Immunocytochemical localization of water-soluble glycoproteins, including Group 1 allergen, in pollen of ryegrass,Lolium perenne, using ferritin-labelled antibody

Summary The cellular sites of the glycoproteins Group 1 allergen (glycoprotein 1) and Antigen A (glycoprotein 2) in mature ryegrass pollen have been investigated by immunoelectron microscopy. Radioimmunoassays confirm previous findings of cross-reactivity between the purified glycoprotein antigens at the high immunoglobulin G (IgG) concentrations used for localization.Freeze-drying of anthers followed by anhydrous processing has been employed because of the water solubility and mobility of the glycoproteins. A double-embedding technique has been developed. This involves, first, embedding anthers in the water-soluble plastic resin JB-4, sectioning and incubating in ferritin-labelled antisera by the indirect method. The sections are then embedded in Spurr's resin for ultra-thin sectioning. Both glycoproteins are found in the following sites: (1) exine and intine wall layers; (2) pollen cytoplasm; (3) the orbicules and anther loculus; and (4) the anther cuticle. In the exine arcades and surface and in the anther loculus, the ferritin label is bound to pollenkitt. The finding that the glycoproteins are in similar sites is predictable in view of the cross-specificity of the antisera. The extent of antibody penetration of the plastic sections has been examined; labelling is confined to cut grains and absent from intact grains.     

Vegetation demographics in Earth System Models: A review of progress and priorities

Numerous current efforts seek to improve the representation of ecosystem ecology and vegetation demographic processes within Earth System Models (ESMs). These developments are widely viewed as an important step in developing greater realism in predictions of future ecosystem states and fluxes. Increased realism, however, leads to increased model complexity, with new features raising a suite of ecological questions that require empirical constraints. Here, we review the developments that permit the representation of plant demographics in ESMs, and identify issues raised by these developments that highlight important gaps in ecological understanding. These issues inevitably translate into uncertainty in model projections but also allow models to be applied to new processes and questions concerning the dynamics of real‐world ecosystems. We argue that stronger and more innovative connections to data, across the range of scales considered, are required to address these gaps in understanding. The development of first‐generation land surface models as a unifying framework for ecophysiological understanding stimulated much research into plant physiological traits and gas exchange. Constraining predictions at ecologically relevant spatial and temporal scales will require a similar investment of effort and intensified inter‐disciplinary communication.     

Resource density regulates the foraging investment in higher termite species

1. Resource density can regulate the area that animals use. At low resource density, there is a conflict in terms of balance between costs of foraging and benefits acquired. The foraging of the higher termite Nasutitermes aff. coxipoensis consists of searching throughout trails and a building galleries phase. 2. In this study, a manipulative field experiment was used to test the hypothesis that colonies of N. aff. coxipoensis forage towards a more profitable balance between the establishment of trails and gallery construction at low resource density. 3. The experiment was conducted in north‐eastern Brazil. Seven experimental plots were established with a continuous increase in resource density (sugarcane baits). Entire colonies of N. aff. coxipoensis were transplanted from their original sites to the experimental plot, totalling 35 nests. The number, branches and total length of trails and galleries were quantified. 4. The results show that N. aff. coxipoensis optimises its foraging output, intensifying the establishment of trails at the cost of gallery construction when resource density is low. The number of trails, the number of trail branches and the total length of trails decreased with increasing resource density. Interestingly, at low resource density, the search effort was concentrated on forming longer and a greater number of trails, a small proportion of which were converted into galleries. The opposite relationship was observed at high resource density. 5. These results suggest an optimisation of search efforts during foraging depending on resource density, a mechanism that may help researchers to understand the use of space by higher termite species.     

β-Galactosidases of Lilium pollen

Lily (Lilium auratum) pollen contains very high levels of β-galactosidase. There are three forms: β-galactosidase I and II differ in M_r, while β-galactosidase III is firmly bound in the pollen wall. The two cytoplasmic forms were separated and partially purified using a combination of chromatography on DEAE-cellulose, Sephadex G-200 and Sepharose 6B. Forms I and II appear to be glycoprotein in nature as shown by binding to Con A-Sepharose. The three enzymes were optimally active near pH 4, and all were inhibited by galactose and galactonolactone. The wall-bound enzyme, β-galactosidase III effectively hydrolysed nitrophenyl β-galactosidase but not lactose, and could not be released from the wall polysaccharide matrix by high salt concentrations or detergents. The total β-galactosidase activity of lily pollen remained constant during in vitro germination. A possible role for this enzyme may be in degradation of stylar arabinogalactans providing a carbon source for pollen tube nutrition.     

ANT INHIBITION OF POLLEN FUNCTION: A POSSIBLE REASON WHY ANT POLLINATION IS RARE

Ant pollination systems are remarkably rare. We show that pollen exposed to ants for brief periods exhibits reduced viability, reduced percent germination, and shorter pollen tubes relative to control pollen. Pollination with ant-borne pollen also results in lower seed-set than pollination with untreated pollen. This disruption of pollination processes must have exerted a powerful selection pressure against the evolution ofant-pollination systems. It is suggested that the nestbuilding and brood-rearing habits of ants require that they secrete large amounts of antibiotics to combat pathogenic microorganisms. It is these secretions that disrupt pollen function. Bees and wasps exhibit very different nesting behavior, consequently there are no chemical barriers to their coevolving with flowers as pollinators.