Sporopollenin accumulation in <Emphasis Type="Italic">Nicotiana tabacum</Emphasis> L. microspore wall during its development

The paper is addressed to the accumulation of sporopollenin components in the microspore wall, sporopollenin polymerization dynamics and possible participation of reactive oxygen species (ROS) in this process. Fluorescent and transmission electron microscopy (TEM) was used. It has been revealed that phenylpropanoid components of sporopollenin accumulate in the microspore wall at the middle and late tetrad stages. At the late tetrad stage they completely cover the microspore surface and accumulate abundantly in aperture areas. In accordance with this, numerous thick sporopollenin lamellae emerge in aperture areas; the lamellae are electron dense and acetolysis-resistant. The exine in non-aperture areas includes acetolysis-resistant sporopollenin, as well as washout components. These particular parts of the wall are intensively stained with fluorescent dye MitoSOX Red, which detects the presence of ROS. The staining disappeared after the treatment of the microspore with superoxide dismutase, demonstrating the presence of superoxide in the exine. Superoxide easily converts to hydrogen peroxide, which can cause oxidative polymerization of sporopollenin components, forming a chemically stable biopolymer. The obtained data favor the hypothesis of ROS involvement in the formation of sporopollenin.     

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%.     

Periplasmic multilamellar membranous structures in Nicotiana tabacum L. pollen grains treated with Ni2+ or Cu2+

Essential trace elements Ni²⁺ and Cu²⁺ can block pollen germination without causing cell death. Mechanisms of this effect remain unclear. Using TEM, we studied the effects of Ni²⁺ or Cu²⁺ treatment on the ultrastructure of the aperture regions in tobacco pollen preparing to germinate in vitro, since in these zones, the main fluxes of water, ions, and metabolites cross the plasmalemma. Neither Ni²⁺ nor Cu²⁺ altered the cytoplasm ultrastructure, but both affected the reorganization of apertural periplasm during pollen activation. Numerous multilamellar membranous structures continuous with the plasma membrane could be seen in hydrated but not yet activated pollen. When the normal activation was completed, the structures disappeared and the plasmalemma became smooth. In the presence of 1 mM Ni²⁺ or 100 μM Cu²⁺, these structures preserved its original appearance. It is assumed to be the storage form for the membrane material, which is to provide an initial phase of the pollen tube growth. Ni²⁺ and Cu²⁺ affect the utilization of these membranes, thereby, blocking the pollen germination.     

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.     

Changes in soil carbon and nitrogen cycling along a 72-year wildfire chronosequence in Michigan jack pine forests

We investigated the changes in soil processes following wildfire in Michigan jack pine (Pinus banksiana) forests using a chronosequence of 11 wildfire-regenerated stands spanning 72 years. The objective of this study was to characterize patterns of soil nutrients, soil respiration and N mineralization with stand development, as well as to determine the mechanisms driving those patterns. We measured in situ N mineralization and soil respiration monthly during the 2002 growing season and used multiple regression analysis to determine the important factors controlling these processes. Growing-season soil respiration rates ranged from a low of 156 g C/m² in the 7-year-old stand to a high of 254 g C/m² in the 22-year-old stand, but exhibited no clear pattern with stand age. In general, soil respiration rates peaked during the months of July and August when soil temperatures were highest. We used a modified gamma function to model a temporal trend in total N mineralization (total N mineralization = 1.853−0.276 × age × e ^{−0.814 × age}; R ² = 0.381; P = 0.002). Total N mineralization decreased from 2.8 g N/m² in the 1-year-old stand to a minimum value of 0.5 g N/m² in the 14-year-old stand, and then increased to about 1.5 g N/m² in mature stands. Changes in total N mineralization were driven by a transient spike in N turnover in the mineral soil immediately after wildfire, followed by a gradual accrual of a slow-cycling pool of N in surface organic horizons as stands matured. Thus, in Michigan jack pine forests, the accumulation of surface organic matter appears to regulate N availability following stand-replacing wildfire.     

Ion Exchange Properties of the Root Cell Walls Isolated from the Halophyte Plants (Suaeda altissima L.) Grown Under Conditions of Different Salinity

Metal and metalloid resistances in plant species and genotypes/accessions are becoming increasingly better understood at the molecular and physiological level. Much of the recent focus into metal resistances has been on hyperaccumulators as these are excellent systems to study resistances due to their very abnormal metal(loid) physiology and because of their biotechnological potential. Advances into the mechanistic basis of metal(loid) resistances have been made through the investigation of metal(loid) transporters, the construction of mutants with altered metal(loid) transport and metabolism, a better understanding of the genetic basis of resistance and hyperaccumulation and investigations into the role of metal(loid) ion chelators. This review highlights these recent advances.     

Transport of Cl– across the Plasma Membrane during Pollen Grain Germination in Tobacco

The role of Cl- transport across the plasma membrane was studied in an early step of pollen grain germination in tobacco Nicotiana tabacum L. The Cl- channel blockers, 5-nitro-2-(3-phenylpropylamino)benzoic acid (NPPB) and niflumic acid, completely suppress the germination with IC(50) approximately 8 micro M. At this concentration NPPB reduces the rate of Cl- efflux out of pollen grain by 1.8-fold in the interval 5-12 min, and niflumic acid reduces the rate 1.2-fold. 4,4;-Diisothiocyanatostilbene-2,2;-disulfonic acid, a known inhibitor of Cl- channels and antiporters, completely suppresses germination as well (IC(50) = 240 micro M), but has no effect on the rate of Cl- efflux. Inhibitors of chloride co-transporters, such as furosemide, bumetanide, and bis(1,3-dibutylbarbituric acid)pentamethine oxonol, suppress the germination by less than 50%. This set of data suggests that NPPB-sensitive anion channels are involved in the activation of pollen grains in the early stage of germination.     

