Role of conserved histidine residues in D-aminoacylase from Alcaligenes xylosoxydans subsp. xylosoxydans A-6

D-Aminoacylase from Alcaligenes xylosoxydans subsp. xylosoxydans A-6 (Alcaligenes A-6) was strongly inactivated by diethylpyrocarbonate (DEPC). An H67N mutant was barely active, with a kcat/Km 6.3 x 10(4) times lower than that of the recombinant wild-type enzyme, while the H67I mutant lost detectable activity. The H67N mutant had almost constant Km, but greatly decreased kcat. These results suggested that His67 is essential to the catalytic event. Both H69N and H69I mutants were overproduced in the insoluble fraction. The kcat/Km of H250N mutant was reduced by a factor of 2.5 x 10(4)-fold as compared with the wild-type enzyme. No significant difference between H251N mutant and wild-type enzymes in the Km and kcat was found. The Zn content of H250N mutant was nearly half of that of wild-type enzyme. These results suggest that the His250 residue might be essential to catalysis via Zn binding.     

Spectrophotometric determination of peptide transport with chromogenic peptide mimetics

A spectrophotometric assay to determine peptide transport has been developed. Using two chromogenic peptide mimetics, L-phenylalanyl-L-2-sulfanilylglycine (PSG) and L-phenylalanyl-L-3-thiaphenylalanine (PSP), the peptide transport patterns in individual cell species can be evaluated effectively. After the addition of PSG to a HeLa cell suspension, sulfanilic acid accumulated progressively inside, but not outside, the cells, demonstrating that PSG was transported wholly intact. The addition of PSP to the same cell suspension was followed immediately by extracellular thiophenol production. Measurement of the rate of thiophenol release thereby provided direct determination of PSP transport. The thiophenol release was consistent with Michaelis-Menten kinetics, with a K(m) of 0.016 mM and a V(max) of 5.07 nmol/min (1 x 10(6) cells/ml, pH 7.4, 37 degrees C). The resulting kinetic constants estimated were in agreement with values determined by single-substrate enzyme kinetics. Using PSP, transport kinetics of various dipeptides was examined by competitive spectrophotometry. As a result, dipeptides tested could be ranked in order of kinetic power for their transport.     

SIDECAR POLLEN suggests a plant-specific regulatory network underlying asymmetric microspore division in Arabidopsis

Asymmetric cell division is a universal strategy to generate diverse cell types necessary for patterning and proliferation of all eukaryotes. The development of haploid male gametophytes (pollen grains) in flowering plants is a remarkable example in which division asymmetry governs the functional specialization and germline differentiation essential for double fertilization. The male gametophyte is patterned via two mitotic divisions resulting in three highly differentiated daughter cells at maturity, a vegetative cell and two sperm cells. The first asymmetric division segregates a unique male germ cell from an undetermined haploid microspore and is executed in an elaborate sequence of cellular events. However the molecular mechanisms governing the division asymmetry in microspores are poorly understood. Recently we studied the phenotype of sidecar pollen (scp) mutants in detail, and demonstrated a requirement of SCP for both the correct timing and orientation of microspore division. SCP is a microspore-specific member of the LOB/AS2 domain family (LBD27/ASL29) showing that a plant-specific regulator plays a key role in oriented division of polarized microspores. Identification of SCP will serve as a new platform to further explore the largely unknown molecular networks regulating division asymmetry in microspores that establishes the male germline in flowering plants.Key words: sidecar pollen, microspore division, division asymmetry, male gametophyte development, male germline, LBD/ASL family proteinUnlike animals, flowering plants do not set aside a distinct germline from an early stage of the life cycle. Instead the angiosperm germline or germ cells are only segregated in the male and female gametophytes by a limited number of post-meiotic mitoses.¹ However, in common with their metazoan cousins, angiosperms utilize division asymmetry for cellular patterning and differentiation of their germlines. Through the unique patterning of a ‘cell-within-a-cell’ structure with three highly differentiated cells, the male gametophyte (pollen grains) serves its biological role to deliver two sessile male gametes to the female gametophyte. Two sequential but different modes of mitotic divisions pattern the male gametophyte (Fig. 1).² The first division (of the microspore) is asymmetric giving rise to two completely different daughter cells, a larger vegetative cell that will form the pollen tube and a smaller germ cell that is engulfed within the vegetative cell cytoplasm. The second division (of the germ cell) usually appears symmetric^† and produces a pair of linked sperm cells. Microspores artificially induced to undergo symmetric division using microtubule inhibitors lack the germ cell and fail to form the typical three-celled structure showing that asymmetry in microspore division is critical for patterning of the male gametophyte.⁴Open in a separate windowFigure 1Male gametophyte development in Arabidopsis (upper part) and mutations that block germ cell formation (lower part). (Upper part) Male gametophyte development involves two rounds of mitotic division. Prior to the first division the centrally positioned microspore nucleus migrates towards the radial wall (the future germ cell pole marked with an asterisk). At this eccentric site the polarized microspores undergo oriented mitosis and cytokinesis giving rise to highly unequal daughter cells, a vegetative cell and a germ cell of which the later produces a pair of sperm cells by symmetric division. (Lower part) Mutants that fail to establish a distinct germ cell arising from specific defects are illustrated. Arrows in red indicate the developmental origin of the phenotypic defects in mutants. Note that two daughter nuclei in the mutants are in grey to show that their cell fates have not yet been thoroughly investigated. n, nucleus; Vn, vegetative nucleus; Gn, generative nucleus; Gc, generative (or germ) cell; Sc, sperm cell; WT, wild type; gem1, gemini pollen1; scp, sidecar pollen; tio, two-in-one; hik/tes, hinkel/tetraspore 12a/12b, kinesin-12a/kinesin-12b.     

