Changes in the composition of ionogenic groups of the wall of the lily pollen grain during germination

Changes in the composition of ionogenic groups of the polymeric matrix of the cell walls of lily (Lilium longiflorum Thunb.) pollen grains were studied during its activation at the early stages of pollen germination. In the cell walls isolated from nonactivated and activated pollen grains, four types of ionogenic groups were identified: amino groups, carboxylic groups of uronic acids, phenolic OH-groups. and groups with pK_a 7–8. During the early stages of germination, ionization constants of each type groups remained unchanged, but the quantitative composition of ionogenic groups in the intine changed. In this matrix, a decrease in the content of phenolic groups and demethylated carboxylic groups of uronic acids was detected. It is supposed that, at early stages of germination, the intine loses some part of acid pectins and some phenolic compounds.     

Chitin-glucan complex in cell walls of the Peltigera aphthosa lichen

Cell walls and chitin-glucan complexes isolated from uneven-aged components of the thallus of the Peltigera aphthosa lichen were studied. The mass fraction of the cell wall and chitin-glucan complexes increased with age, but the content of nitrogen in these structures decreased with age. The basal area of the thallus was characterized by the largest mass fraction of the chitin-glucan complex from the dry mass of the thallus; the apical area, by the largest mass fraction of chitin in the complex. It was demonstrated that in P. aphthosa, the degree of deacetylation of chitin in the complex (depending on the age) was 33 and 54% in the apical and basal areas, respectively. The suggested method of functional analysis of chitin-glucan complexes for the presence of free amino groups in them can be used for studying other lichenified fungi.     

Ion-exchange properties of cell walls of red seaweed <Emphasis Type="Italic">Phyllophora crispa</Emphasis>

Research into ion-exchange properties of cell walls isolated from thallus of red seaweed Phyllophora crispa was carried out. Ion-exchange capacity and the swelling coefficient of the red alga cell walls were estimated at various pH values (from 2 to 12) and at constant ionic strength of a solution (10 mM). It was established that behavior of cell walls as ion-exchangers is caused by the presence in their matrix of two types of cation-exchange groups and amino groups. The amount of the functional group of each type was estimated, and the corresponding values of pK _a were calculated. It can be assumed that ionogenic groups with pK _a ∼5 are carboxyl groups of uronic acids, and ionogenic groups with pK _a ∼7.5 are carboxyl groups of the proteins. Intervals of pH in which cation-exchange groups are ionized and can take part in exchange reactions with cations in the environment are defined. It was found that protein was a major component of cell wall polymeric matrix because its content was 36%.     

Ion-exchange properties of cell walls in chickpea cultivars with different sensitivities to salinity

Ion-exchange properties of polymeric matrices were compared for cell wall preparations isolated from roots and shoots of two cultivars of Cicer arietinum L. (cvs. Bivanij and ILC 482) with different sensitivities to salinity. Irrespective of growth conditions, the cell walls contained four types of ionogenic groups: amino groups, carboxyl groups of uronic and hydroxycinnamic acids, and phenolic hydroxyl groups. Regardless of the salt concentration in the medium, the cells walls of different chickpea cultivars and from different organs of the same plant were similar in qualitative composition of ionogenic groups, although quantities of ionogenic groups per unit dry wt of cell walls varied depending on external and internal factors. Irrespective of the external medium salinity, the cation-exchange capacity of cell walls, expressed per unit dry wt, decreased in a sequence: stem > root ∼ bottom leaves > upper leaves. The volume of chickpea cell walls was found to vary depending on ionic composition and pH of the incubation medium. The results were analyzed in the context of cell wall involvement in responses of C. arietinum to elevated salinity.     

Ion-exchange properties of the cell wall of reindeer lichen <Emphasis Type="Italic">Cladonia rangiferina</Emphasis>

Ion-exchange properties of cell walls were investigated in reindeer lichen Cladonia rangiferina (L.) F. H. Wigg. In order to isolate cell walls, we used living parts of podetia as well as young parts (four upper internodes of podetia) and old parts (from the 4th to the 8th internode). We studied functional dependences of cell wall ion-exchange capacity on pH in the range from 2 to 12 and constant ionic strength of solution equal to 10 mM. It was found that three-dimensional structure of C. rangiferina cell walls comprised three types of ionogenic groups, which determine ion-exchange properties of the cell walls. They are amino groups with pK_a of about 3, carboxyl groups with pK_a of about 7, and phenolic OH-groups with pK_a of about 10. The content of groups of each type and their ionization constants were determined, and it was shown that, in the cell walls of young parts, the content of amino groups and carboxylic groups was greater than in old parts of podetia (by 1.5 and 2.0 times, respectively). It was found that with age the content of nitrogen and the proportion of deacetylated amino groups in the cell walls changed from 34% (young parts of podetia) to 40% (old parts of podetia). It was shown that in C. rangiferina N-acetyl glucosamine and glucosamine are not the main monomers of cell wall polymers because both in thalli and in the cell walls isolated therefrom the content of total nitrogen was less than 1%.     

