescens and Bathysa meridionalis: evidence of biochemical similarities between Dialypetalanthaceae and Rubiaceae-Cinchonoideae). Dialypetalanthus fuscescens is an Amazonian endemic species with problematic taxonomic position. This neotropical rainforest tree belongs to the monospecific Dialypetalanthaceae. In the present work, we analysed the leaf cell-wall polysaccharide composition of Dialypetalanthus fuscescens and compared it to that of Bathysa meridionalis (Rubiaceae-Cinchonoideae). Glycosyl composition and glycosyl-linkage analysis indicated that both species have similar cell wall composition. Arabinogalactans were the major component of the pectic polysaccharides and xylans, although being reported in minor amounts in dicots, were found to be the predominant hemicellulosic polysaccharide in cell walls of both species. These findings are in agreement with previous data on cell wall composition reported for Rubiaceae and corroborate the current suggestion of the possible link between this family and Dialypetalanthaceae.

RESUMO - (Análise comparativa de polissacarídeos de paredes celulares de folhas de Dialypetalanthus fuscescens e Bathysa meridionalis: evidências de similaridades bioquímicas entre Dialypetalanthaceae e Rubiaceae-Cinchonoideae). Dialypetalanthus fuscescens é uma espécie endêmica da Amazônia com posição taxonômica incerta. Esta espécie da floresta úmida neotropical pertence à família monoespecífica Dialypetalanthaceae. Neste trabalho, foi analisada a composição dos polissacarídeos de paredes celulares de folhas de Dialypetalanthus fuscescens e esta comparada com Bathysa meridionalis (Rubiaceae-Cinchonoideae). Análises de composição química e ligações glicosídicas demonstraram que ambas as espécies possuem composição química da parede celular bastante similar. Arabinogalactanos foram identificados como os polissacarídeos pécticos predominantes e os xilanos, embora menos freqüentes em dicotiledôneas, foram encontrados em grandes quantidades na fração hemicelulósica de ambas as espécies. Esses resultados estão de acordo com outros previamente reportados para Rubiaceae e constituem uma evidência adicional da possível proximidade taxonômica de Dialypetalanthaceae com Rubiaceae, como atualmente aceito.

Key words - Dialypetalanthaceae, Amazonian tree, Bathysa meridionalis, Rubiaceae, Cinchonoideae, cell-wall polysaccharides

Introduction

Dialypetalanthus fuscescens Kuhlm. is an endemic Amazonian tree, being the only species of the Dialypetalanthaceae. Its taxonomic position is problematic since this species combines characters such as buds protected by stipules, paracytic stomata, numerous unitegmic ovules, and a well-developed endosperm that suggest a close relationship with the Rubiaceae, with primitive features such as free petals and dimerous floral whorls that are enough to set it apart from the Gentianales (Piesschaert et al. 1997). When in vegetative stage, D. fuscescens is hardly distinguishable from certain Rubiaceae-Cinchonoideae (Piesschaert et al. 1995).

In the past, D. fuscescens was suggested to be closely related to the Myrtales or Rosales (Rizzini & Occhioni 1949, Cronquist 1968). More recently the affinity of this species with Rubiales or Gentianales has been proposed (Dahlgren & Thorne 1984) and accepted instead. However, the lack of ontogenetic and micro- and macromolecular data on D. fuscescens has limited a proper judgement about the possible relationships of this species with other plants (Piesschaert et al. 1997).

Cell wall composition has been used as a taxonomic character to distinguish plant taxa at several hierarchic levels (Reid & Meier 1970, Buckeridge et al. 1995, Carpita 1996, Braga & Dietrich 1999, Szweykowski & Buczkowska 1999). Variations in composition and fine structure of cell-wall polysaccharides have been shown to be useful, in some cases, to substantiate plant phylogenetic relationships proposed on the basis of anatomical features and chemical constituents (Buckeridge et al. 1995, Carpita 1996, Carnachan & Harris 2000).

In the present work, we analysed the polysaccharide composition of leaf cell walls of D. fuscescens and compared it to that of Bathysa meridionalis, a Rubiaceae-Cinchonoideae species.

Material and methods

Plant material - Leaves of Dialypetalanthus fuscescens Kuhlm. (Dialypetalanthaceae) were collected in the Amazonian forest (Buriti, Rondônia, Brazil) and of Bathysa meridionalis Smith & Downs (Rubiaceae-Cinchonoideae) in the forest of Reserva Biológica do Parque Estadual das Fontes do Ipiranga (São Paulo, SP, Brazil). Voucher samples are filed in the Herbarium "Eneida K. Fidalgo" (Instituto de Botânica, SP, Brazil) with numbers SP 300077 and SP 28634, respectively.

Preparation of cell walls - Cell walls were prepared as alcohol-insoluble residue (AIR) as described by Fry (1988). The AIR was washed in acetone (x5) dried at room temperature, and subjected to sequential extraction. Prior to extraction, fibers were separated using a Granutest sieve (20 mesh) and discarded.

