绿色荧光蛋白与Wee1 Hu融合基因的构建及其真核表达

 构建Wee1Hu与增强型绿色荧光蛋白 (GFP)融合基因表达载体 ,并对其在真核细胞的表达及生物学效应进行研究 .应用基因工程技术构建重组载体 ,脂质体转染胰岛 β细胞株 ,流式细胞仪和免疫沉淀 Western印迹检测融合蛋白的表达 ,共聚焦显微镜分析融合蛋白在活细胞内的分布 ,3 D结构模建分析其结构特点 ,并用MTT法检测其生物学活性 .结果显示融合基因在瞬时或稳定转染的真核细胞中均获表达 ,融合蛋白主要分布在胞核区 ,融合蛋白中Wee1Hu的空间构象与天然Wee1Hu完全相同 ,表达融合蛋白的胰岛β细胞可避免其被细胞毒T淋巴细胞 (CTL)杀伤 .结果表明GFP Wee1Hu融合蛋白中 ,可发绿色荧光的分子标签GFP未能影响Wee1Hu的结构及其生物学活性 ;Wee1Hu可通过调控细胞周期而阻断CTL介导的细胞凋亡     

Expression and analysis of green fluorescent proteins in human embryonic kidney cells by capillary electrophoresis

The green fluorescent protein (GFP) has attracted much interest as a reporter for gene expression. In this paper, application of capillary electrophoresis with laser-induced fluorescent (CE-LIF) for quantitation of green fluorescence protein in cellular extracts and single cells is investigated. The S65T mutant form of GFP protein was successfully expressed in human embryonic kidney (HEK293) cells, and its production was confirmed by fluorescence microscopy and CE-LIF. The mass limit of detection for the mutant S65T was 5.3 x 10(-20) mol, which was better than that for the wild-type GFP by a factor of six. Detection of a small amount of GFP is difficult by conventional techniques such as fluorescent microscopy due to interference from cell autofluorescence at low GFP concentrations. The HEK293 cells were transfected with the GFP plasmid that produced S65T-GFP. Transient production of S65T protein was detected 2 h after the transfection and reached a maximum after 48 h. The protein concentration began to decrease significantly after 96 h. Single cell analysis of HEK293 cells after transfection with GFP plasmid indicate a nonuniform production of S65T-GFP protein among cells.     

Crystal structure and refolding properties of the mutant F99S/M153T/V163A of the green fluorescent protein

The mutant F99S/M153T/V163A of the Green Fluorescent Protein (c3-GFP) has spectral characteristics similar to the wild-type GFP, but it is 42-fold more fluorescent in vivo. Here, we report the crystal structure and the refolding properties of c3-GFP and compare them with those of the less fluorescent wt-GFP and S65T mutant. The topology and the overall structure of c3-GFP is similar to the wild-type GFP. The three mutated residues, Ser99, Thr153, and Ala163, lie on the surface of the protein in three different beta-strands. The side chains of Ser99 and Thr153 are exposed to the solvent, whereas that of Ala163 points toward the interior of the protein. No significant deviation from the structure of the wild-type molecule is found around these positions, and there is not clear evidence of any distortion in the position of the chromophore or of the surrounding residues induced by the mutated amino acids. In vitro refolding experiments on urea-denatured c3-GFP reveal a renaturation behavior similar to that of the S65T molecule, with kinetic constants of the same order of magnitude. We conclude that the higher fluorescence activity of c3-GFP can be attributed neither to particular structural features nor to a faster folding process, as previously proposed.     

人源细胞内物质转运调节分子ARFGAP1对细胞分泌功能的影响

 ARF GAP是重要的细胞内物质转运调节分子 .最近 ,在人胎肝 c DNA文库中发现一种新基因 ,其编码的氨基酸序列与大鼠的 ARF1 GAP有 32 %同源性 ,故将其命名为“ARFGAP1”.对ARFGAP1进行功能研究 ,利用分子克隆技术构建绿色荧光蛋白 (GFP) - ARFGAP1融合基因表达质粒 (p EGFP- C1 - ARFGAP1 ) ,经脂质体转染将其导入 COS- 7细胞瞬时表达 ,利用绿色荧光确定ARFGAP1的亚细胞定位 .结果显示 ,ARFGAP1位于细胞质部分 ,表达量高时 ,在核周高尔基体区聚集呈团块状或颗粒状 .构建真核表达质粒 pc DNA3.1 /myc- His- ARFGAP1 ,在 COS- 7细胞中表达 ,并用 ARFGAP1和分泌型碱性磷酸酶 (SEAP)真核表达质粒共同转染 COS- 7细胞 ,发现ARFGAP1在细胞中过表达能部分抑制 SEAP的分泌 .结果证明 ,ARFGAP1对细胞的物质转运和分泌功能有调节作用 .     

