Cell wall polysaccharides are specifically involved in the exclusion of aluminum from the rice root apex

Rice (Oryza sativa) is the most aluminum (Al)-resistant crop species among the small-grain cereals, but the mechanisms responsible for this trait are still unclear. Using two rice cultivars differing in Al resistance, rice sp. japonica 'Nipponbare' (an Al-resistant cultivar) and rice sp. indica 'Zhefu802' (an Al-sensitive cultivar), it was found that Al content in the root apex (0-10 mm) was significantly lower in Al-resistant 'Nipponbare' than in sensitive 'Zhefu802', with more of the Al localized to cell walls in 'Zhefu802', indicating that an Al exclusion mechanism is operating in 'Nipponbare'. However, neither organic acid efflux nor changes in rhizosphere pH appear to be responsible for the Al exclusion. Interestingly, cell wall polysaccharides (pectin, hemicellulose 1, and hemicellulose 2) in the root apex were found to be significantly higher in 'Zhefu802' than in 'Nipponbare' in the absence of Al, and Al exposure increased root apex hemicellulose content more significantly in 'Zhefu802'. Root tip cell wall pectin methylesterase (PME) activity was constitutively higher in 'Zhefu802' than in 'Nipponbare', although Al treatment resulted in increased PME activity in both cultivars. Immunolocalization of pectins showed a higher proportion of demethylated pectins in 'Zhefu802', indicating a higher proportion of free pectic acid residues in the cell walls of 'Zhefu802' root tips. Al adsorption and desorption kinetics of root tip cell walls also indicated that more Al was adsorbed and bound Al was retained more tightly in 'Zhefu802', which was consistent with Al content, PME activity, and pectin demethylesterification results. These responses were specific to Al compared with other metals (CdCl(2), LaCl(3), and CuCl(2)), and the ability of the cell wall to adsorb these metals was also not related to levels of cell wall pectins. All of these results suggest that cell wall polysaccharides may play an important role in excluding Al specifically from the rice root apex.     

Putrescine alleviates aluminum toxicity in rice (Oryza sativa) by reducing cell wall Al contents in an ethylene‐dependent manner

Aluminum (Al³⁺) toxicity in acidic soils limits crop productivity worldwide. In this study, we found that putrescine (PUT) significantly alleviates Al toxicity in rice roots. The addition of 0.1 mM PUT promoted root elongation and reduced the Al content in the root apices of Nipponbare (Nip) and Kasalath (Kas) rice under Al toxicity conditions. Exogenous treatment with PUT reduced the cell wall Al content by reducing polysaccharide (pectin and hemicellulose) levels and pectin methylesterase (PME) activity in roots and decreased the translocation of Al from the external environment to the cytoplasm by downregulating the expression of OsNRAT1, which responsible to encode an Al transporter protein Nrat1 (Nramp aluminum transporter 1). The addition of PUT under Al toxicity conditions significantly inhibited ethylene emissions and suppressed the expression of genes involved in ethylene biosynthesis. Treatment with the ethylene precursor 1‐aminocylopropane‐1‐carboxylic acid (ACC) significantly improved ethylene emission, inhibited root elongation, increased the Al accumulation in root tips and the root cell wall, and increased cell wall pectin and hemicellulose contents in both rice cultivars under Al toxicity conditions. The ethylene biosynthesis antagonist aminoethoxyvinylglycine (AVG, inhibitor of the ACC synthase) had the opposite effect and reduced PME activity. Together, our results show that PUT decreases the cell wall Al contents by suppressing ethylene emissions and decreases the symplastic Al levels by downregulating OsNRAT1 in rice.     

Exogenous nitric oxide enhances cadmium tolerance of rice by increasing pectin and hemicellulose contents in root cell wall

To study the mechanisms of exogenous NO contribution to alleviate the cadmium (Cd) toxicity in rice (Oryza sativa), rice plantlets subjected to 0.2-mM CdCl₂ exposure were treated with different concentrations of sodium nitroprusside (SNP, a NO donor), and Cd toxicity was evaluated by the decreases in plant length, biomass production and chlorophyll content. The results indicated that 0.1 mM SNP alleviated Cd toxicity most obviously. Atomic absorption spectrometry and fluorescence localization showed that treatment with 0.1 mM SNP decreased Cd accumulation in both cell walls and soluble fraction of leaves, although treatment with 0.1 mM SNP increased Cd accumulation in the cell wall of rice roots obviously. Treatment with 0.1 mM SNP in nutrient solution had little effect on the transpiration rate of rice leaves, but this treatment increased pectin and hemicellulose content and decreased cellulose content significantly in the cell walls of rice roots. Based on these results, we conclude that decreased distribution of Cd in the soluble fraction of leaves and roots and increased distribution of Cd in the cell walls of roots are responsible for the NO-induced increase of Cd tolerance in rice. It seems that exogenous NO enhances Cd tolerance of rice by increasing pectin and hemicellulose content in the cell wall of roots, increasing Cd accumulation in root cell wall and decreasing Cd accumulation in soluble fraction of leaves.     