Ion-Exchange Properties of Cell Walls Isolated from Lupine Roots

Acid–base properties of cell walls isolated from various root tissues of 7-day-old lupine seedlings and 14-day-old lupine plants grown in various media were studied. The ion-exchange capacity of root cell walls was estimated at various pH values (from 2 to 12) and constant ionic strength (10 mM). The parameters determining the qualitative and quantitative composition of cell wall ionogenic groups along the root length and in its radial direction were estimated using Gregor's model. This model fits the experimental data reasonably well. Four types of ionogenic groups were found in the cell walls: an amino group (pK _a 3), two types of carboxylic groups (pK _a 5 and 7.3, the first being the carboxylic group of galacturonic acid), and a phenolic group (pK _a 10). The number of functional groups of each type was estimated, and the corresponding ionization constant values were calculated. It is shown that the chemical composition of the ionogenic groups was constant along the root length as well as in its radial direction and did not depend on either physiological state or root nutrition, while the number of different groups varied. The content of carboxylic groups of -D-polygalacturonic acid in the root cell walls of 14-day-old plants was shown to depend on the distance from the root tip, being maximal in the zone of lateral roots. The number of these groups was 10- and 2-fold less in the central cylinder compared to that of cortex for 14-day-old plants and 7-day-old seedlings, respectively.     

The effect of nitrogen on growth and key thallus components in the two tripartite lichens, Nephroma arcticum and Peltigera aphthosa

Relationships between growth, nitrogen and concentration of unique biont components were investigated for the tripartite lichens Nephroma arcticum (L.) Torss. and Peltigera aphthosa (L.) Willd. Nitrogen availability was manipulated during 4 summer months by removing cephalodia and their associated N₂ fixation activity, or by weekly irrigation with NH₄NO₃. Chlorophyll and ribulose 1·5‐biphosphate carboxylase/oxygenase (Rubisco), and chitin and ergosterol were used as photobiont and mycobiont markers, respectively. Nitrogen concentrations were similar in older and newer parts of the same thallus, varying between 2 and 5 g m^?2, with P. aphthosa having higher concentrations than N. arcticum. Both chlorophyll (Chl a) and chitin were linearly correlated with thallus N, but N. arcticum invested more in fungal biomass and had lower Chl a concentrations in comparison with P. aphthosa at equal thallus N. During the 4 months, control and N‐fertilized thalli of N. arcticum increased in area by 0·2 m² m^?2 and P. aphthosa by 0·4 m² m^?2. Thallus expansion was significantly inhibited in samples without cephalodia, but there was no effect on lichen weight gain. Mean relative growth rate (RGR; mg g^?1 d^?1) was 3·8 for N. arcticum and 8·4 for P. aphthosa, when time (d) reflected the lichen wet periods. RGR was 2–3 times lower when based on the whole time, i.e. when including dry periods. The efficiency (e) of converting incident irradiance into lichen biomass was positively and linearly correlated with thallus Chl a concentration to the same extent in both species. The slower growth rates of N. arcticum, in comparison with P. aphthosa, could then be explained by their lower nitrogen and Chl a concentrations and a subsequently lower light energy conversion efficiency. Functional and dynamic aspects of resource allocation patterns of the two lichens are discussed in relation to the above findings.     

Ion-exchange properties of cell walls of red seaweed Phyllophora crispa

Research into ion-exchange properties of cell walls isolated from thallus of red seaweed Phyllophora crispa was carried out. Ion-exchange capacity and the swelling coefficient of the red alga cell walls were estimated at various pH values (from 2 to 12) and at constant ionic strength of a solution (10 mM). It was established that behavior of cell walls as ion-exchangers is caused by the presence in their matrix of two types of cation-exchange groups and amino groups. The amount of the functional group of each type was estimated, and the corresponding values of pK(a) were calculated. It can be assumed that ionogenic groups with pK(a) -5 are carboxyl groups of uronic acids, and ionogenic groups with pK(a) -7.5 are carboxyl groups of the proteins. Intervals of pH in which cation-exchange groups are ionized and can take part in exchange reactions with cations in the environment are defined. It was found that protein was a major component of cell wall polymeric matrix because its content was 36%.     