Recombination of the GFP gene to the BFP gene using a man-made site-selective DNA cutter

By using the recently developed man-made DNA cutter [a combination of Ce(IV)/EDTA and two DNA additives], green fluorescent protein (GFP) was converted to closely related blue fluorescent protein (BFP). The phosphodiester linkages at T196-A200 in the sense strand of GFP were hydrolyzed by the cutter, and the A1-T196 fragment in the product was selectively connected with the downstream fragment (C197-A720) of BFP by T4 DNA ligase. This recombination changed three codons in the GFP gene (TGC at 196–198, TAT at 199–201, and ACC at 502–504) to TCT, CAT, and ATC in BFP, and accordingly three amino acids in GFP (Cys65, Tyr66, and Thr167) were altered to Ser65, His66, and Ile167. The recombinant gene was successfully expressed in Escherichia coli and emitted blue fluorescence, confirming the absence of undesired side reactions (mutation, deletion, insertion, depurination, etc.) in the DNA manipulation. Electronic Supplementary Material Supplementary material is available for this article at and is accessible for authorized users.     

Engineering and characterization of a superfolder green fluorescent protein

Existing variants of green fluorescent protein (GFP) often misfold when expressed as fusions with other proteins. We have generated a robustly folded version of GFP, called 'superfolder' GFP, that folds well even when fused to poorly folded polypeptides. Compared to 'folding reporter' GFP, a folding-enhanced GFP containing the 'cycle-3' mutations and the 'enhanced GFP' mutations F64L and S65T, superfolder GFP shows improved tolerance of circular permutation, greater resistance to chemical denaturants and improved folding kinetics. The fluorescence of Escherichia coli cells expressing each of eighteen proteins from Pyrobaculum aerophilum as fusions with superfolder GFP was proportional to total protein expression. In contrast, fluorescence of folding reporter GFP fusion proteins was strongly correlated with the productive folding yield of the passenger protein. X-ray crystallographic structural analyses helped explain the enhanced folding of superfolder GFP relative to folding reporter GFP.     

Understanding the role of Arg96 in structure and stability of green fluorescent protein

Arg96 is a highly conservative residue known to catalyze spontaneous green fluorescent protein (GFP) chromophore biosynthesis. To understand a role of Arg96 in conformational stability and structural behavior of EGFP, the properties of a series of the EGFP mutants bearing substitutions at this position were studied using circular dichroism, steady state fluorescence spectroscopy, fluorescence lifetime, kinetics and equilibrium unfolding analysis, and acrylamide-induced fluorescence quenching. During the protein production and purification, high yield was achieved for EGFP/Arg96Cys variant, whereas EGFP/Arg96Ser and EGFP/Arg96Ala were characterized by essentially lower yields and no protein was produced when Arg96 was substituted by Gly. We have also shown that only EGFP/Arg96Cys possessed relatively fast chromophore maturation, whereas it took EGFP/Arg96Ser and EGFP/Arg96Ala about a year to develop a noticeable green fluorescence. The intensity of the characteristic green fluorescence measured for the EGFP/Arg96Cys and EGFP/Arg96Ser (or EGFP/Arg96Ala) was 5- and 50-times lower than that of the nonmodified EGFP. Intriguingly, EGFP/Arg96Cys was shown to be more stable than EGFP toward the GdmCl-induced unfolding both in kinetics and in the quasi-equilibrium experiments. In comparison with EGFP, tryptophan residues of EGFP/Arg96Cys were more accessible to the solvent. These data taken together suggest that besides established earlier crucial catalytic role, Arg96 is important for the overall folding and conformational stability of GFP.     

A Molecular Mechanics and Database Analysis of the Structural Preorganization and Activation of the Chromophore-Containing Hexapeptide Fragment in Green Fluorescent Protein

Abstract

We propose that heterologous posttranslational chromophore formation in green fluorescent protein (GFP) occurs because the chromophore-forming amino acid residues 65SYG67 are preorganized and activated for imidazolinone ring formation. Based on extensive molecular mechanical conformational searching of the precursor hexapeptide fragment (64FSYGVQ69), we suggest that the presence of low energy conformations characterized by short contacts (～3Å) between the carbonyl carbon of Ser65 and the amide nitrogen of Gly67 accounts for the initial step in posttranslational chromophore formation. Database searches showed that the tight turn required to establish the key short contact is a unique structural motif that is rarely found, except in other FSYG tetrapeptide sequences. Additionally, ab initio calculations demonstrated that an arginine side chain can hydrogen bond to the carbonyl oxygen of Ser65, activating this group for nucleophilic attack by the nearby lone pair of the Gly67 amide nitrogen. We propose that GFP chromophore-formation is initiated by a unique combination of conformational and electronic enhancements, identified by computational methods.     

