Hfe deficiency impairs pulmonary neutrophil recruitment in response to inflammation

Regulation of iron homeostasis and the inflammatory response are tightly linked to protect the host from infection. Here we investigate how imbalanced systemic iron homeostasis in a murine disease model of hereditary hemochromatosis (Hfe(-/-) mice) affects the inflammatory responses of the lung. We induced acute pulmonary inflammation in Hfe(-/-) and wild-type mice by intratracheal instillation of 20 μg of lipopolysaccharide (LPS) and analyzed local and systemic inflammatory responses and iron-related parameters. We show that in Hfe(-/-) mice neutrophil recruitment to the bronchoalveolar space is attenuated compared to wild-type mice although circulating neutrophil numbers in the bloodstream were elevated to similar levels in Hfe(-/-) and wild-type mice. The underlying molecular mechanisms are likely multifactorial and include elevated systemic iron levels, alveolar macrophage iron deficiency and/or hitherto unexplored functions of Hfe in resident pulmonary cell types. As a consequence, pulmonary cytokine expression is out of balance and neutrophils fail to be recruited efficiently to the bronchoalveolar compartment, a process required to protect the host from infections. In conclusion, our findings suggest a novel role for Hfe and/or imbalanced iron homeostasis in the regulation of the inflammatory response in the lung and hereditary hemochromatosis.     

Studies on microbial antagonism in rhizosphere soils of potato varieties differentially susceptible to black-scurf and wilt

Summary The antagonistic microflora in the rhizosphere of plants of three varieties of potato, viz. Ps 194' Up to date, and a local variety of different ages were analysed. Antagonists were selected either by random isolation or by Wilska's spraying technique. The antagonists were always found in higher frequency in rhizosphere compared with the control soil. The highest percentage of actinomycetes antagonists were found in the variety Up to date; of fungal antagonists in the variety Ps 194; while the local variety was found to be the poorest in this regard. Further, the antagonistic activity of these organisms was estimated by a cross-streak method and the resistant antagonists were also selected by cross-antagonism. The most resistant antagonists found were Trichoderma viride T 56 and T 7, Chaetomium trilaterate F 75, Streptomyces alboflavus Rs 40, Streptomyces sp. Cs 73, Pseudomonas sp. Rs 1 50 and Pseudomonas sp III Ps 63.     

Correction of the CF defect by curcumin: hypes and disappointments

Cystic fibrosis (CF), the most-common lethal hereditary disease in the white population, is caused by mutations in the cystic fibrosis transmembrane conductance regulator (CFTR) gene. The mutation that is most frequently responsible for the disease, DeltaF508, causes misfolding and retention of the CFTR protein in the endoplasmic reticulum. This leads to a series of cellular dysfunctions and results in a multi-organ disease. In a recent report, Egan et al.(1) demonstrated that curcumin, a non-toxic natural product and major constituent of turmeric spice, corrected the CF defects in DeltaF508 CF mice. This paper aroused a lot of attention and hopes were raised that curcumin might produce similar effects in human, giving an efficient treatment for most CF patients. However, skepticism is growing since subsequent studies fail to reproduce these initial exciting results. Thus, although herbal medicines and dietary supplements can be desirable alternatives to classical pharmacological compounds, their efficacy needs careful evaluation both in vivo and ex vivo.     

X-ray, neutron and NMR studies of the catalytic mechanism of aspartic proteinases

