Genetic transformation of Trichosporon cutaneum with a plasmid, pAN 7–1, from filamentous fungi

Genetic transformation of a biological oxygen demand (BOD)-sensing yeast, Trichosporon cutaneum IFO 10466 was carried out using a plasmid shuttle vector, pAN 7–1, between Escherichia coli and Aspergillus niger and Aspergillus nidulans. The hygromycin B-resistant transformants were obtained with the plasmid by using the spheroplasts. The transformation frequency was up to 70 colonies per g of plasmid DNA. Southern-blot analysis and transformation test of E. coli using DNA extracts from hygromycin B-resistant transformants of IFO 10466 indicated that pAN 7–1 existed independently in the cells without integration into the chromosome. These results suggest that pAN 7–1 has potential availability for introduction and expression of the external gene such as a bioluminescence gene, lux or luc, to create a luminous yeast for BOD sensing. © Rapid Science Ltd. 1998     

MtrAB–LpqB: a conserved three-component system in actinobacteria?

Streptomyces coelicolor is the model organism for the actinobacteria, a group of high-GC Gram-positive bacteria with members that are notable both for their industrial importance as antibiotic producers and for their pathogenicity. The S. coelicolor genome encodes a subgroup of sensor kinases that is genetically linked to lipoprotein genes, at least one of which functions as an accessory protein to its co-translated kinase. Another member of this subgroup, MtrB, is widely conserved in the actinobacteria, along with its presumed cognate response regulator MtrA and the lipoprotein LpqB. Here, we postulate a possible role for LpqB in the MtrAB signal transduction pathway. We discuss what is known about this pathway in the actinobacteria and offer insights into why an essential response regulator does not necessarily need its cognate sensor kinase for activation.     

Fluorescent vital staining of plant sexual cell nuclei with DNA—specific fluorochromes and its application in gametoplast fusion

DNA－binding fluorochromes are often used for vital staining of plant cell nuclei.However,it is not always sure whether the cells after staining still remain in living state.We chose several criteria to estimate the validity of real vital staining for sexual cell nuclei.These were:the cytoplasmic streaming in pollen tubes whose nuclei were stined,the simultaneous visualization of fluorochromatic reaction and nucleus staining in isolated generative cells,and the capability of isolated.prestained generative or sperm cells to fuse with other protoplasts.The results confirmed that 4,6-diamidino-2-phenylindole(DAPI),Hoechst 33258 and mithramycin could be used as real vital stains,though their efficiency varied from case to case;among them DAPI showed best effect.The fluo rescent vital staining technique offered a useful means foridentification and selection of heterokaryons in gametoplast manipulation studies.     

Tethering,evagination, and vesiculation via cell–cell interactions in microvascular flow

Biomechanics and Modeling in Mechanobiology - Vesiculation is a ubiquitous process undergone by most cell types and serves a variety of vital cell functions; vesiculation from erythrocytes, in...     

Mitochondrial,but not peroxisomal, β-oxidation of fatty acids is conserved in coenzyme A-Deficient rat liver

Growth hormone (GH) exerts acute insulin-like effects, such as increased lipogenesis and inhibition of catecholamine-induced lipolysis, in rat adipocytes that have not been exposed to GH during the preceding three hours. We found that OPC3911, a highly specific inhibitor of the cGMP-inhibited cAMP phosphodiesterase, completely blocked the antilipolytic but not the lipogenic effect of GH. This indicates that the antilipolytic effect of GH is mediated through activation of this phosphodiesterase leading to reduction of cAMP levels in the same manner as has been shown for insulin.     

Syncytia in plants: cell fusion in endosperm—placental syncytium formation in Utricularia (Lentibulariaceae)

The syncytium formed by Utricularia is extremely unusual and perhaps unique among angiosperm syncytia. All typical plant syncytia (articulated laticifers, amoeboid tapetum, the nucellar plasmodium of river weeds) are formed only by fusion of sporophytic cells which possess the same genetic material, unlike Utricularia in which the syncytium possesses nuclei from two different sources: cells of maternal sporophytic nutritive tissue and endosperm haustorium (both maternal and paternal genetic material). How is this kind of syncytium formed and organized and is it similar to other plant syncytial structures? We used light and electron microscopy to reconstruct the step-by-step development of the Utricularia syncytia. The syncytia of Utricularia developed through heterotypic cell fusion involving the digestion of the cell wall, and finally, heterokaryotic multinucleate structures were formed, which possessed different-sized nuclei that were not regularly arranged in the cytoplasm. We showed that these syncytia were characterized by hypertrophy of nuclei, abundant endoplasmic reticulum and organelles, and the occurrence of wall ingrowths. All these characters testify to high activity and may confirm the nutritive and transport functions of the syncytium for the developing embryo. In Utricularia, the formation of the syncytium provides an economical way to redistribute cell components and release nutrients from the digested cell walls, which can now be used for the embryo, and finally to create a large surface for the exchange of nutrients between the placenta and endosperm.     

