Induction of Near-vessellessness in Ephedra campylopoda C. A. Mey.

Near-vessellessness was induced in the secondary xylem of Ephedracampylopoda C. A. Mey. by mechanical bark blocking or by wounding.Both treatments resulted in regions of near-vesselless xylem.Xylem formed after the mechanical bark blocking also had regionsin which the orientation of the axial components was changedfrom axial to lateral. Since either mechanical arrest of phloemand cambial transport or wounding of the cambium almost stoppeddifferentiation into vessels, and instead induced differentiationinto tracheids, it seems that the developmental signal for tracheiddifferentiation is not the same as that for vessels. The possibleregulation of near-vessellessness in Ephedra is discussed.Copyright1994, 1999 Academic Press Differentiation, Ephedra campylopoda, near-vessellessness, wood formation, xylem     

Mean-field model of immobilized enzymes embedded in a grafted polymer layer

Two-dimensional mean-field lattice theory is used to model immobilization and stabilization of an enzyme on a hydrophobic surface using grafted polymers. Although the enzyme affords biofunctionality, the grafted polymers stabilize the enzyme and impart biocompatibility. The protein is modeled as a compact hydrophobic-polar polymer, designed to have a specific bulk conformation reproducing the catalytic cleft of natural enzymes. Three scenarios are modeled that have medical or industrial importance: 1), It is shown that short hydrophilic grafted polymers, such as polyethylene glycol, which are often used to provide biocompatibility, can also serve to protect a surface-immobilized enzyme from adsorption and denaturation on a hydrophobic surface. 2), Screening of the enzyme from the surface and nonspecific interactions with biomaterial in bulk solution requires a grafted layer composed of short hydrophilic polymers and long triblock copolymers. 3), Hydrophilic polymers grafted on a hydrophobic surface in contact with an organic solvent form a dense hydrophilic nanoenvironment near the surface that effectively shields and stabilizes the enzyme against both surface and solvent.     

Potential defence from herbivory by ‘dazzle effects’ and ‘trickery coloration’ of leaf variegation

The very conspicuous dazzle coloration invented for naval defence during World War I was used in pre‐radar days to mislead attackers of naval units about vessel size, type, speed, and direction. Among several potential types of defences, it is proposed that zebra‐like white leaf variegation may defend leaves and other plant organs from herbivory as a result of dazzle effects. Two different dazzle effects may be involved in defending plants from herbivory, making it hard for herbivores (1) to decide where, in a three‐dimensional space, to bite the leaves (large herbivores) and (2) to land on them (insects). In addition, the related types of leaf coloration described in the present study, comprising parallels of military defensive trickery naval painting, may also deceive herbivores about the actual shape, location, and identity of leaves. Some of these visual defences may operate at the same time as other visual defences, such as aposematism, or serve various physiological functions. © 2014 The Linnean Society of London, Biological Journal of the Linnean Society, 2014, 111 , 692–697.     

Plant biological warfare: thorns inject pathogenic bacteria into herbivores

Thorns, spines and prickles are among the rich arsenal of antiherbivore defence mechanisms that plants have evolved. Many of these thorns are aposematic, that is, marked by various types of warning coloration. This coloration was recently proposed to deter large herbivores. Yet, the mechanical defence provided by thorns against large herbivores might be only the tip of the iceberg in a much more complicated story. Here we present evidence that thorns harbour an array of pathogenic bacteria that are much more dangerous to herbivores than the painful mechanical wounding by the thorns. Pathogenic bacteria like Clostridium perfringens, the causative agent of the life-threatening gas gangrene, and others, were isolated and identified from date palm (with green-yellow-black aposematic spines) and common hawthorn (with red aposematic thorns). These thorn-inhabiting bacteria have a considerable potential role in antiherbivory, and may have uniquely contributed to the common evolution of aposematism (warning coloration) in thorny plants.     