Proteoid Root Development of Phosphorus Deficient Lupin is Mimicked by Auxin and Phosphonate

White lupin (Lupinus albus L.) develops proteoid (cluster) rootsin response to phosphorus deficiency. Proteoid roots are composedof tight clusters of rootlets that initiate from the pericycleopposite protoxylem poles and emerge from every protoxylem polewithin the proteoid root axis. Auxins are required for lateralroot development, but little is known of their role in proteoidroot formation. Proteoid root numbers were dramatically increasedin P-sufficient (+P) plants by application of the syntheticauxin, naphthalene acetic acid (NAA), to leaves, and were reducedin P-deficient (-P) plants by the presence of auxin transportinhibitors [2,3,5-triiodobenzoic acid (TIBA) and naphthylphthalamicacid (NPA)]. While ethylene concentrations in the root zonewere 1.5-fold higher in -P plants, there was no effect on proteoidroot numbers of the ethylene inhibitors aminoethoxyvinvylglycine(AVG) and silver thiosulphate. Phosphonate, which interfereswith plant perception of internal P concentration, dramaticallyincreased the number of proteoid root segments in +P plants.Activities of phosphoenolpyruvate carboxylase (PEPC), malatedehydrogenase (MDH) and exuded acid phosphatase in proteoidroot segments were not different from +P controls when NAA wasapplied to +P lupin plants, but increased to levels comparableto -P plants in the phosphonate treatment. Addition of TIBAor NPA to -P plants reduced PEPC and MDH activity of -P proteoidroots to levels found in +P or -P normal root tissues, but didnot affect acid phosphatase in root exudates. These resultssuggest that auxin transport from the shoot plays a role inthe formation of proteoid roots during P deficiency. Auxin-stimulatedproteoid root formation is necessary, but not sufficient, tosignal the up-regulation of PEPC and MDH in proteoid root segments.In contrast, phosphonate applied to P-sufficient white lupinelicits the full suite of coordinated responses to P deficiencyCopyright2000 Annals of Botany Company Lupinus albus L., white lupin, proteoid roots, auxin, ethylene, phosphonate, phosphorus deficiency     

Model studies on the role of citrate, malate and pectin esterification on the enzymatic degradation of Al- and Ca-pectate gels: possible implications for Al-tolerance

Aluminium (Al) tolerance in plants may be conferred by reduced binding of Al in the cell wall through low root cation exchange capacity (CEC) or by organic acid exudation. Root CEC is related to the degree of esterification (DE) of pectin in the cell wall, and pectin hydrolysis plays a role in cell expansion. Therefore, it was hypothesised that Al-tolerant plants with a low root CEC maintain pectin hydrolysis in the presence of Al, allowing cell expansion to continue. Irrespective of the DE, binding of Al to pectin reduced the enzymatic hydrolysis of Al-pectin gels by polygalacturonase (E.C. 3.2.1.15). Pectin gels with calcium (Ca) were slightly hydrolysed by polygalacturonase. It was concluded, therefore, that Al tolerance conferred by low root CEC is not mediated by the ability to maintain pectin hydrolysis. Citrate and malate, but not acetate, effectively dissolved Al-pectate gel and led to hydrolysis of the dissolved pectin by polygalacturonase. The organic acids did not dissolve Ca-pectate, nor did they increase pectin hydrolysis by polygalacturonase. It was concluded that exudation of some organic acids can remove Al bound to pectin and this could alleviate toxicity, constituting a tolerance mechanism.     