Targeted delivery of paclitaxel using folate-conjugated heparin-poly(β-benzyl-l-aspartate) self-assembled nanoparticles

A self-assembled nanoparticulate system composed of a folate-conjugated heparin-poly(β-benzyl-l-aspartate) (HP) amphiphilic copolymer was proposed for targeted delivery of the antineoplastic drug paclitaxel (PTX). PTX was incorporated into three types of heparin-based nanoparticles, including HP, folate-conjugated HP (FHP), and folate-polyethylene glycol (PEG)-conjugated HP (FPHP), using a simple dialysis method. The PTX-loaded nanoparticles were then characterized according to particle size (140-190 nm) and size distribution, drug-loading content and efficiency, and in vitro release behavior. In the cellular uptake study using KB cells positive for the folate-receptor (FR), FHP and FPHP nanoparticles showed a much higher cellular uptake than did unconjugated HP nanoparticles. Specifically, when the PEG spacer was inserted between the folate ligand and heparin backbone, FPHP nanoparticles had a greater cellular uptake than did FHP nanoparticles. The in vitro cytotoxicity of PTX-loaded HP, FHP, and FPHP nanoparticles was studied in KB cells and FR-negative A549 cells. Compared with the cytotoxicity in A549 cells, PTX-loaded FHP and FPHP nanoparticles exhibited more potent cytotoxicity in KB cells than did PTX-loaded HP nanoparticles and free-PTX, suggesting that the presence of folate enhanced intracellular uptake via FR-mediated endocytosis. In addition, FPHP nanoparticles exhibited much greater cytotoxicity in KB cells than did FHP nanoparticles. These results suggest that PTX-loaded folate-conjugated HP nanoparticles are a potentially useful delivery system for cancer cells positive for the folate-receptor.     

Interleukin-4 plus tumor necrosis factor α augments the antigenicity of melanoma cells

Immune cytokines are important regulators of the immune response to neoplastic cells. We previously reported that interleukin 4 (IL-4) and either tumor necrosis factor α (TNF) or interferon γ (IFN) synergistically inhibit melanoma cell growth and induce cell differentiation. In the present study we used various combinations of IL-4, IFN and TNF to enhance the antigenicity of melanoma cells. IL-4 plus TNF significantly increased the ability of melanoma cells to stimulate cytotoxic T cells (CTL) and act as targets of these CTL; IL-4 plus IFN was somewhat less effective, while TNF plus IFN was not as effective. IL-4 plus TNF also increased the expression of HLA class I and HLA-DR antigens on melanoma cells. The CTL lines examined in this study were CD3⁺CD4⁺ and oligoclonal. These preclinical results suggest that the immune response to melanoma whole-cell vaccines might be enhanced by pretreating vaccine cells with IL-4 plus TNF.     

Effects of solution conditions on virus retention by the Viresolve® NFP filter

Virus filtration can provide a robust method for removal of adventitious parvoviruses in the production of biotherapeutics. Although virus filtration is typically thought to function by a purely size‐based removal mechanism, there is limited data in the literature indicating that virus retention is a function of solution conditions. The objective of this work was to examine the effect of solution pH and ionic strength on virus retention by the Viresolve^® NFP membrane. Data were obtained using the bacteriophage ?X174 as a model virus, with retention data complemented by the use of confocal microscopy to directly visualize capture of fluorescently labeled ?X174 within the filter. Virus retention was greatest at low pH and low ionic strength, conditions under which there was an attractive electrostatic interaction between the negatively charged membrane and the positively charged phage. In addition, the transient increase in virus transmission seen in response to a pressure disruption at pH 7.8 and 10 was completely absent at pH 4.9, suggesting that the trapped virus are unable to overcome the electrostatic attraction and diffuse out of the pores when the pressure is released. Further confirmation of this physical picture was provided by confocal microscopy. Images obtained at pH 10 showed the migration of previously captured phage; this phenomenon was absent at pH 4.9. These results provide important new insights into the factors governing virus retention using virus filtration membranes. © 2015 American Institute of Chemical Engineers Biotechnol. Prog., 31:1280–1286, 2015     