Green fluorescent protein as a noninvasive intracellular pH indicator.

It was found that the absorbance and fluorescence of green fluorescent protein (GFP) mutants are strongly pH dependent in aqueous solutions and intracellular compartments in living cells. pH titrations of purified recombinant GFP mutants indicated >10-fold reversible changes in absorbance and fluorescence with pKa values of 6.0 (GFP-F64L/S65T), 5.9 (S65T), 6.1 (Y66H), and 4.8 (T203I) with apparent Hill coefficients of 0.7 for Y66H and approximately 1 for the other proteins. For GFP-S65T in aqueous solution in the pH range 5-8, the fluorescence spectral shape, lifetime (2.8 ns), and circular dichroic spectra were pH independent, and fluorescence responded reversibly to a pH change in <1 ms. At lower pH, the fluorescence response was slowed and not completely reversed. These findings suggest that GFP pH sensitivity involves simple protonation events at a pH of >5, but both protonation and conformational changes at lower pH. To evaluate GFP as an intracellular pH indicator, CHO and LLC-PK1 cells were transfected with cDNAs that targeted GFP-F64L/S65T to cytoplasm, mitochondria, Golgi, and endoplasmic reticulum. Calibration procedures were developed to determine the pH dependence of intracellular GFP fluorescence utilizing ionophore combinations (nigericin and CCCP) or digitonin. The pH sensitivity of GFP-F64L/S65T in cytoplasm and organelles was similar to that of purified GFP-F64L/S65T in saline. NH4Cl pulse experiments indicated that intracellular GFP fluorescence responds very rapidly to a pH change. Applications of intracellular GFP were demonstrated, including cytoplasmic and organellar pH measurement, pH regulation, and response of mitochondrial pH to protonophores. The results establish the application of GFP as a targetable, noninvasive indicator of intracellular pH.     

STAT3 入核分子机制的初步研究

为了研究Stat3入核的分子机制,将SV40大T抗原的经典核定位序列NLS(nuclear localization sequence)分别融合在Stat3-GFP分子和缺失突变体Dstat3-GFP的分子之间,构建Stat3-NLS-GFP和Dstat3-NLS-GFP融合分子。转染293T细胞,以NLS-GFP为阳性对照,通过激光共聚焦显微镜的观察融合分子的亚细胞位置,未经白介素-6刺激的Stat3-NLS-GFP和经白介素-6刺激的Stat3-GFP呈胞核分布,未经白介素-6刺激的Stat3-GFP和Dstat3-NLS-GFP呈胞浆分布,初步证明Stat3入核是由于获得了核定位序列。     

Imaging fluorescence resonance energy transfer between two green fluorescent proteins in living yeast

We show that fluorescence resonance energy transfer between two mutants of the green fluorescent protein (GFP) can be monitored by imaging microscopy in living yeast. This work is based on the constitutive expression of a GFP-containing fusion protein and the inducible expression of the tobacco etch virus (TEV) protease. In the fusion protein, the P4.3 GFP mutant is linked to the YS65T GFP mutant by a spacer bearing the TEV protease-specific cleavage site.     

Structural and spectral response of green fluorescent protein variants to changes in pH

The green fluorescent protein (GFP) from the jellyfish Aequorea victoria has become a useful tool in molecular and cell biology. Recently, it has been found that the fluorescence spectra of most mutants of GFP respond rapidly and reversibly to pH variations, making them useful as probes of intracellular pH. To explore the structural basis for the titration behavior of the popular GFP S65T variant, we determined high-resolution crystal structures at pH 8.0 and 4.6. The structures revealed changes in the hydrogen bond pattern with the chromophore, suggesting that the pH sensitivity derives from protonation of the chromophore phenolate. Mutations were designed in yellow fluorescent protein (S65G/V68L/S72A/T203Y) to change the solvent accessibility (H148G) and to modify polar groups (H148Q, E222Q) near the chromophore. pH titrations of these variants indicate that the chromophore pKa can be modulated over a broad range from 6 to 8, allowing for pH determination from pH 5 to pH 9. Finally, mutagenesis was used to raise the pKa from 6.0 (S65T) to 7.8 (S65T/H148D). Unlike other variants, S65T/H148D exhibits two pH-dependent excitation peaks for green fluorescence with a clean isosbestic point. This raises the interesting possibility of using fluorescence at this isosbestic point as an internal reference. Practical real time in vivo applications in cell and developmental biology are proposed.     

