Barley aleurone layer cell protoplasts as a transient expression system

Protoplasts were prepared from barley aleurone layers using Onozuka cellulase digestion and purification through a Percoll gradient. Protoplasts prepared by this procedure had a viability ranging from 60% to 80% during the first two days of culture. They were responsive to gibberellic acid (GA) as measured by the stimulation of -amylase synthesis. The GA stimulation was counteracted by abscisic acid (ABA). In the presence of polyethylene glycol (PEG), the protoplasts took up exogenously added plasmid DNA containing the reporter gene coding for chloramphenicol acetyl transferase (CAT) linked to a 35S promoter from cauliflower mosaic virus (CaMV) or to barley -amylase gene promoters and expressed CAT activity. Therefore, barley aleurone layer protoplasts are suitable for analysis of hormoneresponsive elements in hydrolase genes.     

Characterization of a 46 kda insect chitinase from transgenic tobacco

A 46 kDa Manduca sexta (tobacco hornworm) chitinase was isolated from leaves of transgenic tobacco plants containing a recombinant insect chitinase cDNA, characterized, and tested for insecticidal activity. The enzyme was purified by ammonium sulfate fractionation, Q-Sepharose anion-exchange chromatography and mono-S cation-exchange chromatography. Although the gene for the chitinase encoded the 85 kDa full-length chitinase as previously reported by Kramer et al. [Insect Biochem. Molec. Biol. 23, 691–701 (1993)], the enzyme is produced in tobacco as a 46 kDa protein that is approximately four-fold less active than the 85 kDa chitinase. The N-terminal amino acid sequence of the 46 kDa chitinase is identical to that of the 85 kDa chitinase. The former enzyme is not glycosylated, whereas the latter contains approximately 25% carbohydrate. The pH and temperature optima of the 46 kDa chitinaseare similar to those of the 85 kDa chitinase. The former enzyme is more basic than the latter. The 46 kDa chitinase likely consists of the N-terminal catalytic domain of the 85 kDa chitinase and lacks the C-terminal domain that contains several potential sites for glycosylation. The 46 kDa chitinase is expressed in a number of plant organs, including leaves, flowers, stems and roots. Enzyme levels are higher in leaves and flowers than in stems and roots, and leaves from the middle portion of the plant have more chitinase than leaves from the top and bottom portions. Little or no enzyme is secreted outside of the plant cells because it remains in the intracellular space, even though its transit sequence is processed. When fed at a 2% dietary level, the 46 kDa chitinase caused 100% larval mortality of the merchant grain beetle, Oryzaephilis mercator. The results of this study support the hypothesis that insect chitinase is a biopesticidal protein for insect pests feeding on insect chitinase gene-containing transgenic plants.     

Basic fibroblast growth factor is efficiently released from a cytolsolic storage site through plasma membrane disruptions of endothelial cells.

Cells of gut and skin frequently suffer mechanically-induced plasma membrane disruptions in vivo, and bioactive molecules, including basic fibroblast growth factor (bFGF), could enter and leave cytoplasm through these disruptions. We here provide three lines of evidence that bFGF is released with surprising efficiency through plasma membrane disruptions, resembling those known to occur in vivo, produced by scraping endothelial cells from their culturing substratum. First, 41% of the total of bFGF extractable in 1 M NaCl by freeze-thaw and sonication was released simply by scraping the endothelial cells. Second, relative to release of lactate dehydrogenase, cells wounded by scraping under conditions promoting greater than 60% cell survival released a significantly larger amount (up to twofold more) of growth promoting activity than did cells uniformly killed and irreversibly permeabilized by scraping in the cold or by freezing and thawing. Last, cells that survived membrane disruptions released, and contained, less bFGF on each subsequent wounding, consistent with release of bFGF through transient (i.e., survivable) membrane disruptions. A polyclonal antibody against bFGF completely neutralized the growth promoting activity released by scraping, confirming that bFGF is released through endothelial cell plasma membrane disruptions. Cell fractionation and immunolocalization, including a novel permeabilization technique for electron microscope immunolocalization, demonstrated a cytosolic location of bFGF. We conclude that many characteristics of bFGF--its broad spectrum of producing and target cell types, cytosolic location, efficient release through biologically and pathologically relevant plasma membrane wounds, and its release from cells that survive membrane wounds--make it a strong candidate as a "wound hormone" for rapidly initiating the cell growth required for routine maintenance of tissue integrity and/or repair after injury.     

Properties of Barley Seed Chitinases and Release of Embryo-Associated Isoforms during Early Stages of Imbibition

Barley (Hordeum vulgare L.) seeds contain at least five proteins with chitinase (CH) activity. Two of these (CH1 and CH2) are found primarily in the aleurone and endosperm tissues, and the other three (CH3, CH4, and CH5) are enriched in the embryo. From the bran fraction, three of these CHs (CH1, CH2, and CH3) were purified to apparent homogeneity. These three CHs have apparent molecular masses of 27, 34, and 35 kilodaltons and isoelectric points of 9.3, 9.2, and 8.7, respectively. CH2 and CH3 have amino terminal sequences resembling a portion of the chitin-binding domain of lectins and other plant defense proteins. CH1 lacks this domain. All three CHs exhibit antifungal activity and inhibit the mycelial growth of some species of trichoderma and Fusarium in vitro. During the early period of imbibition by seeds, two of the embryo-associated CHs are selectively released into the surrounding aqueous medium.     