Cell wall physicochemical properties determine the thallus biomineralization pattern of Padina gymnospora (Phaeophyceae)

Approximately half of the Padina (Dictyotales, Phaeophyceae) species mineralize aragonite needles over the adaxial thallus surface, where mineral bands are interspersed with nonmineralized regions along the thallus from the apical to basal end. However, this calcification pattern and the related algal properties are not well understood. Therefore, this work was performed to elucidate a potential role of cell walls in the inhibition/induction of mineralization in the brown alga Padina gymnospora. In a comparison of specific thallus regions, differences were identified in the cellulose distribution, microfibrils arrangement and thickness, distribution and abundance of phenolic substances, and physical differences among the surfaces of the thallus (deformation, adhesion, topography, and nano‐rugosity). In vitro mineralization assays indicated that phenolic substances are strong modulators of calcium carbonate crystals growth. In addition, de novo mineralization assays over cell wall surfaces that were used as templates, even without cellular activity, indicated that the cell wall remains a key factor in the induction/inhibition of mineralization. Overall, the current findings indicate a strong correlation between the physico‐chemical and structural properties of the cell wall and the alternation pattern of the mineralization bands over the thallus of P. gymnospora.     

CHEMICAL COMPOSITION AND STRUCTURE OF THE CELL WALLS OF THE CONCHOCELIS AND THALLUS PHASES OF PORPHYRA TENERA (RHODOPHYCEAE)1,2

Purified cell walls were prepared from both the conchocelis and thallus phases of Porphyra tenera (Kjellm.). The nitrogen content of cell walls from the conchocelis was significantly greater than that for the thallus cell walls, being 3.35 ± 0.26% and 2.39± 0.03%, respectively. Amino acid analysis revealed important differences. The conchocelis cell wall hydrolyzates were richer in aspartic acid, glutamic acid, methionine, and basic amino acids. The thallus cell wall hydrolyzates, however, contained much more glycine and alanine than did those of the conchocelis. Hydroxyproline was not detected in cell walls of either phase. The neutral sugar content of cell wall hydrolyzates from the thallus was more than double that from the conchocelis being 83.6% and 34.5%, respectively. The former contained predominantly mannose which accounted for 72.2% of the neutral sugars while the latter was principally galactose (49.9%) and glucose (36.4%). Methylation analysis confirmed the presence of cellulose microfibrils in the conchocelis in contrast to xylan microfibrils in the thallus. The results establish that the conchocelis and thallus phases of P. tenera differ markedly in the structure and composition of the cell walls.     

Degradabflity and phenolic components of cell walls of wheat in relation to susceptibility to Puccinia striiforntis

Cell walls of tips and bases of laminae of flag leaves from 11 cultivars of winter wheat of varying susceptibility to Puccinia striiforntis yellow rust) were compared by examining their phenolic components released by treatment with a commercial cellulase. Isolated cell walls of both susceptible and resistant cultivars released water-soluble carbohydrate esters of phenolic acids, the major acid detected being trans-ferulic. There was no relationship between the amount of phenolic esters released by cellulase and susceptibility to yellow rust. The leaf lamina tips, which were much more susceptible to yellow rust than the corresponding bases, had lower cell wall contents than the bases and their walls were more degradable by cellulase. Examination of transverse sections of leaf laminae of cv. Little Joss showed that cells whose walls contained phenolic groups that gave a red colour reaction with p-nitrobenzene diazonium tetrafluoroborate, occupied a larger area of leaf lamina bases than of the tips. A greater percentage of the abaxial epidermal cells of the bases, compared with the tips, had walls that gave this red colour reaction. We suggest that the presence of phenolic groups in these walls may be related to the greater resistance of the bases to P. striiforntis.     

Features of ionogenic group composition in polymeric matrix of lily pollen wall

The composition of ionogenic groups and ion-exchange capacity were studied in the polymeric matrix of cell walls isolated from the pollen grain and tissues of vegetative organs (leaves and stems) of Lilium longiflorum Thunb. The ion-exchange capacity was evaluated at different pH values and ionic strength of 100 mM. In the two-layered pollen wall and the somatic cell walls four types of ionogenic groups were found: amino groups, two carboxyl groups (represented by residues of uronic and hydroxycinnamic acids), and phenolic OH-groups. The groups of all four types are present in the intine, whereas the exine contains one type of anion-exchange and two types of cation-exchange groups. The contents of each type group and their ionization constants were determined. The qualitative and quantitative compositions of structural polymers of the pollen intine and somatic cell walls are significantly different. It is suggested that hydroxycinnamic acids should be involved in cross-linking of polysaccharide chains in both the intine and somatic cell primary walls, and such cross-links play a crucial role in the structural organization and integrity of the pollen grain wall.     