Current proposals for the catalytic mechanism of aspartic proteinases are largely based on X-ray structures of bound oligopeptide inhibitors possessing non-hydrolysable analogues of the scissile peptide bond. Until recent years, the positions of protons on the catalytic aspartates and the ligand in these complexes had not been determined with certainty due to the inadequate resolution of these analyses. There has been much interest in locating the catalytic protons at the active site of aspartic proteinases since this has major implications for detailed understanding of the mechanism of action and the design of improved transition state mimics for therapeutic applications. In this review we discuss the results of studies which have shed light on the locations of protons at the catalytic centre. The first direct determination of the proton positions stemmed from neutron diffraction data collected from crystals of the fungal aspartic proteinase endothiapepsin bound to a transition state analogue (H261). The neutron structure of the complex at a resolution of 2.1 A provided evidence that Asp 215 is protonated and that Asp 32 is the negatively charged residue in the transition state complex. Atomic resolution X-ray studies of inhibitor complexes have corroborated this finding. A similar study of the native enzyme established that it, unexpectedly, has a dipeptide bound at the catalytic site which is consistent with classical reports of inhibition by short peptides and the ability of pepsins to catalyse transpeptidation reactions. Studies by NMR have confirmed the findings of low-barrier and single-well hydrogen bonds in the complexes with transition state analogues.     

Shoot apex explants for induction of somatic embryogenesis in mature Quercus robur L. trees

A procedure for inducing somatic embryos in shoot apex explants (2 mm) excised from shoot proliferation cultures established from adult oak trees (Quercus robur) was investigated. Embryogenesis was induced in shoot tip as well as leaf explants in three out of the five genotypes evaluated. Somatic embryos were formed by culture in induction medium supplemented with 21.48 μM naphthalene acetic acid and 2.22 μM benzyladenine for 8 weeks, and successive transfer of explants to expression media with a low concentration of growth regulators and without them. Both types of explants formed callus tissue from which somatic embryos developed, indicating indirect embryogenesis. Although the embryogenic frequencies were lower than 12%, it did not prevent the establishment of clonal embryogenic lines maintained by repetitive embryogenesis. Histological study confirmed an indirect somatic embryogenesis process from shoot tip explants, in which leaf primordia and the corresponding axial zones were involved in generating callus, whereas the apical meristem itself did not proliferate. The origin of embryogenic cells appeared to be associated with dedifferentiation of certain parenchymal cells in callus regions after transfer of explants to expression media without auxin. Division of embryogenic cells gave rise to proembryo aggregates of unicellular origin, although a multicellular origin from bulging embryogenic areas would also seem possible. Further development led to the formation of cotyledonary-stage somatic embryos and nodular embryogenic structures that may be considered as anomalous embryos with no clear bipolarity. Inducement of somatic embryos from explants isolated from shoot cultures ensures plant material all year round, thus providing a significant advantage over the use of leaf explants from field-grown trees.     

Role of Secondary Metabolites and Brassinosteroids in Plant Defense Against Environmental Stresses

Being sessile, plants are subjected to a diverse array of environmental stresses during their life span. Exposure of plants to environmental stresses results in the generation of reactive oxygen species (ROS). These activated oxygen species tend to oxidize various cellular biomolecules like proteins, nucleic acids, and lipids, a process that challenges the core existence of the cell. To prevent the accumulation of these ROS and to sustain their own survival, plants have developed an intricate antioxidative defence system. The antioxidative defence system comprises various enzymatic and nonenzymatic molecules, produced to counter the adverse effect of environmental stresses. A sizable number of these molecules belong to the category of compounds called secondary metabolites. Secondary metabolites are organic compounds that are not directly involved in the growth and development of plants but perform specialized functions under a given set of conditions. Absence of secondary metabolites results in long-term impairment of the plant’s survivability. Such compounds generally include pigments, phenolics, and so on. Plant phenolic compounds such as flavonoids and lignin precursors have been reported to accumulate in response to various biotic and abiotic stresses and are regarded as crucial defence compounds that can scavenge harmful ROS. Another important category of plant metabolites, called brassinosteroids, exhibit stress regulatory and growth-promoting activity and are classified as phytohormones. Elucidation of the physiological and molecular effects of secondary metabolites and brassinosteroids have catapulted them as highly promising and environment-friendly natural substances, suitable for wider application in plant protection and crop yield promotion. The present review focuses on our current understanding of how plants respond to the generation of excessive ROS and the role of secondary metabolites and brassinosteroids in countering the adverse effects of environmental stresses.     