Response to Phosphate Deficiency in Bean (Phaseolus vulgarisL.) Roots. Respiratory Metabolism, Sugar Localization and Changes in Ultrastructure of Bean Root Cells

Bean plants (Phaseolus vulgarisL. ‘Zlota Saxa’)were cultured on complete (+P) or phosphate-deficient (-P) nutrientmedium. A large increase in glucose concentration was foundin the meristematic zone of -P roots compared to control roots.The increased glucose concentration in the meristematic zonedid not influence total respiration rate. Glucose or uncoupler(carbonyl cyanide m-chlorophenylhydrazone) failed to increasethe respiration rate in -P root segments, but stimulated respirationin +P roots. The ultrastructure of cortical cells from the meristematicroot zone showed marked differences between +P and -P plants.Large vacuoles, invaginations of the plasmalemma and condensedforms of mitochondria were dominating features in cortical cellsof -P roots. Analysis of extracts after treating roots withdimethylsulfoxide (DMSO) indicated different localization ofsugars in the cell compartments. In roots of -P plants, mostof the reducing sugars were detected in the cytoplasm fractionwhile most sucrose was in the vacuole. Observations of the effectof 10% DMSO on cell ultrastructure indicated partial destructionof the plasmalemma but not the tonoplast. The localization ofreducing sugars in secondary vacuoles or plasmalemma invaginationsin the cells from the meristematic region of -P roots is discussed.Copyright1998 Annals of Botany Company. Bean (Phaseolus vulgarisL.), roots, Pi deficiency, respiration, meristematic zone, ultrastructure, sugar efflux, reducing sugars and sucrose localization.     

Citrate-permeable channels in the plasma membrane of cluster roots from white lupin

White lupin (Lupinus albus) is well adapted to phosphorus deficiency by developing cluster roots that release large amounts of citrate into the rhizosphere to mobilize the sparingly soluble phosphorus. To determine the mechanism underlying citrate release from cluster roots, we isolated protoplasts from different types of roots of white lupin plants grown in phosphorus-replete (+P) and phosphorus-deficient (-P) conditions and used the patch-clamp technique to measure the whole-cell currents flowing across plasma membrane of these protoplasts. Two main types of anion conductance were observed in protoplasts prepared from cluster root tissue: (1) an inwardly rectifying anion conductance (IRAC) activated by membrane hyperpolarization, and (2) an outwardly rectifying anion conductance (ORAC) that became more activated with membrane depolarization. Although ORAC was an outward rectifier, it did allow substantial inward current (anion efflux) to occur. Both conductances showed citrate permeability, with IRAC being more selective for citrate3- than Cl- (PCit/PCl = 26.3), while ORAC was selective for Cl- over citrate (PCl/PCit = 3.7). Both IRAC and ORAC were sensitive to the anion channel blocker anthracene-9-carboxylic acid. These currents were also detected in protoplasts derived from noncluster roots of -P plants, as well as from normal (noncluster) roots of plants grown with 25 microm phosphorus (+P). No differences were observed in the magnitude or frequency of IRAC and ORAC currents between the cluster roots and noncluster roots of -P plants. However, the IRAC current from +P plants occurred less frequently than in the -P plants. IRAC was unaffected by external phosphate, but ORAC had reduced inward current (anion efflux) when phosphate was present in the external medium. Our data suggest that IRAC is the main pathway for citrate efflux from white lupin roots, but ORAC may also contribute to citrate efflux.     

Phosphorus deficiency enhances aluminum tolerance of rice (Oryza sativa) by changing the physicochemical characteristics of root plasma membranes and cell walls

The negative charge at the root surface is mainly derived from the phosphate group of phospholipids in plasma membranes (PMs) and the carboxyl group of pectins in cell walls, which are usually neutralized by calcium (Ca) ions contributing to maintain the root integrity. The major toxic effect of aluminum (Al) in plants is the inhibition of root elongation due to Al binding tightly to these negative sites in exchange for Ca. Because phospholipid and pectin concentrations decrease in roots of some plant species under phosphorus (P)-limiting conditions, we hypothesized that rice (Oryza sativa L.) seedlings grown under P-limiting conditions would demonstrate enhanced Al tolerance because of their fewer sites on their roots. For pretreatment, rice seedlings were grown in a culture solution with (+P) or without (−P) P. Thereafter, the seedlings were transferred to a solution with or without Al, and the lipid, pectin, hemicellulose, and mineral concentrations as well as Al tolerance were then determined. Furthermore, the low-Ca tolerance of P-pretreated seedlings was investigated under different pH conditions. The concentrations of phospholipids and pectins in the roots of rice receiving −P pretreatment were lower than those receiving +P pretreatment. As expected, seedlings receiving the −P pretreatment showed enhanced Al tolerance, accompanied by the decrease in Al accumulation in their roots and shoots. This low P-induced enhanced Al tolerance was not explained by enhanced antioxidant activities or organic acid secretion from roots but by the decrease in phospholipid and pectin concentrations in the roots. In addition, low-Ca tolerance of the roots was enhanced by the −P pretreatment under low pH conditions. This low P-induced enhancement of low-Ca tolerance may be related to the lower Ca requirement to maintain PM and cell wall structures in roots of rice with fewer phospholipids and pectins.     