Spatial organization of the three‐component lichen Peltigera aphthosa in functional terms

The cephalolichen Peltigera aphthosa (L.) Willd. is characterized by lateral heterogeneity, which manifests itself in the presence of three thallus zones, referred to as the apical, basal and medial zone. These zones differ in terms of interaction between lichen bionts and their physiological activity. The apical thallus zone is more efficient in establishing a contact with cyanobacteria, because of a higher lectin content and a larger overall thallus surface area due to the presence of numerous mycobiont hyphae. Cephalodia are formed in this zone. The interaction between the mycobiont and cyanobiont is more intense in the medial zone. However, the establishment of the contact with cyanobacteria in this zone less probable. The spatial distribution of lectins in the thallus was determined. To reveal the differences in photosynthetic activity in three thallus zones, transient analysis of chlorophyll a fluorescence and the assessment of non‐photochemical quenching of excited chlorophyll states were performed. Assimilation of absorbed light energy was more effective in the medial zone. The basal zone was characterized by decreased photosynthetic activity, lichen dissociation and thallus death.     

The characterization of lectins from the thripartite lichen <Emphasis Type="Italic">Peltigera aphthosa</Emphasis> (L.) Willd.

Agglutinin from Pemtigera aphthosa (L.) Willd. was isolated and its characteristics were obtained. It is a glycoprotein lectin with D-galactose specificity. Lectin concentration decreases from the apical parts of the thallus to its basal region. Finer differences in the agglutinating activity of different parts of the thallus reflect physiological differences in certain areas and their role in the functioning of lichen symbiosis.     

The Physiology of the Lichen Peltigera aphthosa, with Special Reference to the Blue-green Phycobiont (Nostoc sp.)

Variations in the morphology and physiology were noted when parts of the Peltigera aphthosa Willd. thallus differing in age were examined. The many small cephalodia on the growing apex of the lichen showed a lower heterocyst frequency (14%) than those on the rest of the thallus (21–22%), which was reflected in the nitrogenase activity. In contrast, highest levels of photosynthesis (¹⁴CO₂ uptake and O₂ evolution) were noted at the growing apex. while respiration rates were fairly stable over the thallus. The water-holding capacity was greatest in the midparts. Cephalodial biomass represented an average of 2.6% of total thallus biomass. while the number and size of these structures varied considerably. A minor part of the total carbon fixation (¹⁴CO₂) and net oxygen evolution (O₂ electrode) was performed by the blue-green phycobiont (Nostoc) in light. A rapid excretion of ammonia from isolated cephalodia was noticed, which together with a comparatively constant C:N ratio throughout the thallus indicated a rapid transport of metabolites facilitated by close physical contact (electron microscopy).     

Composition of cell wall phenolics and polysaccharides of the potential bioenergy crop –Miscanthus

The composition and concentrations of cell wall polysaccharides and phenolic compounds were analyzed in mature stems of several Miscanthus genotypes, in comparison with switchgrass and reed (Arundo donax), and biomass characteristics were correlated with cell wall saccharification efficiency. The highest cellulose content was found in cell walls of M. sinensis‘Grosse Fontaine’ (55%) and in A. donax (47%) and lowest (about 32%) in M. sinensis‘Adagio’. There was little variation in lignin contents across M. sinensis samples (all about 22–24% of cell wall), however, Miscanthus×giganteus (M × g) cell walls contained about 28% lignin, reed – 23% and switchgrass – 26%. The highest ratios of cellulose/lignin and cellulose/xylan were in M. sinensis‘Grosse Fontaine’ across all samples tested. About the same total content of ester‐bound phenolics was found in different Miscanthus genotypes (23–27 μg/mg cell wall), while reed cell walls contained 17 μg/mg cell wall and switchgrass contained a lower amount of ester‐bound phenolics, about 15 μg/mg cell wall. Coumaric acid was a major phenolic compound ester‐bound to cell walls in plants analyzed and the ratio of coumaric acid/ferulic acid varied from 2.1 to 4.3, with the highest ratio being in M × g samples. Concentration of ether‐bound hydroxycinnamic acids varied greatly (about two‐three‐fold) within Miscanthus genotypes and was also the highest in M × g cell walls, but at a concentration lower than ester‐bound hydroxycinnamic acids. We identified four different forms of diferulic acid esters bound to Miscanthus cell walls and their concentration and proportion varied in genotypes analyzed with the 5‐5‐coupled dimer being the predominant type of diferulate in most samples tested. The contents of lignin and ether‐bound phenolics in the cell wall were the major determinants of the biomass degradation caused by enzymatic hydrolysis.     

