Molecular characterization of dopamine D2 receptor isoforms tagged with green fluorescent protein

In this study, a cleavable signal peptide fused to the enhanced green fluorescent protein (EGFP) was tagged to the extracellular N-terminus of the human dopamine D2 receptor short and long isoforms (D2S and D2L). Ligand-binding properties of EGFP-tagged receptors were essentially unchanged in comparison to their respective wild-type receptors. The dopamine-mediated activation of both EGFP-D2 isoforms generated a robust inhibition of adenylyl cyclase type 5 in intact cells. In addition, the receptor density of EGFP-D2S and EGFP-D2L in transfected human embryonic kidney 293 (HEK293) cells was not altered when compared to cells transfected with the untagged D2S and D2L. However, the receptor densities of untagged and EGFP-tagged D2L were significantly lower in comparison to those measured with D2S constructs. Moreover, the receptor density of EGFP-D2S and EGFP-D2L was differentially upregulated in cells treated with antipsychotic drugs. As assessed by confocal microscopy, both EGFP-D2 isoforms were present on the cell surface. Notably, in contrast to the predominant plasma membrane localization of EGFP-D2S, EGFP-D2L was visualized both on the plasma membrane and intracellularly before dopamine exposure. Importantly, EGFP-D2S and EGFP-D2L are robustly internalized after dopamine treatment. Overall, our data suggest a differential intracellular sorting of D2S and D2L.     

Sequence variants in the melatonin-related receptor gene (GPR50) associate with circulating triglyceride and HDL levels

The gene encoding the melatonin-related receptor (GPR50) is highly expressed within hypothalamic nuclei concerned with the control of body weight and metabolism. We screened GPR50 for mutations in an obese cohort and identified an insertion of four amino acid residues (TTGH) at position 501, two common coding polymorphisms (T528A and V602I), and one noncoding polymorphism (C-16X2GPR50T). Single-nucleotide polymorphisms were then typed in 500 English Caucasian subjects, and associations were sought to intermediate obesity phenotypes. Although no association was seen with body mass index, carriers of two copies of the mutant allele at C-16X2GPR50T, Ins501Del, and A1582G had significantly higher fasting circulating triglyceride levels (P < 0.05). In a separate set of 585 subjects, the associations were replicated, with statistically significant effects of similar magnitude and direction. The association of C-16X2GPR50T with fasting triglycerides was highly significant (P < 0.001). In addition, a significant association between C-16X2GPR50T and circulating HDL levels was observed in the combined population, with C-16X2GPR50T carriers having significantly lower circulating HDL-cholesterol levels (1.39 mM) than wild-type subjects (1.47 mM) (P < 0.01). These findings suggest a previously unexpected role for this orphan receptor in the regulation of lipid metabolism that warrants further investigation.     

Innate immune response to human bone marrow fibroblastic cell implantation in CB17 scid/beige mice

Immunocompromised mouse models have been extensively used to assess human cell implantation for evaluation of cytotherapy, gene therapy and tissue engineering strategies, as these mice are deficient in T and B lymphoid cells. However, the innate immune response and its effect on human cell xenotransplantation in these mouse models are mainly unknown. The aim of this study is to characterise the myeloid populations in the spleen and blood of CB17 scid beige (CB17 sb) mice, and to study the inflammatory cell responses to xenogeneic implantation of enhanced green fluorescent protein (GFP)-labelled human bone marrow fibroblastic (HBMF) cells into CB17 sb mice. The results indicate that even though CB17 sb mice are deficient in B- and T-cells, they exhibit some increases in their monocyte (Mo), macrophage (Mphi) and neutrophil (Neu) populations. NK cell and eosinophil populations show no differences compared with wild-type Balb/C mice. An innate immune response, identified by CR3 (CD11b/CD18)-positive myeloid inflammatory cells and F4/80-positive macrophages, was evident in the tissues where HBMF cells were implanted. As a consequence, the majority of implanted HBMF cells were eliminated by 4 weeks after implantation. Interestingly, the mineralised matrix formed by osteogenic HBMF cells was also eroded by multinuclear Mphi-like giant cells. We conclude that CB17 sb mice retain active innate immune cells, which respond to HBMF cell xenotransplantation. This study highlights the importance of the innate immune cells in the anti-xenograft response and suggests that strategies to block the activities of these cells may ameliorate the progressive long-term elimination of xenotransplants.     