Fractionation of cell-wall material - Cell walls were delignified with 3% sodium chlorite (NaClO₂) in 0.4% acetic acid at 80 °C. After 1 h, NaClO₂ and acetic acid concentration were increased to 4% and 0.8%, respectively, and the incubation was carried out for an additional 2 h with continuous shaking. The insoluble material was suspended in deionized water and centrifuged at 2500 g. The pellet was washed twice in water, recovered by centrifugation and freeze-dried. The supernatants were combined, dialyzed for 48 h, lyophilized, weighed and considered as NaClO₂ fraction. Cell-wall polysaccharides were obtained from the delignified pellet as described by Gorshkova et al. (1996). The pellet was initially extracted twice with 0.5% ammonium oxalate (pH 7) at 80 °C under N₂ for 1 h each. The depectinized cell walls were then extracted twice with 4 M KOH (containing 3 mg/ml sodium borohydride) at 25 °C under N₂ for 1 h each. The fraction yields were determined gravimetrically.

Gel-permeation chromatography - Fractions dissolved in 150 mM McIlvaine buffer (pH 5.2) were loaded onto a Sepharose 4B column (1.5 cm i.d. x 87 cm, Pharmacia). Eluted fractions (3 ml) were collected and assayed for uronic acids and sugar content. Linear dextrans (Mr 2,000 and 76 kDa) were used for calibration.

Colorimetric assay - Uronic acid content was determined by the m-hydroxybiphenyl method (Filisetti-Cozzi & Carpita 1991) using galacturonic acid as standard. Sugar content was estimated by phenol-sulfuric assay using glucose as standard (Dubois et al. 1956).

Sugar composition - Neutral and acidic glycosyl compositions were determined as described (York et al. 1985). Briefly, samples were hydrolyzed with 1.0 M methanolic-HCl for 16 h at 80 °C. The released methylglycosides were dried down and N-acetylated using methanol and acetic anhydride (1:1, v:v) for 15 min at 45 °C. The acetylated samples were trimethyl-silylated (TMS) with Tri-Sil and resolved on a 30 m DB-1 column (0.25 x 0.25, i.d.; J & W Scientific, Folsom, CA) in a Hewlett Packard 5985 GC-MS system using myo-inositol as internal standard. The following temperature conditions were used: 160 °C for 3 min, then raised to 200 °C at 2 °C/min, and increased to 260 °C at 10 °C/min. A standard of derivatized methylglycosides were also run for comparison and identification of peaks.

Sugar linkage analysis - Glycosyl linkage composition was analysed by Gas Chromatography coupled to mass spectrometry (GC-MS) of partially O-methylated alditol acetates. Per-O-methylation was performed using the Hakomori method (Hakomori 1964). The methylated polysaccharides were then isolated by extraction with methylene chloride, dried down, and subjected to sequential hydrolysis (2 M TFA, 120 °C for 2 h), reduction (sodium borodeuteride, NaBD₄), and acetylation using acetic anhydride and pyridine. The resulting partially methylated alditol acetates were analyzed by GC-MS using a 30 m Sp2330 column in a Hewlett-Packard 5985 GC-MS system using myo-inositol as internal standard. The following temperature conditions were used: 2 min at an initial temperature of 80 °C, increased to 170 °C at 30 °C/min, then to 240 °C at 40 °C/min and held 5 min at 240 °C.

Results and Discussion

The fractionation of leaf cell walls of D. fuscescens by chemical extraction yielded hemicelluloses as the major fraction (table 1). Although NaClO₂ also extracted a significant amount of material, colorimetric analysis indicated that the carbohydrate content of this fraction was 27.1%, compared with 78.3% for the 4 M KOH extract.

Differences in the amounts of material released from the walls by each extraction were found between D. fuscescens and B. meridionalis (table 1). Nevertheless, the total percentage of sugars and uronic acids recovered were similar for both species, accounting for ca. 27% and 13% of the cell wall dry wt, respectively. The carbohydrate content of the ammonium oxalate (36.4%) and KOH (79.6%) extracts of B. meridionalis was also similar to those of D. fuscescens.

A delignification procedure also extracted part of the pectins from cell walls of D. fuscescens since the same sugar residues predominated in the NaClO₂ and ammonium oxalate soluble fractions (table 2). The large amounts of arabinosyl and galactosyl residues found in these fractions, and the presence of 4-linked galactosyl residues and a high proportion of t-arabinosyl residues detected by glycosyl linkage composition analysis indicated the presence of arabinogalactans as the predominant neutral component of the pectic polysaccharides (table 3). Linkage analyses of these neutral components also revealed small amounts of 3,6-linked galactosyl residues suggesting that pectins from both fractions also contain type-II arabinogalactans (table 3). Arabinose and galactose were also the major neutral components found in NaClO₂ and ammonium oxalate fractions of B. meridionalis (table 2). These sugars have been reported to constitute large proportion of the pectins from cell walls of Alibertia myrcifolia, another Cinchonoideae-Rubiaceae species from tropical forests (Braga et al. 1998).