Evolution study of the Baeyer–Villiger monooxygenases enzyme family: Functional importance of the highly conserved residues

Baeyer–Villiger monooxygenases (BVMOs) catalyze the transformation of linear and cyclic ketones into their corresponding esters and lactones by introducing an oxygen atom into a C–C bond. This bioreaction has numerous advantages compared to its chemical version; it does not induce the use of potentially harmful reagents (i.e., green chemistry) and displays significant better enantio- and regio-selectivity.     

General and specific lipid–protein interactions in Na,K-ATPase

The molecular activity of Na,K-ATPase and other P2 ATPases like Ca^2 +-ATPase is influenced by the lipid environment via both general (physical) and specific (chemical) interactions. Whereas the general effects of bilayer structure on membrane protein function are fairly well described and understood, the importance of the specific interactions has only been realized within the last decade due particularly to the growing field of membrane protein crystallization, which has shed new light on the molecular details of specific lipid–protein interactions. It is a remarkable observation that specific lipid–protein interactions seem to be evolutionarily conserved, and conformations of specifically bound lipids at the lipid–protein surface within the membrane are similar in crystal structures determined with different techniques and sources of the protein, despite the rather weak lipid–protein interaction energy. Studies of purified detergent-soluble recombinant αβ or αβFXYD Na,K-ATPase complexes reveal three separate functional effects of phospholipids and cholesterol with characteristic structural selectivity. The observations suggest that these three effects are exerted at separate binding sites for phophatidylserine/cholesterol (stabilizing), polyunsaturated phosphatidylethanolamine (stimulatory), and saturated PC or sphingomyelin/cholesterol (inhibitory), which may be located within three lipid-binding pockets identified in recent crystal structures of Na,K-ATPase. The findings point to a central role of direct and specific interactions of different phospholipids and cholesterol in determining both stability and molecular activity of Na,K-ATPase and possible implications for physiological regulation by membrane lipid composition. This article is part of a special issue titled “Lipid–Protein Interactions.”     

Characterization of the α-mannosidase gene family in filamentous fungi: N-glycan remodelling for the development of eukaryotic expression systems

Although filamentous fungi are used extensively for protein expression, their use for the production of heterologous glycoproteins is constrained by the types of N-glycan structures produced by filamentous fungi as compared to those naturally found on the glycoproteins. Attempts are underway to engineer the N-glycan synthetic pathways in filamentous fungi in order to produce fungal expression strains which can produce heterologous glycoproteins carrying specific N-glycan structures. To fully realize this goal, a detailed understanding of the genetic components of this pathway in filamentous fungi is required. In this review, we discuss the characterization of the α-mannosidase gene family in filamentous fungi and its implications for the elucidation of the N-glycan synthetic pathway.     

Glutathionyl-biliverdin IXα, a new heme catabolite in a marine annelid: Sex and cell specific accumulation

We have isolated and characterized the green pigment accumulating in coelomic cells (eleocytes) of the common clam worm Nereis virens by means of RP-HPLC and ESI-tandem mass spectrometry. This pigment is a novel biliverdin-glutathione conjugate in which the glutathione is linked to the biliverdin-backbone via a thioether bond. The yolk precursor vitellogenin, a female-specific high-density lipoprotein (ρ = 1179 kg/m³) with a native molecular mass of ∼500 kDa and a subunit mass of ∼150 kDa, is capable of transporting this pigment as well as heme. The sex-independent large discoidal lipoprotein present in the coelomic fluid, which is sequestered by the eleocytes, could also be shown to transport heme. This renders both lipoproteins as heme-lipoproteins. As the vitellogenin is secreted by the eleocytes, this suggests the eleocytes as a metabolic hub linking the uptake of the potent pro-oxidant heme thought to arise from aged hemoglobin via the large discoidal lipoprotein and its conversion to a bile pigment-conjugate. The conjugate is exported from the eleocytes to the oocytes via vitellogenin leading to the accumulation of green yolk protein. In contrast, no such export route exists in male eleocytes resulting in an accumulation of the biliverdin-conjugate in these cells.     

Double-stranded microRNA mimics can induce length- and passenger strand–dependent effects in a cell type–specific manner

MicroRNAs are short (17–26) noncoding RNAs driving or modulating physiological and pathological cellular events. Overexpression of miR-155 is pathogenic in B-cell malignancy but was also reported in a number of solid tumors—in particular, in breast cancer, where its role remains unclear and often contradictory. Using representative cell line models, we sought to determine whether the discrepant miR-155 effects in breast cancer could be explained by the heterogeneity of the disease. The growth of six breast cancer cell lines transfected with several miRNA mimics was analyzed. We found MCF-7 cell growth to be inhibited by miR-155 and miR-145 mimics, both 23-nt long, but not by a number of shorter mimics, including a universal commercial negative control. Microarray and Western blot analyses revealed induction of apoptosis, associated with interferon-β after activation of the double-stranded RNA sensor pathway. 3′ Trimming of the miRNA mimics to 21 nt substantially reduced their growth-inhibitory potency. Mutating the canonical seed of the miR-155 mimic had no effect on the induced inhibition, which was abolished by mutating the miRNA seed of the artificial passenger strand. A panel of breast cancer cell lines showed a wide range of sensitivities to 23-mer mimics, broadly consistent with the sensitivity of the cell lines to Poly (I:C). We demonstrate two sources for nonspecific in vitro effects by miRNA mimics: duplex length and the artificial passenger strand. We highlight the danger of a universal 21-mer negative control and the importance of using matched seed mutants for reliable interpretation of phenotypes.     