A brief review of coarse-grained and other computational studies of molecularly imprinted polymers

Molecular imprinting is an established method for the creation of artificial recognition sites in synthetic materials through polymerization and cross-linking in the presence of template molecules. Removal of the templates leaves cavities that are complementary to the template molecules in size, shape, and functionality. In recent years, various theoretical and computational models have been developed as tools to aid in the design of molecularly imprinted polymers (MIPs) or to provide insight into the features that determine MIP performance. These studies can be grouped into two general approaches-screening for possible functional monomers for particular templates and macromolecular models focusing on the structural characterization of the imprinted material. In this review, we pay special attention to coarse-grained models that characterize the functional heterogeneity in imprinted pores, but also cover recent advances in atomistic and first principle studies. We offer a critical assessment of the potential impact of the various models towards improving the state-of-the-art of molecular imprinting.     

The Potential Anti-Herbivory Role of Microorganisms on Plant Thorns

Thorns, spines and prickles are some of the anti-herbivore defenses that plants have evolved. They were recently found to be commonly aposematic (warning coloration). However, the physical anti-herbivore defense executed by these sharp structures seems to be only the tip of the iceberg. We show that thorns of various plant species commonly harbor an array of aerobic and anaerobic pathogenic bacteria including Clostridium perfringens the causative agent of the life-threatening gas gangrene, Bacillus anthracis, and Pantoea agglomerans. Septic inflammation caused by plant thorn injury can result not only from bacteria. Medical literature indicates that thorns, spines or prickles also introduce pathogenic fungi into animals or humans. Dermatophytes that cause subcutaneous mycoses are unable to penetrate the skin and must be introduced into the subcutaneous tissue by a puncture wound. The common microorganism-thorn combinations seem to have been an important contributor to the fact that so many plant thorns are aposematically colored, as a case of convergent evolution of aposematism in these organisms.Key Words: aposematism, herbivory, pathogen, spine, thorn, bacillus anthracis, clostridium perfringens, sporotrichosis, Mycetoma, subcutaneous mycotic disease     

The Relation between α-Helical Conformation and Amyloidogenicity

Amyloid fibrils are stable aggregates of misfolded proteins and polypeptides that are insoluble and resistant to protease activity. Abnormal formation of amyloid fibrils in vivo may lead to neurodegenerative disorders and other systemic amyloidosis, such as Alzheimer’s, Parkinson’s, and atherosclerosis. Because of their clinical importance, amyloids are under intense scientific research. It is believed that short polypeptide segments within proteins are responsible for the transformation of correctly folded proteins into parts of larger amyloid fibrils and that this transition is modulated by environmental factors, such as pH, salt concentration, interaction with the cell membrane, and interaction with metal ions. Most studies on amyloids focus on the amyloidogenic sequences. The focus of this study is on the structure of the amyloidogenic α-helical segments because the α-helical secondary structure has been recognized to be a key player in different stages of the amyloidogenesis process. We have previously shown that the α-helical conformation may be expressed by two parameters (θ and ρ) that form orthogonal coordinates based on the Ramachandran dihedrals (φ and ψ) and provide an illuminating interpretation of the α-helical conformation. By performing statistical analysis on α-helical conformations found in the Protein Data Bank, an apparent relation between α-helical conformation, as expressed by θ and ρ, and amyloidogenicity is revealed. Remarkably, random amino acid sequences, whose helical structures were obtained from the most probable dihedral angles, revealed the same dependency of amyloidogenicity, suggesting the importance of α-helical structure as opposed to sequence.     

Plant coloration undermines herbivorous insect camouflage

The main point of our hypothesis "coloration undermines camouflage" is that many color patterns in plants undermine the camouflage of invertebrate herbivores, especially insects, thus exposing them to predation and causing them to avoid plant organs with unsuitable coloration, to the benefit of the plants. This is a common case of "the enemy of my enemy is my friend" and a visual parallel of the chemical signals that plants emit to call wasps when attacked by caterpillars. Moreover, this is also a common natural version of the well-known case of industrial melanism, which illustrates the great importance of plant-based camouflage for herbivorous insects and can serve as an independent test for our hypothesis. We claim that the enormous variations in coloration of leaves, petioles and stems as well as of flowers and fruits undermine the camouflage of invertebrate herbivores, especially insects. We assume that the same principle might operate in certain animal-parasite interactions. Our hypothesis, however, does not contrast or exclude other previous or future explanations of specific types of plant coloration. Traits such as coloration that have more than one type of benefit may be selected for by several agents and evolve more rapidly than ones with a single type of advantage.