Single-molecule imaging of full protein synthesis by immobilized ribosomes

How folding of proteins is coupled to their synthesis remains poorly understood. Here, we apply single-molecule fluorescence imaging to full protein synthesis in vitro. Ribosomes were specifically immobilized onto glass surfaces and synthesis of green fluorescent protein (GFP) was achieved using modified commercial Protein Synthesis using Recombinant Elements that lacked ribosomes but contained purified factors and enzyme that are required for translation in Escherichia coli. Translation was monitored using a GFP mutant (F64L/S65T/F99S/M153T/V163A) that has a high fluorophore maturation rate and that contained the Secretion Monitor arrest sequence to prevent dissociation from the ribosome. Immobilized ribosomal subunits were labeled with Cy3 and GFP synthesis was measured by colocalization of GFP fluorescence with the ribosome position. The rate of appearance of colocalized ribosome GFP was equivalent to the rates of fluorescence appearance coupled with translation measured in bulk, and the ribosome-polypeptide complexes were stable for hours. The methods presented here are applicable to single-molecule investigation of translational initiation, elongation and cotranslational folding.     

A novel mutant of green fluorescent protein with enhanced sensitivity for microanalysis at 488 nm excitation.

Green fluorescent protein (GFP) has been utilized as a powerful reporter of gene expression and protein localization in cells. We discovered a mutant carrying point mutation S208L from a UV-excitable GFP (F99S/M153T/V163A). It had the enhanced fluorescence intensity. Introduction of the red-shifted mutations (F64L/S65T) to this mutant led to the GFP having the brightest mutants reported which were expressed in Escherichia coli and excited at 488 nm. The relative fluorescence intensities to that of wild-type GFP and GFPuv were increased about 120- and 10-fold, respectively. It was shown that the S208L mutation contributes to both a higher intrinsic brightness of GFP and a higher expression level in E. coli.     

Jellyfish green fluorescent protein as a useful reporter for transient expression and stable transformation in<Emphasis Type="Italic"> Medicago sativa</Emphasis> L.

The aim of the experiments reported herein was to transiently test different gene constructs using green fluorescent protein (GFP) as a reporter gene for a future localization of the maize -zein in the chloroplast of alfalfa (Medicago sativa L.). The transient expression of two GFP genes was compared in alfalfa leaves to determine which of these two mutants is the easier to detect. Based on the intensity of fluorescence emitted, the GFP S65C gene was used to assemble a chloroplast-targeted GFP to verify the efficiency of the transit peptide for chloroplast targeting. A chloroplast-targeted fusion protein between -zein and GFP was then assembled, and this protein was observed to accumulate in small aggregates into the chloroplasts of transiently transformed cells. To the best of our knowledge, this is the first report of the GFP S65C gene being used to obtain transformed alfalfa plants expressing GFP.Communicated by D. Dudits     

Measurement of green fluorescent protein concentration in single cells by image analysis

The gene encoding the green fluorescent protein (GFP) has been widely used in studies of gene expression. The GFP can be detected nondestructively in living cells or tissues by the green fluorescence of the protein under blue light. Solutions of enhanced GFP (EGFP) of known concentration were filled in glass capillaries and used to calibrate a method for quantitative determination of EGFP or GFP-S65T in plant cells. Images captured by a digital camera were analyzed to determine the linear range for measurement of EGFP expression. The value of the method was illustrated by analysis of the relative levels of GFP expression under control of different promoters in aleurone cells of barley.     

High level Purkinje cell specific expression of green fluorescent protein in transgenic mice

The green fluorescent protein (GFP) has become a powerful tool in molecular and cell biology. It is a commonly used marker for cloning and transfection experiments as well as a useful label of living cells allowing continuous observation of developing structures. In order to unravel mechanisms of neuronal differentiation, we generated a transgenic mouse model which expresses GFPS65T,hu under the control of the Purkinje cell-specific promoter L7/pcp-2. Here, we show that GFPS65T,hu is highly expressed specifically in the cerebellum in whole mount preparations after the 2nd postnatal week. GFPS65T,hu can be detected exclusively in Purkinje cells of cerebellar slices. The fluorescence intensity of GFPS65T,hu should enable the characterization and recording of axons, dendrites, and spines protruding from these neuronal processes. The level of GFP expression can be quantified by western blotting which allows to analyze protein expression and L7/pcp-2 promoter regulation in vivo. The application of cellular and physiological techniques on L7GFP mice will provide a remarkable opportunity to investigate various aspects of neuronal development at the cellular and subcellular levels.     