Site-directed mutagenesis and functional analysis of active site acidic amino acid residues D142, D144 and E146 in Manduca sexta (tobacco hornworm) chitinase

Chitinases (EC 3.2.1.14) are glycosyl hydrolases that catalyze the hydrolysis of beta-(1, 4)-glycosidic bonds in chitin, the major structural polysaccharide present in the cuticle and gut peritrophic matrix of insects. Two conserved regions have been identified from amino acid sequence comparisons of family 18 glycosyl hydrolases, which includes Manduca sexta (tobacco hornworm) chitinase as a member. The second of these regions in M. sexta chitinase contains three very highly conserved acidic amino acid residues, D142, D144 and E146, that are probably active site residues. In this study the functional roles of these three residues were investigated using site-directed mutagenesis for their substitutions to other amino acids. Six mutant proteins, D142E, D142N, D144E, D144N, E146D and E146Q, as well as the wild-type enzyme, were produced using a baculovirus-insect cell line expression system. The proteins were purified by anion-exchange chromatography, after which their physical, kinetic and substrate binding properties were determined. Circular dichroism spectra of the mutant proteins were similar to that of the wild-type protein, indicating that the presence of mutations did not change the overall secondary structures. E146 was required for enzymatic activity because mutants E146Q and E146D were devoid of activity. D144E retained most of the enzymatic activity, but D144N lost nearly 90%. There was a shift in the pH optimum from alkaline pH to acidic pH for mutants D142N and D144E with minimal losses of activity relative to the wild-type enzyme. The pH-activity profile for the D142E mutation resembled that of the wild-type enzyme except activity in the neutral and acidic range was lower. All of the mutant proteins bound to chitin. Therefore, none of these acidic residues was essential for substrate binding. The results indicate that E146 probably functions as an acid/base catalyst in the hydrolytic mechanism, as do homologous residues in other glycosyl hydrolases. D144 apparently functions as an electrostatic stabilizer of the positively charged transition state, whereas D142 probably influences the pKa values of D144 and E146.     

Trait plasticity alters the range of possible coexistence conditions in a competition–colonisation trade‐off

Most of the classical theory on species coexistence has been based on species‐level competitive trade‐offs. However, it is becoming apparent that plant species display high levels of trait plasticity. The implications of this plasticity are almost completely unknown for most coexistence theory. Here, we model a competition–colonisation trade‐off and incorporate trait plasticity to evaluate its effects on coexistence. Our simulations show that the classic competition–colonisation trade‐off is highly sensitive to environmental circumstances, and coexistence only occurs in narrow ranges of conditions. The inclusion of plasticity, which allows shifts in competitive hierarchies across the landscape, leads to coexistence across a much broader range of competitive and environmental conditions including disturbance levels, the magnitude of competitive differences between species, and landscape spatial patterning. Plasticity also increases the number of species that persist in simulations of multispecies assemblages. Plasticity may generally increase the robustness of coexistence mechanisms and be an important component of scaling coexistence theory to higher diversity communities.     

Retroactive Maintains Cuticle Integrity by Promoting the Trafficking of Knickkopf into the Procuticle of Tribolium castaneum

Molting, or the replacement of the old exoskeleton with a new cuticle, is a complex developmental process that all insects must undergo to allow unhindered growth and development. Prior to each molt, the developing new cuticle must resist the actions of potent chitinolytic enzymes that degrade the overlying old cuticle. We recently disproved the classical dogma that a physical barrier prevents chitinases from accessing the new cuticle and showed that the chitin-binding protein Knickkopf (Knk) protects the new cuticle from degradation. Here we demonstrate that, in Tribolium castaneum, the protein Retroactive (TcRtv) is an essential mediator of this protective effect of Knk. TcRtv localizes within epidermal cells and specifically confers protection to the new cuticle against chitinases by facilitating the trafficking of TcKnk into the procuticle. Down-regulation of TcRtv resulted in entrapment of TcKnk within the epidermal cells and caused molting defects and lethality in all stages of insect growth, consistent with the loss of TcKnk function. Given the ubiquity of Rtv and Knk orthologs in arthropods, we propose that this mechanism of new cuticle protection is conserved throughout the phylum.     

Short-term succession of marine microbial fouling communities and the identification of primary and secondary colonizers

Microbial succession during the initial stages of marine biofouling has been rarely studied, especially in the Arabian Gulf. This study was undertaken to follow temporal shifts in biofouling communities in order to identify primary and secondary colonizers. Quantitative analysis revealed a significant increase in total biomass, coverage of macrofoulers, chlorophyll a concentrations, and bacterial counts with time. The relative abundance of the adnate diatoms increased with time, whereas it decreased in the case of the plocon diatoms. Non-metric multidimensional scaling (NMDS) ordination based on MiSeq data placed the bacterial communities in three distinct clusters, depending on the time of sampling. While the relative abundance of Alphaproteobacteria and Flavobacteriia decreased with time, suggesting their role as primary colonizers, the relative abundance of Actinobacteria and Planctomycetia increased with time, suggesting their role as secondary colonizers. Biofouling is a dynamic process that involves temporal quantitative and qualitative shifts in the micro- and macrofouling communities.