α-catenin,vinculin, and F-actin in strengthening E-cadherin cell–cell adhesions and mechanosensing

Classical cadherins play a crucial role in establishing intercellular adhesion, regulating cortical tension, and maintaining mechanical coupling between cells. The mechanosensitive regulation of intercellular adhesion strengthening depends on the recruitment of adhesion complexes at adhesion sites and their anchoring to the actin cytoskeleton. Thus, the molecular mechanisms coupling cadherin-associated complexes to the actin cytoskeleton are actively being studied, with a particular focus on α-catenin and vinculin. We have recently addressed the role of these proteins by analyzing the consequences of their depletion and the expression of α-catenin mutants in the formation and strengthening of cadherin-mediated adhesions. We have used the dual pipette assay to measure the forces required to separate cell doublets formed in suspension. In this commentary, we briefly summarize the current knowledge on the role of α-catenin and vinculin in cadherin-actin cytoskeletal interactions. These data shed light on the tension-dependent contribution of α-catenin and vinculin in a mechanoresponsive complex that promotes the connection between cadherin and the actin cytoskeleton and their requirement in the development of adhesion strengthening.     

Complex multicellularity in fungi: evolutionary convergence,single origin,or both?

Complex multicellularity represents the most advanced level of biological organization and it has evolved only a few times: in metazoans, green plants, brown and red algae and fungi. Compared to other lineages, the evolution of multicellularity in fungi follows different principles; both simple and complex multicellularity evolved via unique mechanisms not found in other lineages. Herein we review ecological, palaeontological, developmental and genomic aspects of complex multicellularity in fungi and discuss general principles of the evolution of complex multicellularity in light of its fungal manifestations. Fungi represent the only lineage in which complex multicellularity shows signatures of convergent evolution: it appears 8–11 times in distinct fungal lineages, which show a patchy phylogenetic distribution yet share some of the genetic mechanisms underlying complex multicellular development. To explain the patchy distribution of complex multicellularity across the fungal phylogeny we identify four key observations: the large number of apparently independent complex multicellular clades; the lack of documented phenotypic homology between these clades; the conservation of gene circuits regulating the onset of complex multicellular development; and the existence of clades in which the evolution of complex multicellularity is coupled with limited gene family diversification. We discuss how these patterns and known genetic aspects of fungal development can be reconciled with the genetic theory of convergent evolution to explain the pervasive occurrence of complex multicellularity across the fungal tree of life.     

Production of arachidonic acid and dihomo-γ-linolenic acid from glycerol by oil-producing filamentous fungi, Mortierella in the ARS culture collection

The filamentous fungi of the genus Mortierella are known to produce arachidonic acid from glucose, and the species alpina is currently used in industrial production of arachidonic acid in Japan. In anticipation of a large excess of the co-product glycerol from the national biodiesel program, we are trying to find new uses for bioglycerin. We screened 12 Mortierella species: M. alpina NRRL 6302, M. claussenii NRRL 2760, M. elongata NRRL 5246, M. epigama NRRL 5512, M. humilis NRRL 6369, M. hygrophila NRRL 2591, M. minutissima NRRL 6462, M. multidivaricata NRRL 6456, M. nantahalensis NRRL 5216, M. parvispora NRRL 2941, M. sepedonioides NRRL 6425, and M. zychae NRRL 2592 for their production of arachidonic acid (AA) and dihomo-γ-linolenic acid (DGLA) from glycerol. With glucose as substrate all of the strains tested produced AA and DGLA. The total fatty acid content of 125 mg/g cell dry weight (CDW) and fatty acid composition for AA (19.63%) and DGLA (5.95%) in the mycelia of M. alpina grown on glucose were comparable with those reported by Takeno et al. (Appl Environ Microbiol 71:5124–5128, 2005). With glycerol as substrate all species tested grew on glycerol and produced AA and DGLA except M. nantahalensis NRRL 5216, which could not grow on glycerol. The amount of AA and DGLA produced were comparable with those obtained with glucose-grown mycelia. The top five AA producers (mg AA/CDW) from glycerol were in the following order: M. parvispora > M. claussenii > M. alpina > M. zychae > M. minutissima. The top five dry mycelia weights were: M. zychae > M. epigama > M. hygrophila > M. humilis > M. minutissima. The top five species for total fatty acids production (mg /g CDW) were: M. claussenii > M. parvispora > M. minutissima > M. hygrophila > M. maltidivaricata. We selected two species, M. alpina and M. zychae for further studies with glycerol substrate. Their optimum production conditions were determined. Time course studies showed that the maximum cell growth and AA production for both species were at 6 days of incubation. Therefore, glycerol can be considered for industrial use in the production of AA and DGLA.