Interaction between mammalian glyceraldehyde-3-phosphate dehydrogenase and L-lactate dehydrogenase from heart and muscle

The exceptionally high protein concentration in living cells can favor functional protein-protein interactions that can be difficult to detect with purified proteins. In this study we describe specific interactions between mammalian D-glyceraldehyde-3-phosphate dehydrogenase (GAPDH) and L-lactate dehydrogenase (LDH) isozymes from heart and muscle. We use poly(ethylene-glycol) (PEG)-induced coprecipitation and native agarose electrophoresis as two independent methods uniquely suited to mimic some of the conditions that can favor protein-protein interaction in living cells. We found that GAPDH interacts with heart or muscle isozymes of LDH with approximately one-to-one stoichiometry. The interaction is specific; GAPDH shows interaction with two LDH isozymes that have very different net charge and solubility in PEG solution, while no interaction is observed with GAPDH from other species, other NAD(H) dehydrogenases, or other proteins that have very similar net charge and molecular mass. Analytical ultracentrifugation showed that the LDH and GAPDH complex is insoluble in PEG solution. The interaction is abolished by saturation with NADH, but not by saturation with NAD(+) in correlation with GAPDH solubility in PEG solution. The crystal structures show that GAPDH and LDH isozymes share complementary size, shape, and electric potential surrounding the active sites. The presented results suggest that GAPDH and LDH have a functional interaction that can affect NAD(+)/NADH metabolism and glycolysis in living cells.     

Application of fluorescent probes to study structural changes in Aspergillus fumigatus exposed to amphotericin B, itraconazole, and voriconazole

The broad objective of this study was to document patterns of structural changes following antifungal treatment, and to determine any relationship with minimum inhibitory concentration (MIC) of an antifungal. Three clinical isolates of Aspergillus fumigatus, with high, intermediate, and low amphotericin B (AB), itraconazole (IZ), and voriconazole (VZ) MICs were studied in 24-well plates with cover slips. The fluorescent probes used were Calcofluor White (cell wall), propidium iodide (nucleus), and MitoTracker Green FM (mitochondria). Fluorescent microscopy as early as 3-h after exposure revealed that AB treated hyphae had intact cell wall with deformed mitochondria and nuclei while IZ and VZ treated hyphae revealed no intact cell wall, and deformation of mitochondria and nuclei. At 48 h, AB treated cells revealed rupture of hyphae and disintegration of mitochondria, and nuclei, IZ treated hyphae were swollen with disintegration of mitochondria, and nuclei while VZ treated hyphae showed rupture and disintegration of mitochondria and nuclei. The structural changes for the three strains studied were similar in fluorescent microscopy as long as the incubation time and their respective MICs were used. Thus, AB, IZ, and VZ induced gross organelle defects in A. fumigatus nuclei, mitochondria, and cell wall, which were consistent with respective MICs of antifungals used.     

Metabolic flux distribution for γ-linolenic acid synthetic pathways in<Emphasis Type="Italic">Spirulina platensis</Emphasis>

Spirulina produces γ-linolenic acid (GLA), an important pharmaceutical substance, in a relatively low level compared with fungi and plants, prompting more research to improve its GLA yield. In this study, metabolic flux analysis was applied to determine the cellular metabolic flux distributions in the GLA synthetic pathways of twoSpirulina strains, wild type BP and a high-GLA producing mutant Z19/2. Simplified pathways involving the GLA synthesis ofS. platensis formulated comprise of photosynthesis, gluconeogenesis, the pentose phosphate pathway, the anaplerotic pathway, the tricarboxylic cycle, the GLA synthesis pathway, and the biomass synthesis pathway. A stoichiometric model reflecting these pathways contains 17 intermediates and 22 reactions. Three fluxes—the bicarbonate (C-source) uptake rate, the specific growth rate, and the GLA synthesis rate—were measured and the remaining fluxes were calculated using linear optimization. The calculation showed that the flux through the reaction converting acetyl-CoA into malonyl-CoA in the mutant strain was nearly three times higher than that in the wild-type strain. This finding implies that this reaction is rate controlling. This suggestion was supported by experiments, in which the stimulating factors for this reaction (NADPH and MgCl₂) were added into the culture medium, resulting in an increased GLA-synthesis rate in the wild type strain.     