稻、麦根系H~ 的分泌与介质磷水平的关系

水稻、小麦根系H~ 的分泌量随供磷水平的降低而增加,并存在明显的昼夜变化。在自然光照下H~ 分泌量随光强度增加而增多,同时强光比黑暗时H~ 分泌对磷供应水平更为敏感。磷供应不足还诱导水稻根系柠檬酸分泌量增加,而苹果酸则差异不明显。难溶性磷的溶解率与根系H~ 和柠檬酸分泌所导致的根际pH下降有密切联系。因此,在有效磷不足的条件下可明显提高稻、麦根际土壤中难溶性磷的利用率,其中丰产型小麦和粳稻品种对土壤中磷利用的根际效应更为显著。     

Species variability in boron requirement is correlated with cell wall pectin

Fourteen species of crop plants which differ in their reportedtissue boron requirements were grown in B-replete or B-deficientmedium. Leaf samples were collected and analysed for B and cellwall components. There was a significant positive correlationamong the species between B concentration in the leaf or thecell wall and uronic acid, rhamnose and galactose (indicativeof pectin) in the cell wall. The concentration of cell wallpectin was also positivety related with reported tissue-B requirementsand observed sensitivity to B deficiency. Boron deficiency didnot alter the amount of uronic acid present in cell walls, suggestingthat there was no effect of B deficiency on pectin metabolism.Under B-deficient conditions the amount of ‘soluble’B (i.e. B not associated with the cell wall) declined dramaticallywhile the proportion of cellular B that was ‘insoluble’(i.e. B associated with the cell wall) increased. The positiverelationship between pectin content, insoluble B and tissue-Brequirement of diverse species suggests that the amount of cellwall pectin may be significant in determining the relative tissue-Brequirements of the species. These results indicate that either(1) species with high cell wall pectin contents require greateramounts of B for the construction of the cell wall, or (2) pectinin cell walls forms an insoluble complex with B, thereby reducingits availability for other putative B-requiring metabolic functions.Thus, species with a high pectin content would have a highertissue-B requirement. Key words: Boron, deficiency, uronic acid, pectin, cell wall     

Glucose alleviates cadmium toxicity by increasing cadmium fixation in root cell wall and sequestration into vacuole in Arabidopsis

Glucose(Glu) is involved in not only plant physiological and developmental events but also plant responses to abiotic stresses. Here, we found that the exogenous Glu improved root and shoot growth, reduced shoot cadmium(Cd) concentration, and rescued Cdinduced chlorosis in Arabidopsis thaliana(Columbia ecotype,Col-0) under Cd stressed conditions. Glucose increased Cd retained in the roots, thus reducing its translocation from root to shoot signi fi cantly. The most Cd retained in the roots was found in the hemicellulose 1. Glucose combined with Cd(Glu t Cd) treatment did not affect the content of pectin and its binding capacity of Cd while it increased the content of hemicelluloses 1 and the amount of Cd retained in it signi fi cantly. Furthermore, Leadmium Green staining indicated that more Cd was compartmented into vacuoles in Glu t Cd treatment compared with Cd treatment alone, which was in accordance with the R e ssigni fi cant upregulation of the expression of tonoplastlocalized metal transporter genes, suggesting that compartmentation of Cd into vacuoles also contributes to the Glu-alleviated Cd toxicity. Taken together, we demonstrated that Glu-alleviated Cd toxicity is mediated through increasing Cd fi xation in the root cell wall and sequestration into the vacuoles.     

