Studies on Phyto-peroxidase

Japanese-radish peroxidase c, a paraperoxidase exhibiting the optical absorption spectrum of low-spin nature, was found to transform to a high-spin state by removing a dissociable ligand of low molecular weight by the addition of the stoichiometric amount of p-chloro mercuribenzoate, as in the case of horseradish peroxidase I or wheat germ peroxidase 566. The reaction could be reversed by the addition of cysteine to remove p-chloromercuribenzoate. As this ligand would be possibly cyanide, the affinity of the high-spin form of the enzyme to sodium cyanide was determined, which was found to be much higher than that of Japanese-radish peroxidase a. The high-spin form of peroxidase c formed the usual Compound I by the addition of hydrogen peroxide, so that the peroxidatic reaction catalyzed by this enzyme should follow the common mechanism of plant peroxidases. However, Compound II was scarecely observed during the course of the stepwise reduction of Compound I by ascorbate, probably because of its more rapid conversion to the free enzyme.     

甲醛固定对GFP发光特性的影响

绿色荧光蛋白(GFP)能够作为报告分子对活体细胞中特定基因的时空表达进行实时追踪,因此广泛应用于生物学研究领域。在用GFP对细胞活动进行追踪的实验中,常有无法在取样后及时对样品进行荧光观察的情况,此时需要先将样品进行固定以便对其进行观测。然而,不恰当的细胞固定方法会导致胞内GFP荧光信号强度减弱、位置改变等后果。甲醛是最常用的细胞固定剂,也常被用于固定表达GFP蛋白的细胞样品。但对甲醛固定GFP样品的报道多是针对于真核细胞,且固定效果也存在较大差异。文章系统地探索了甲醛浓度、固定时间、固定缓冲液种类对两种细菌(E.coli及鱼腥蓝细菌Anabaena PCC7120)胞内GFP信号的影响。结果显示,较低浓度(≤1%)的甲醛处理2h后,细胞的荧光强度在1d后仍可保持80%以上,胞内荧光点无弥散现象发生。具有相近pH的几种常见缓冲液对荧光强度的影响无显著差异。随着甲醛浓度的增加、固定时间的延长、溶液pH的增加(中性至偏碱性),细胞中的荧光强度会逐渐降低。     

鸡卵清蛋白基因转录起始点的确定及表达载体的构建

采用5’RACE方法确定鸡卵清蛋白基因转录起始点的位置,通过序列分析得出转录起始点为G,从而确定出核心启动子及上游调控区的位置。应用PCR技术分别扩增两段卵清蛋白基因上游调控序列的两个片段,长度分别为1．5kb和2．9kb。经PCR测序和克隆测序后,针对突变的碱基进行修复,并将修复的两片段分别连接在带有绿色荧光蛋白报告基因pGFP-N2载体上,为使pGFP-N2载体本身的CMV启动子不影响对鸡卵清蛋白启动子的研究,将其切去,构建了P1.5koval-GFP和R2.9koval-GFP两种表达载体,经酶切鉴定这两种表达载体构建正确。     

家蝇卵黄蛋白基因启动子区的克隆与活性分析

从家蝇基因组文库中分离到含约1．7kb5’上游区的家蝇卵黄蛋白-1基因组基因序列,根据其5’上游序列,PCR扩增出大小不同的4个启动子片段,分别插入到切除了CMV启动子的pCMV-GFP质粒中的绿色荧光蛋白报告基因上游,构建了pMYP1-GFP、pMYP2-GFP、pMYP3-GFP和pMYP4-GFP4个重组质粒。另将 684／ 7、 1165／ 7这两个启动子片段用SpeⅠ和HindⅢ双酶切,去除包含CAAT／TATA盒的 302／ 7序列区后,分别构建了pMYP5-GFP和pMYP6-GFP两个重组质粒。通过电转移实验和荧光检测表明。 684／ 7、 1165／ 7、 1616／ 7这3个启动子片段具有转录活性,而 684／ 7启动子片段的转录活性最强, 296／ 7、 684／ 302、 1165／ 302这3个启动子片段无转录活性。上述实验结果表明。 302／ 7序列区为启动子的核心部分。 302到 1616之间存在调控性启动子或增强子等其他一些顺式元件。细胞转染实验证实,6种启动子片段在BHK-21和Sf9细胞中都未表现出可检测的转录活性,说明家蝇卵黄蛋白基因启动子具有组织或细胞特异性。     

Symmetry of septin hourglass and ring structures

Septin filaments form ordered hourglass and ring-shaped structures in close apposition to the yeast bud-neck membrane. The septin hourglass scaffolds the asymmetric localization of many essential cell division proteins. However, it is unknown whether the septin structures have an overall polarity along the mother-daughter axis that determines the asymmetric protein localization. Here we engineered rigid septin- green fluorescent protein (GFP) fusions with various fluorescence dipole directions by changing the position of the GFP beta-barrel relative to the septin filament axis. We then used polarized fluorescence microscopy to detect potential asymmetries in the filament organization. We found that both the hourglass and ring filament assemblies have sub-resolution C(2) symmetry and lack net polarity along the mother-daughter axis. The hourglass filaments have an additional degree of symmetry relative to the ring filaments, most likely due to a twist in their higher-order structure. We previously reported that during the hourglass to rings transition septin filaments change their direction. Here we show that the filaments also undergo a change in their lateral organization, consistent with filament untwisting. The lack of net septin polarity along the mother-daughter axis suggests that there are no septin-based structural reasons for the observed asymmetry of other proteins. We discuss possible anisotropic processes that could break the septin symmetry and establish the essential bud-neck asymmetry.     