A glucoamylase::GFP gene fusion to study protein secretion by individual hyphae of Aspergillus niger

Although Aspergillus niger is used as a host for heterologous protein production, yields are generally lower than those obtained for homologous proteins. Mechanisms of protein secretion and the secretory pathway in filamentous fungi are poorly characterised, although there is evidence to suggest that secretion occurs by a mechanism similar to that in other eukaryotes, but with proteins destined for secretion being directed to the hyphal tip. We report on a method using a glucoamylase: GFP gene fusion which allows us for the first time to monitor, in vivo, protein secretion in A. niger at the single hyphal level. A synthetic green fluorescent protein (sGFP(S65T)) was fused to truncated A. niger glucoamylase (GLA:499). Southern blot analysis of transformants confirmed that the gene fusion had successfully integrated into the A. niger genome. Confocal and fluorescence microscopy revealed that the GLA::GFP fusion protein is fluorescent in A. niger and appears to be directed to the hyphal tip. In young mycelia, hyphal cell wall fluorescence is apparent and immunogold labelling of GFP confirmed that GFP was partially localised within the hyphal cell wall. Using Western blotting, extracellular GLA::GFP was detected only in culture filtrates of young mycelia grown in a soya milk medium. The actin inhibitor latrunculin B was used to disrupt the secretion process, and its effects on the distribution of GLA::GFP were monitored.     

Modification of growth anisotropy and cortical microtubule dynamics in Arabidopsis hypocotyls grown under microgravity conditions in space

We carried out a space experiment, denoted as Aniso Tubule, to examine the effects of microgravity on the growth anisotropy and cortical microtubule dynamics in Arabidopsis hypocotyls, using lines in which microtubules are visualized by labeling tubulin or microtubule‐associated proteins (MAPs) with green fluorescent protein (GFP). In all lines, GFP‐tubulin6 (TUB6)‐, basic proline‐rich protein1 (BPP1)‐GFP‐ and spira1‐like3 (SP1L3)‐GFP‐expressing using a constitutive promoter, and spiral2 (SPR2)‐GFP‐ and GFP‐65 kDa MAP‐1 (MAP65‐1)‐expressing using a native promoter, the length of hypocotyls grown under microgravity conditions in space was longer than that grown at 1 g conditions on the ground. In contrast, the diameter of hypocotyls grown under microgravity conditions was smaller than that of the hypocotyls grown at 1 g. The percentage of cells with transverse microtubules was increased under microgravity conditions, irrespective of the lines. Also, the average angle of the microtubules with respect to the transverse cell axis was decreased in hypocotyls grown under microgravity conditions. When GFP fluorescence was quantified in hypocotyls of GFP‐MAP65‐1 and SPR2‐GFP lines, microgravity increased the levels of MAP65‐1, which appears to be involved in the maintenance of transverse microtubule orientation. However, the levels of SPR2 under microgravity conditions were comparable to those at 1 g. These results suggest that the microgravity‐induced increase in the levels of MAP65‐1 is involved in increase in the transverse microtubules, which may lead to modification of growth anisotropy, thereby developing longer and thinner hypocotyls under microgravity conditions in space.     

Productive interaction of chaperones with substrate protein domains allows correct folding of the downstream GFP domain

Green fluorescent protein (GFP) has been used to report protein folding by correlating solubility with fluorescence. In a GFP fusion protein, an upstream aggregation-prone domain can disrupt de novo folding of the GFP domain in Escherichia coli, resulting in a loss of fluorescence. Previously, we showed that prevention of misfolding of the upstream aggregation-prone domain by a coupled folding and binding interaction during protein synthesis restored both GFP fluorescence and solubility. Since molecular chaperones often fold nascent polypeptides through a bind-and-release interaction, the question remains whether the chaperone interaction with the upstream aggregation-prone domain enhances GFP fluorescence. Here, we demonstrate that a significant increase in GFP fluorescence occurred only when appropriate chaperones that recognized the aggregation-prone protein and helped its folding were co-expressed. A possible correlation between GFP fluorescence and the productive folding by chaperones is proposed. This study may provide a general strategy for identifying chaperones specific for difficult-to-fold proteins.