A new approach to the investigation on the tonogenic groups of root cell walls

Acid-base properties of wheat, lupin, pea root cell walls were investigated. The roots of etiolated and green plants of different age were analysed by the potentiometric method. The ion exchange capacity of root cell walls (S_i) was estimated at various pH values (pH_i 2 to pH_i 12) and constant ion strength of the solution (10 mM). To analyse polysigmoid curves pH_i =f (S_i), Gregor's equation was used. It was shown that Gregor's model fits fairly well the experimental data. The total quantities of cation-exchange (S_t ^cat) and anion-exchange (S_t ^an) groups were determined in the root cell walls. It was shown that the quantity of anion exchange groups is varied through a small range (60–185 μmol/g dry wt.) in plant species tested, and that the S_t ^cat differs widely from 550 to 1300 μmol/g dry wt. For leguininous plants the quantity of acidic groups (fixed anions) is nearly twice as large as that for cereals. It was found that in seedlings as well as in plants, there are 3 cation-exchange groups and one anion-exchange group in root cell walls. The quantity of functional groups of each type (S^j) was estimated, and the corresponding values of n^j and pK_a ^j were calculated. It can be assumed that the groups with the pK_a ¹ ≈ 3.2 are amine groups, the ones with PK_a ² ≈ 5 are groups of galacturonic acid, the ones with pK_a ≈ 7.5 are the carboxyl groups of the second species, and the ones with pK_a ⁴ ≈ 40 are the phenolic groups. The values of dissociation constants (pK_a ^j) and S^j indicate that the root cell walls of wheat, lupin and pea are identical in qualitative structure of ionogenic groups but vary in the quantity of each ionogenic group. It was demonstrated that the summarized quantity of carboxyl groups (S² + S³) should be connected directly with the pH gradient in the extracellar space at the membrane surface. The gradient arises from ion-exchange reactions between cations of an outer medium and protons of the ionized carboxyl groups of the cell walls. The results suggest that, S_t ^cat and S_t ^an allow the quantitative estimation of ion exchange properties of the cell walls. The resulting parameters (S^j, pK_a ^j and n^j) allow prediction of changes in an ionic composition of a medium that bathes the cell membrane, during the first step of mineral nutrition uptake. This revised version was published online in June 2006 with corrections to the Cover Date.     

Membrane potential changes during pollen germination and tube growth

Using methods of quantitative fluorescent microscopy, we studied membrane potential changes during pollen germination and in growing pollen tubes. Two voltage-sensitive dyes were used, i.e., DiBAC₄(3), to determine the mean membrane potential values in pollen grains and isolated protoplasts, and Di-4-ANEPPS, to map the membrane potential distribution on the surfaces of the pollen protoplast and pollen tube. We have shown that the activation of the tobacco pollen grain is accompanied by the hyperpolarization of the vegetative cell plasma membrane by about 8 mV. Lily pollen protoplasts were significantly hyperpolarized (−108 mV) with respect to the pollen grains (−23 mV) from which they were isolated. We have found the polar distribution of the membrane potential along the protoplast surface and the longitudinal potential gradient along the pollen tube. In the presence of plasma membrane H⁺-ATPase inhibitor sodium orthovanadate (1 mM) or its activator fusicoccin (1 μM), the longitudinal voltage gradient was modified, but did not disappear. Anion channel blocker NPPB (40 μM) fully discarded the gradient in pollen tubes. The obtained results indicate the hyperpolarization of the plasma membrane during pollen germination and uneven potential distribution on the pollen grain and tube surfaces. An inhibitory analysis of the distribution of the potential in the tube has revealed the involvement of the plasma membrane H⁺-ATPase and anion channels in the regulation of its value.     

Changes in the hormonal status of the Taraxacum officinale Web. ovary at early stages of embryogenesis

The hormonal status of the Taraxacum officinale Web. ovary was quantitatively assayed for the first time during early stages of embryogenesis. Apparent concentrations of endogenous cytokinins were measured using two systems of enzyme-linked immunosorbent assay (ELISA). The ELISA systems differed from one another by the specificity for the main endogenous forms of zeatin. The specificity of two heterological ELISA systems based on zeatin- and kinetin-specific antisera was studied. A new immunochemical approach to the problem of differential quantitative determination of natural zeatin forms is suggested. This approach does not require preliminary separation of experimental samples into individual fractions. True concentrations of zeatin and zeatin riboside in the T. officinale ovary were calculated based on the average values of apparent concentrations of endogenous cytokinins. When the embryo sac maturation had been completed, there was a threefold increase in the zeatin riboside concentration within the following 12 h. By the time of the first division of an unfertilized ovicell (i.e., within the next 12 h), there had been a twofold decrease in the zeatin riboside concentration. Therefore, at early stages of division of the unfertilized ovicell the zeatin riboside concentration virtually returned to the initial level. In contrast to zeatin riboside, there was a steady trend toward an increase in the zeatin concentration in the T. officinale ovary. Within the first 12 h and the next 12 h after completion of the embryo sac maturation, the zeatin concentration was increased 1.5-fold and 2-fold, respectively. The results of this work provide a pioneering insight into the dynamics of various natural forms of zeatin during the reproductive process. The immunochemical approach to quantitative monitoring of various natural forms of zeatin and their dynamics during embryogenesis suggested in this work can be extended to similar biological, medical, and agricultural problems of differential determination of low-molecular-weight agents of similar structure but different biological activity.