Transgenic proteoid roots of white lupin: a vehicle for characterizing and silencing root genes involved in adaptation to P stress

White lupin (Lupinus albus L.) has become an illuminating model for the study of plant adaptation to phosphorus (P) deficiency. It adapts to -P stress with a highly coordinated modification of root development and biochemistry resulting in short, densely clustered secondary roots called proteoid (or cluster) roots. In order to characterize genes involved in proteoid root formation and function in a homologous system, we have developed an Agrobacterium rhizogenes-based transformation system for white lupin roots that allows rapid analysis of reporter genes as well as RNA interference (RNA(i))-based gene silencing. We used this system to characterize a lupin multidrug and toxin efflux (Lupinus albus MULTIDRUG AND TOXIN EFFLUX, LaMATE) gene previously shown to have enhanced expression under -P stress. Here, we show that LaMATE had high expression in proteoid roots not only under -P, but also under -Fe, -N, -Mn and +Al stress. A portion containing the putative LaMATE promoter was fused to GUS and enhanced green fluorescence protein (EGFP) reporter genes, and a translational LaMATE::EGFP fusion was constructed under control of the LaMATE promoter. The LaMATE promoter directed P-dependent GUS and EGFP expression to proteoid roots. Confocal microscopy in white lupin and Arabidopsis point to the plasma membrane as the likely location of the LaMATE protein. LaMATE displayed homology to FRD3 in Arabidopsis, but did not complement an Arabidopsis ferric reductase defective 3 (FRD3) mutant. RNA(i)-based gene silencing was shown to effectively reduce LaMATE expression in transformed white lupin roots. LaMATE RNAi-silenced plants displayed an about 20% reduction in dry weight.     

Cell-wall pectin and its degree of methylation in the maize root-apex: significance for genotypic differences in aluminium resistance

Cell-wall (CW) pectin content and its degree of methylation in root apices of selected maize cultivars were studied in relation to genotypic Al resistance. Maize cultivars differing in Al resistance were grown in nutrient solution treated with or without Al, and pectin content of the root tips was determined. Control plants did not differ in pectin content in the 5 mm root apex. Al treatment increased the pectin content of the root apex in all cultivars but more prominently in the Al-sensitive cultivars. Pectin and Al contents in 1 mm root sections decreased from the apex to the 3–4 mm zone. Pectin contents of the apical root sections were consistently higher although significantly different only in the 1–2 mm zone in the Al-sensitive cv Lixis. Al contents in most root sections were significantly higher in cv Lixis than in Al-resistant cv ATP-Y. Localization of pectins by immunofluorescence revealed that Al-sensitive cv. Lixis has a higher proportion of low-methylated pectin and thus a higher negativity of the cell wall than Al-resistant cv ATP-Y. This is in agreement with the higher Al content and Al sensitivity of cv Lixis. It is concluded that differences in CW pectin and its degree of methylation contribute to genotypic differences in Al resistance in maize in addition to the release of organic acid anions previously reported.     

Aluminium effects on mechanical properties of cell wall analogues

Aluminium (Al) toxicity adversely impacts plant productivity in acid soils by restricting root growth and although several mechanisms are involved the physiological basis of decreased root elongation remains unclear. Understanding the primary mechanisms of Al rhizotoxicity is hindered due to the rapid effects of soluble Al on root growth and the close proximity of many cellular components within the cell wall, plasma membrane, cytosol and nucleus with which Al may react. To overcome some of these difficulties, we report on a novel method for investigating Al interactions with Komagataeibacter xylinus bacterial cellulose (BC)‐pectin composites as cell wall analogues. The growth of K. xylinus in the presence of various plant cell wall polysaccharides, such as pectin, has provided a unique in vitro model system with which to investigate the interactions of Al with plant cell wall polysaccharides. The BC‐pectin composites reacted in a similar way with Al as do plant cell walls, providing insights into the effects of Al on the mechanical properties of the BC‐pectin composites as cell wall analogues. Our findings indicated that there were no significant effects of Al (4–160 μM) on the tensile stress, tensile strain or Young's modulus of the composites. This finding was consistent with cellulose, not pectin, being the major load bearing component in BC‐pectin composites, as is also the case in plant cell walls.     

PARVUS affects aluminium sensitivity by modulating the structure of glucuronoxylan in Arabidopsis thaliana

Glucuronoxylan (GX), an important component of hemicellulose in the cell wall, appears to affect aluminium (Al) sensitivity in plants. To investigate the role of GX in cell‐wall‐localized xylan, we examined the Arabidopsis thaliana parvus mutant in detail. This mutant lacks α‐D‐glucuronic acid (GlcA) side chains in GX and has greater resistance to Al stress than wild‐type (WT) plants. The parvus mutant accumulated lower levels of Al in its roots and cell walls than WT despite having cell wall pectin content and pectin methylesterase (PME) activity similar to those of WT. Our results suggest that the altered properties of hemicellulose in the mutant contribute to its decreased Al accumulation. Although we observed almost no differences in hemicellulose content between parvus and WT under control conditions, less Al was retained in parvus hemicellulose than in WT. This observation is consistent with the finding that GlcA substitutions in WT GX, but not mutant GX, were increased under Al stress. Taken together, these results suggest that the modulation of GlcA levels in GX affects Al resistance by influencing the Al binding capacity of the root cell wall in Arabidopsis.     