O-Methylated mannogalactan from the microalga Coccomyxa mucigena, symbiotic partner of the lichenized fungus Peltigera aphthosa

A structural study of the carbohydrates from Coccomyxa mucigena, the symbiotic algal partner of the lichenized fungus Peltigera aphthosa, was carried out. It produced an O-methylated mannogalactan, with a (1 → 6)-linked β-galactopyranose main-chain partially substituted at O-3 by β-Galp, 3-OMe-α-Manp or α-Manp units. There were no similarities with polysaccharides previously found in the lichen thallus of P. aphthosa. Moreover, the influence of lichenization in polysaccharide production by symbiotic microalgae and the nature of the photobiont in carbohydrate production in lichen symbiosis are also discussed.     

不同林龄杉木+闽楠复层林土壤磷形态及微生物功能多样性变化

磷是限制亚热带地区林木生长的关键因素之一,研究土壤微生物群落功能多样性对土壤磷素的影响,对亚热带地区人工林可持续经营具有重要意义。在江西官山林场选取了3种不同林龄杉木+闽楠（4 a、7 a、11 a）复层林为研究对象,测定了土壤全磷、有效磷及无机磷组分含量,采用Biolog-ECO法研究了复层林表土层（0-20 cm）土壤微生物群落对碳源的利用特征,并分析了土壤磷素与土壤微生物功能多样性的关系。结果表明：（1）土壤全磷、有效磷及无机磷组分含量随复层林营建时间延长呈增加趋势;（2）不同林分类型土壤微生物群落功能多样性差异显著。土壤微生物碳源代谢活性（AWCD）以及多样性指数也均随复层林营建时间延长呈增加趋势;多聚物类是杉木纯林土壤微生物利用的主要碳源,7 a复层林对碳水化合物、羧酸和酚酸的利用强度较大,11 a复层林对氨基酸、胺类、多聚物、羧酸和酚酸的利用强度较大,并且11 a复层林土壤微生物群落代谢碳水化合物、氨基酸、羧酸、胺类和酚酸的强度显著高于4 a复层林和杉木纯林,而4 a复层林与杉木纯林土壤微生物群落对不同碳源利用率的差异较小（除多聚物外）。（3）土壤微生物多样性指数、氨基酸类、胺类和酚酸类物质与土壤全磷、有效磷、Al-P和Fe-P含量之间显著正相关,随机森林模型分析表明,氨基酸、胺类和酚酸是不同林分类型土壤微生物利用的主要碳源。因此,杉木纯林转化为复层异龄林更有利于森林土壤磷的储存和供应,土壤微生物群落代谢功能多样性的增大可能是提高复层异龄林土壤磷有效性的关键调控因素。     

Characterization of cell wall properties in needles from Scotch pine trees of various vigor

Ion-exchange properties of needle cell walls were studied on healthy and severely weakened Scotch pine (Pinus sylvestris L.) trees subjected to industrial pollutions with sulfur and heavy metals. Three types of cation-exchange groups were identified: carboxylic groups of polygalacturonic acid, carboxylic groups unrelated to polygalacturonic acid, and phenolic OH-groups. The needles of impaired trees (vigor state IV) differed from needles of healthy plants (vigor state I) by a higher coefficient of cell wall swelling, higher nitrogen content, and lower content of ion-exchanging groups in the cell wall structure. It is supposed that differences in ion-exchange capacity of cell walls could be among the causes for distribution of pine trees into several groups according to their vigor.     

Reiterative production and deformation of cell walls in expanding thallus nets of the lichen ramalina menziesii (Lecanorales,Ascomycetes)

The thallus of the lichen Ramalina menziesii Tayl. is composed of net-like units that develop by diffuse expansion of perforated tissue produced at the net apex. Study of net tissue with transmission electron microscopy reveals that the cortical cells are surrounded by a succession of cell walls alternating with layers of an electron-transparent matrix substance. In the course of thallus growth the cortical cell walls are continually deformed and new ones constructed. The deposition of new walls and matrix layers displaces the older walls centrifugally from the cell. Electron-dense boundaries develop at the interfaces among cells where the remains of the oldest walls are compressed against those of neighboring cells. As new branch cells are inserted through the concentric accumulations, the dense boundaries appear to enclose fascicles of cells, visible in cross section with light microscopy. Cortical organization in Ramalina menziesii is contrasted with that reported in other lichens, and a functional relationship to diffuse growth of the thallus is suggested.