The positive effect of arabinogalactan on induction of somatic embryogenesis in Quercus bicolor followed by embryo maturation and plant regeneration

This is the first report on the successful induction of somatic embryogenesis in swamp white oak from leaf and shoot apex explants excised from in vitro shoot cultures derived from 6- to 7-year-old trees. We demonstrated that arabinogalactan from larch wood (2–4 mg/L) promoted embryogenesis in the three genotypes evaluated by increasing the frequency of somatic embryogenesis, the embryogenic sites per explant, and by speeding the onset of embryo initiation. The explants were cultured sequentially on three culture media consisting of Murashige and Skoog (MS) salts and vitamins supplemented with 500 mg/L casein hydrolysate and different concentrations of α-naphthaleneacetic acid (NAA) and 6-benzylaminopurine (BA). Somatic embryogenesis induction frequencies of up to 12.4, 4.5, and 0.7 % were obtained for the three genotypes. Clonal embryogenic lines were maintained by repetitive embryogenesis following culture on MS medium containing 0.44 μM BA with or without 0.27 μM NAA. Before germination, cotyledonary-stage embryos were cultured for 4 weeks in maturation medium (MS medium with half-strength macronutrients) containing 6 % sorbitol. Germination response was significantly improved by applying a 2-month cold storage as a post-maturation treatment. The mineral formulation and plant growth regulator content of the germination medium influenced the frequency of plantlet conversion with the best results achieved on Gresshoff and Doy medium with BA (0.25–0.44 μM). This procedure resulted in over 50–60 % of germinating embryos exhibiting continuous root growth and either epicotyl elongation or shoot development.     

Shoot regeneration from in vitro-derived leaf and root explants of <Emphasis Type="Italic">Centaurea ultreiae</Emphasis>

In vitro culture is currently used to produce plant material for ex situ conservation of endangered species. In this study, an efficient protocol for shoot regeneration from leaves and roots was developed for Centaurea ultreiae, a critically endangered species. Organogenesis from leaf and root explants was promoted by incubating these explants on half-strength Murashige and Skoog (MS) medium in the presence of one of four different cytokinins [6-benzyladenine (BA), zeatin, kinetin or N⁶-(2-isopentenyl) adenine (2iP)], each provided at five different levels. Shoot organogenesis was induced in both explants. The best response, 90% of leaf explants producing a mean of 2.48 shoots per explants and 94.3% of root explants producing a mean of 5.60 viable shoots per explants, was observed when explants were incubated on a medium containing 0.55 μM BA. Histological studies revealed connectivity between vascular tissues of regenerated shoots and cambial cells of leaf explants. Moreover, adventitious shoots were derived from pericycle cells of root explants and parenchymatic cells of callus tissues.     

Coordination of kinase and phosphatase activities by Lem4 enables nuclear envelope reassembly during mitosis

Mitosis in metazoa requires nuclear envelope (NE) disassembly and reassembly. NE disassembly is driven by multiple phosphorylation events. Mitotic phosphorylation of the protein BAF reduces its affinity for chromatin and the LEM family of inner nuclear membrane proteins; loss of this BAF-mediated chromatin-NE link contributes to NE disassembly. BAF must reassociate with chromatin and LEM proteins at mitotic exit to reform the NE; however, how its dephosphorylation is regulated is unknown. Here, we show that the C. elegans protein LEM-4L and its human ortholog Lem4 (also called ANKLE2) are both required for BAF dephosphorylation. They act in part by inhibiting BAF's mitotic kinase, VRK-1, in vivo and in vitro. In addition, Lem4/LEM-4L interacts with PP2A and is required for it to dephosphorylate BAF during mitotic exit. By coordinating VRK-1- and PP2A-mediated signaling on BAF, Lem4/LEM-4L controls postmitotic NE formation in a function conserved from worms to humans.