The role of cell wall components from groundnut roots in solubilizing sparingly soluble phosphorus in low fertility soils

Groundnuts have a superior ability to take up P from soils with low P fertility compared to sorghum and soybean. Previous experiments showed that this ability was neither attributable to better root development nor to root exudates capable of solubilizing Fe- and Al-bound P, the sparingly soluble P forms in soils. Direct "contact reactions" between cell wall components from these 3 plant species (groundnut, soybean and sorghum) and P-fixing Fe and Al minerals were examined. Cell wall preparations from groundnut roots showed a superior P solubilizing ability than those of soybean and sorghum. Cell wall activity of groundnut roots may thus at least partly explain the superior growth of this crop under P-deficient conditions. To characterize the active site responsible for P solubilization, effects of pH, heat, addition of cations, and digestion with enzymes (pectinase and cellulase) or HCl on P solubilization were investigated. Conclusion are 1) Solubilizing ability is not related to root CEC because soybean with higher root CEC showed an inferior solubilizing ability compared to groundnut. 2) The reaction site of cell-walls of groundnut roots is stable against heating and digestion with cellulase and pectinase. 3) Solubilizing ability was severely reduced by digestion with HCl. 4) Pre-treating cell walls with either Al3+, Fe3+, or Ga3+ decreased solubilizing ability but cations with lower valency such as Na+, K+, Ca2+ or Mg2+ had no effect. Soaking roots of groundnuts grown in solution culture in 0.5 M NaOH for 30 seconds prior to cell wall preparation led to a 30% reduction in solubilization of P from FePO4 without permanently damaging plants. This suggests that 5) the active component of the cell walls was located on the root epidermal cell surfaces. Based on these results a phosphorus solubilizing mechanism is proposed.     

Modifications of cell wall pectin in tomato cell suspension in response to cadmium and zinc

Retention of metal cations by the cell wall is a common process found in plants in response to stress induced by the presence of trace metals (TMs). In this study conducted on a tomato cell suspension culture, cadmium (Cd) and zinc (Zn) were added to the medium at maximal concentrations of 0.5 and 2 mM, respectively. We showed that around 50 % of Zn or Cd was confined into the cell wall of tomato cells. Besides, their accumulation in the cell wall increased with the exogenous concentration in the culture medium. Characterization of cell wall pectins showed a decrease in the highly methylesterified pectin fraction whereas the weakly methylesterified pectin remained stable in response to Cd. Moreover, a significant increase in the degree of methylesterification was observed in both fractions. This was probably associated to the reduced pectin methylesterase (PME) activity in the treated cells. Furthermore, linked to a reduction of pectin content we showed a reduced expression of the galacturonosyltransferase QUA1 gene whereas PME1 expression remained unchanged. Taking together, these data strongly suggest that pectin biosynthesis and its modification in the cell wall are strongly regulated in response to TM exposure in tomato cells.     

硅对盐胁迫下枣树组织培养苗细胞壁形成和相关酶活性的影响

盐胁迫（75mmol·L^-1 NaCl）下,枣树微茎段外植体成活率、生根率及枣苗的侧根条数和长度、苗高、单株重量均较对照显著减小;盐胁迫下加硅（Si）（0．75mmol·L^-1 KSiO3）,枣苗的前述指标与对照无显著性差异。盐胁迫下,枣组织培养生根苗细胞壁提取率显著下降,细胞壁中蛋白和低分子量果胶含量显著降低,EDTAU溶性果胶和碱溶性果胶含量显著提高,半纤维素和纤维素含量降低;盐胁迫下加Si,枣苗细胞壁提取率显著提高,细胞壁主要戍分的含量水平与对照相近。与盐胁迫下相比,盐胁迫下加Si,虽然枣苗果胶甲酯酶（PME）和多聚半乳糖醛酸酶（PG）活性升高未达显著性差异水平,但纤维素酶（Cx）活性显著降低,3种水解酶活性的比值均显著增大,细胞壁共价结合态H^＋-ATP酶活性显著升高。结果说明,提高培养基可溶性Si水平,可显著改善受盐胁迫枣苗细胞壁水解酶的活性平衡、组分含量的均衡及细胞壁内外溶质的适应性分配,从而为枣苗较好生长奠定了基础。