H+-ATPase defect in Corynebacterium glutamicum abolishes glutamic acid production with enhancement of glucose consumption rate

A mutant of Corynebacterim glutamicum ('Brevibacterium flayum') ATCC14067 with a reduced H+-ATPase activity, F172-8, was obtained as a spontaneous neomycin-resistant mutant. The ATPase activity of strain F172-8 was reduced to about 25% of that of the parental strain. Strain F172-8 was cultured in a glutamic-acid fermentation medium containing 100 g/l of glucose using ajar fermentor. It was found that glucose consumption per cell during the exponential phase was higher by 70% in the mutant than in the parent. The respiration rate per cell of the mutant also increased to twice as much as that of the parent. However, the growth rate of the mutant was lower than that of the parent. Under those conditions, the parent produced more than 40 g/l glutamic acid, while the mutant hardly produced any glutamic acid. Instead the mutant produced 24.6 g/l lactic acid as the main metabolite of glucose. Remarkably, the accumulation of pyruvate and pyruvate-family amino acids, i.e., alanine and valine, was detected in the mutant. On the other hand, the parent accumulated alpha-ketoglutaric acid and a glutamate-family amino acid, proline, as major by-products. It was concluded that the decrease in the H+-ATPase activity caused the above-mentioned metabolic changes in strain F172-8, because a revertant of strain F172-8, R2-1, with a H+-ATPase activity of 70% of that of strain ATCC14067, showed a fermentation profile similar to that of the parent. Sequence analyses of the atp operon genes of these strains identified one point mutation in the gamma subunit in strain F172-8.     

Studies on aspartase VIII. Protease-mediated activation: comparative survey of protease specificity for activation and peptide cleavage

The active species of aspartase from Escherichia coli is further 3-5 fold activated upon limited proteolysis with trypsin releasing carboxy-terminal peptides as reported previously (N. Yumoto, M. Tokushige, and R. Hayashi. Biochim. Biophys. Acta, 616, 319 (1980) ). Survey of the protease specificity for the activation revealed that subtilisin BPN' and several other proteases having far broader substrate specificity than trypsin also activated the enzyme. The results of sequence analyses revealed that subtilisin BPN' cleaved mainly the serylarginine bond near the carboxy-terminal and released an octapeptide, while trypsin cleaved mainly the arginyltyrosine bond which is just next to the subtilisin cleavage site. These results suggest that the protease-mediated activation does not necessarily require a site-specific peptidyl cleavage, but the cleavage of any bond within a certain region centered at arginine, the eighth residue from the carboxy-terminal, is sufficient.     

Degradation of methylmercury by selenium

When methylmercury was incubated in the presence of selenite and reduced glutathione (GSH), the mercury which was extracted into benzene under acidic condition decreased gradually with the elapse of time. This decrease was due to the cleavage of mercury-carbon bond of methylmercury. The reaction did not proceed when selenite or GSH was singly added to the reaction mixture. L-Cysteine, 2-mercaptoethanol and sodium sulfide in place of GSH also were effective for decomposition of methylmercury in combination with selenite, but oxidized glutathione (GSSG) and L-cystine were not. This suggests that reduction of selenite is needed for the degradation of methylmercury. Thus, the effect of reduced metabolites of selenite produced by GSH was investigated. Glutathione selenotrisulfide (GSSeSG) requierd GSH for the degradation of methylmercury, whereas H₂Se possessed a strong activity even in the absence of GSH. This may indicate that H₂Se is involved directly in the conversion of methylmercury to inorganic mercury. This phenomenon found in $\text{in vitro}$ experiments is discussed in relation to the biotransformation of methylmercury.     

Correlation between cell aggregation and antibody production in IgE-producing plasma cells

Allergic conditions result in the increase of immunoglobulin (Ig)E-producing plasma cells (IgE-PCs); however, it is unclear how IgE production is qualitatively controlled. In this study, we found that IgE-PCs in spleen of immunized mice formed homotypic cell aggregates. By employing IgE-producing hybridomas (IgE-hybridomas) as a model of IgE-PCs, we showed that these cells formed aggregates in the presence of specific antigens (Ags). The formation of the Ag-induced cell aggregation involved secreted IgE and Fcγ receptor (FcγR)II/FcγRIII, but not FcεRs. Ag-induced cell aggregation plus lipopolysaccharide signaling resulted in an enhancement of IgE production in aggregated IgE-hybridomas. Furthermore, the administration of anti-FcγRII/FcγRIII antagonistic monoclonal antibody to immunized mice tended to reduce the splenic IgE-PC aggregation as well as the serum IgE levels. Taken together, our results suggested that Ag-IgE complexes induced IgE-PCs aggregation via FcγRII/FcγRIII, leading to the enhancement of IgE production. These findings suggest the presence of a novel mechanism for regulation of IgE production.