Monitoring for dynamic biological processing by intramolecular bioluminescence resonance energy transfer system using secreted luciferase

Proteolytic processing plays crucial roles in physiological and pathophysiological cellular functions such as peptide generation, cell cycle, and apoptosis. We developed a novel biophysical bioluminescence resonance energy transfer (BRET) system between a secreted Vargula luciferase (Vluc) and an enhanced yellow fluorescent protein (EYFP) for visualization of cell biological processes. The bioluminescence spectrum of the fusion protein (Vluc-EYFP) is bimodal (lambdamax = 460 nm (Vluc) and 525nm (EYFP)), indicating that the excited-state energy of Vluc transfers to EYFP (in short, BRET). The BRET signal can be measured in the culture medium and pursue quantitative production of two neuropeptides, nocistatin (NST) and nociceptin/orphanin FQ (N/OFQ) in living cells. NST and N/OFQ are located in tandem on the same precursor, but NST exhibits antagonistic action against N/OFQ-induced central functions. Insertion of a portion of the NST-N/OFQ precursor (Glu-Gln-Lys-Gln-Leu-Gln-Lys-Arg-Phe-Gly-Gly-Phe-Tyr-Gly) in Vluc-EYFP makes the fusion protein cleavable at Lys-Arg in NG108-15 cells, and proprotein convertase 1 enhances this digestion. The change in BRET signals quantifies the processing of the fusion protein. Our novel intramolecular BRET system using a secreted luciferase is useful for investigating peptide processing in living cells.     

Mutation of active site residues in the chitin-binding domain ChBDChiA1 from chitinase A1 of Bacillus circulans alters substrate specificity: use of a green fluorescent protein binding assay

A fluorescent binding assay was developed to investigate the effects of mutagenesis on the binding affinity and substrate specificity of the chitin-binding domain of chitinase A1 from Bacillus circulans WL-12. The chitin-binding domain was genetically fused to the N-terminus of a green fluorescent protein, and the polyhistidine-tagged hybrid protein was expressed in Escherichia coli. Residues likely to be involved in the binding site were mutated and their contributions to binding and substrate specificity were evaluated by affinity electrophoresis and depletion assays. The experimental binding isotherms were analyzed by non-linear regression using a modified Langmuir equation. Non-conservative substitution of tryptophan residue (W687) nearly abolished chitin-binding affinity and dramatically lowered chitosan binding while retaining the original level of curdlan binding. Double mutation E668K/P689A had altered specificity for several substrates and also impaired chitin binding significantly. Other substitutions in the binding site altered substrate specificity but had little effect on overall affinity for chitin. Interestingly, mutation T682A led to a higher specificity towards chitinous substrates than the wildtype. Furthermore, the ChBD-GFP hybrid protein was tested for use in diagnostic staining of cell walls of fungi and yeast and for the detection of fungal infections in tissue samples.     

Evaluation of three expanded bed adsorption anion exchange matrices with the aid of recombinant enhanced green fluorescent protein overexpressed in Escherichia coli

Three anion exchanger expanded bed adsorption (EBA) matrices: Streamline DEAE, Streamline Q XL and Q Hyper Z were evaluated with the aid of EFGP from an ultrasonic homogenate of Escherichia coli. Two pH of buffer were tested. Capture was done in an expanded mode whereas elution was done in a packed mode. The same conditions were chosen for evaluation of the three matrices. We observed a loss of EGFP (8-15%) in the through flow fraction especially with the Streamline Q XL matrix, probably due to an aggregation of beads during sample application. The beads of this matrix possess tentacles which probably retain a lot of cellular and molecular debris. The two other matrices gave a good purification of the EGFP (7-15-fold) but the Q Hyper Z matrix appeared to give the best results. It is composed of little size and density beads which lead to a higher exchange surface and then a better mass transfer.     

Lipid-Membrane Affinity of Chimeric Metal-binding Green Fluorescent Protein

The Green Fluorescent Protein (GFP) is a useful marker to trace the expression of cellular proteins. However, little is known about changes in protein interaction properties after fusion to GFP. In this study, we present evidence for a binding affinity of chimeric cadmium-binding green fluorescent proteins to lipid membrane. This affinity has been observed in both cellular membranes and artificial lipid monolayers and bilayers. At the cellular level, the presence of Cd-binding peptide promoted the association of the chimeric GFP onto the lipid membrane, which declined the fluorescence emission of the engineered cells. Binding affinity to lipid membranes was further investigated using artificial lipid bilayers and monolayers. Small amounts of the chimeric GFP were found to incorporate into the lipid vesicles due to the high surface pressure of bilayer lipids. At low interfacial pressure of the lipid monolayer, incorporation of the chimeric Cd-binding GFP onto the lipid monolayer was revealed. From the measured lipid isotherms, we conclude that Cd-binding GFP mediates an increase in membrane fluidity and an expansion of the surface area of the lipid film. This evidence was strongly supported by epifluorescence microscopy, showing that the chimeric Cd-binding GFP preferentially binds to fluid-phase areas and defect parts of the lipid monolayer. All these findings demonstrate the hydrophobicity of the GFP constructs is mainly influenced by the fusion partner. Thus, the example of a metal-binding unit used here shines new light on the biophysical properties of GFP constructs.This revised version was published online in June 2005 with a corrected cover date.