Galacturonic acid was also found in high proportion in the NaClO₂ and ammonium oxalate soluble fractions of D. fuscescens (table 2). 2- and 2,4-linked rhamnosyl residues commonly associated with rhamnogalacturoran-I were detected only in small amounts in these fractions (not shown). Although these findings suggest that homogalacturonans are the major acidic polysaccharides in the pectins of D. fuscescens, the possibility that considerable amounts of rhamnose were lost after derivatization can not be discarded.

The monosaccharide composition of ammonium oxalate soluble fraction from B. meridionalis was very similar to that of D. fuscescens (table 2). The rare sugars, 2-O-methyl fucose, 2-O-methyl xylose and apiose, typical of the rhamnogalacturoran-II portion of pectins, were detected in trace amounts in the ammonium oxalate fractions of both species.

The material extracted by strong alkali from the leaf cell walls of D. fuscescens and B. meridionalis was rich in xylose and contained considerable amounts of arabinose, galactose and glucose (table 2). From methylation analysis, 4-linked xylosyl was the most abundant linkage, indicating the presence of a xylan as the major fraction of the KOH extract of these species. This polymer appears to be branched at every 8-10 residues solely at the O-2 position, as indicated by the relative amount of 2,4-linked xylosyl residues (table 3). The presence of this substituted xylan accounted in part for the t-Ara present in this fraction. Xylans, although being reported as a minor component of hemicelluloses from dicots and non-gramineous monocots (Carpita & Gibeaut 1993), were shown to predominate in leaf cell walls of two Cinchonoideae-Rubiaceae species from tropical environment (Braga et al. 1998). The linkage analyses (table 3) revealed a 4-linked xylan with a low degree of branching exclusively at the O-2 position, which could be explained, at least in part, due to the presence of secondary cell walls commonly found in leaf tissues. On the other hand, glycosyl linkages expected from xyloglucan of type-I walls (2-xylosyl, 4,6-glucosyl, 2-galactosyl and t-fucosyl) were not detected in the KOH fractions suggesting that this polysaccharide is present only in minute amounts in the cell walls of both species. Cell suspension cultures of R. jasminoides, a tropical Cinchonoideae-Rubiaceae species, show that, although xyloglucan is also present in their primary cell walls, the arabinoxylan is the predominant hemicellulosic polysaccharide found in the cells of this species (C.O. Fernandes, M.S. Buckeridge and M.R. Braga, unpublished data). These findings suggest that xylans instead of xyloglucans can account for most of the leaf hemicelluloses found in the Cinchonoideae species analysed and also in D. fuscencens.

4-Linked mannosyl residues, although detected in low amounts in 4 M KOH extracts and in the pectic material from D. fuscencens and B. meridionalis, indicated the presence of a glucomannan (table 3).

Gel permeation profiles of NaClO₂ and KOH soluble fractions are shown in figure 1. For both species, uronic acids of the NaClO₂ fractions co-eluted with the largest bulk of neutral sugars. Most of the pectic polymers of the NaClO₂ fractions eluted at Mr lower than 76 kDa (figure 1A, C). Total carbohydrate profile of D. fuscescens showed small amounts of polysaccharides of high Mr which were not detected in extracts of B. meridionalis (figure 1A, C). The KOH extracts of both species also had similar elution patterns of neutral sugars on Sepharose 4B, presenting a broad peak centered around 76 kDa (figure 1C, D). Although again in minor proportion, higher Mr polysaccharides were found only in D. fuscescens. Due to the very small amount of material available, ammonium oxalate fractions were not analysed by gel permeation chromatography.

From these results, we conclude that the cell-wall polysaccharides of D. fuscescens and B. meridionalis have similar glycosyl and glycosyl-linkage compositions. The presence of a xylan as the predominant hemicellulosic polysaccharide of leaf cell walls of D. fuscescens resembles the composition already reported for leaf cell walls of two Rubiaceae-Cinchonoideae (Braga et al. 1998), thus corroborating the current suggestion of a link between Dialypetalanthaceae and Rubiaceae. Additional leaf cell wall glycosyl and glycosyl-linkage composition data from other species in families of the Gentianales would be necessary to substantiate the usefulness of cell wall composition data as a taxonomic marker. At present, such data are not available.

Acknowledgments - We thank Dr. Nicholas C. Carpita (University of Purdue, USA) for technical suggestions, and Dr. Marcos S. Buckeridge for the critical review of the manuscript. We also thank Dr. Parastoo Azadi (CCRC/UGA, USA) for the glycosyl and glycosyl linkage composition analyses. Thanks are due to CNPq (Brazil) for the fellowship to F. Moraes and for the research fellow grant to M.R. Braga. This work was also supported in part by FAPESP (BIOTASP, 98/05124-8, Brazil) and by the Department of Energy-funded (DE-FG05-93ER-20097) Center for Plant and Microbial Complex Carbohydrates.

2. University of Georgia, Complex Carbohydrate Research Center and Department of Botany, 220 Riverbend Road, 30602-4712 Athens, GA, USA.

3. Corresponding author: bragamr@canalvip.com.br

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