Functional Analysis of Human tRNA Isodecoders

tRNA isodecoders share the same anticodon but have differences in their body sequence. An unexpected result from genome sequencing projects is the identification of a large number of tRNA isodecoder genes in mammalian genomes. In the reference human genome, more than 270 isodecoder genes are present among the approximately 450 tRNA genes distributed among 49 isoacceptor families. Whether sequence diversity among isodecoder tRNA genes reflects functional variability is an open question. To address this, we developed a method to quantify the efficiency of tRNA isodecoders in stop-codon suppression in human cell lines. First, a green fluorescent protein (GFP) gene that contains a single UAG stop codon at two distinct locations is introduced. GFP is only produced when a tRNA suppressor containing CUA anticodon is co-transfected with the GFP gene. The suppression efficiency is examined for 31 tRNA isodecoders (all contain CUA anticodon), 21 derived from four isoacceptor families of tRNA^Ser genes, 7 from five families of tRNA^Leu genes, and 3 from three families of tRNA^Ala genes. We found that isodecoder tRNAs display a large difference in their suppression efficiency. Among those with above background suppression activity, differences of up to 20-fold were observed. We were able to tune tRNA suppression efficiency by subtly adjusting the tRNA sequence and inter-convert poor suppressors into potent ones. We also demonstrate that isodecoder tRNAs with varying suppression efficiencies have similar stability and exhibit similar levels of aminoacylation in vivo. Our results indicate that naturally occurring tRNA isodecoders can have large functional variations and suggest that some tRNA isodecoders may perform a function distinct from translation.     

The Effect of Monastrol on the Processive Motility of a Dimeric Kinesin-5 Head/Kinesin-1 Stalk Chimera

Controlled activity of several kinesin motors is required for the proper assembly of the mitotic spindle. Eg5, a homotetrameric bipolar kinesin-5 from Xenopus laevis, can cross-link and slide anti-parallel microtubules apart by a motility mechanism comprising diffusional and directional modes. How this mechanism is regulated, possibly by the tail domains of the opposing motors, is poorly understood. In order to explore the basic unregulated kinesin-5 motor activity, we generated a stably dimeric kinesin-5 construct, Eg5Kin, consisting of the motor domain and neck linker of Eg5 and the neck coiled coil of Drosophila melanogaster kinesin-1 (DmKHC). In single-molecule motility assays, we found this chimera to be highly processive. In addition, we studied the effect of the kinesin-5-specific inhibitor monastrol using single-molecule fluorescence assays. We found that monastrol reduced the length of processive runs, but strikingly did not affect velocity. Quantitative analysis of monastrol dose dependence suggests that two bound monastrol molecules are required to be bound to an Eg5Kin dimer to terminate a run.     

Binding of the inhibitor protein IF(1) to bovine F(1)-ATPase

In the structure of bovine F₁-ATPase inhibited with residues 1-60 of the bovine inhibitor protein IF₁, the α-helical inhibitor interacts with five of the nine subunits of F₁-ATPase. In order to understand the contributions of individual amino acid residues to this complex binding mode, N-terminal deletions and point mutations have been introduced, and the binding properties of each mutant inhibitor protein have been examined. The N-terminal region of IF₁ destabilizes the interaction of the inhibitor with F₁-ATPase and may assist in removing the inhibitor from its binding site when F₁F_o-ATPase is making ATP. Binding energy is provided by hydrophobic interactions between residues in the long α-helix of IF₁ and the C-terminal domains of the β_DP-subunit and β_TP-subunit and a salt bridge between residue E30 in the inhibitor and residue R408 in the C-terminal domain of the β_DP-subunit. Several conserved charged amino acids in the long α-helix of IF₁ are also required for establishing inhibitory activity, but in the final inhibited state, they are not in contact with F₁-ATPase and occupy aqueous cavities in F₁-ATPase. They probably participate in the pathway from the initial interaction of the inhibitor and the enzyme to the final inhibited complex observed in the structure, in which two molecules of ATP are hydrolysed and the rotor of the enzyme turns through two 120° steps. These findings contribute to the fundamental understanding of how the inhibitor functions and to the design of new inhibitors for the systematic analysis of the catalytic cycle of the enzyme.     

Improved imaging of actin filaments in transgenic Arabidopsis plants expressing a green fluorescent protein fusion to the C- and N-termini of the fimbrin actin-binding domain 2

The role of the actin cytoskeleton in plant development is intimately linked to its dynamic behavior. Therefore it is essential to continue refining methods for studying actin organization in living plant cells. The discovery of green fluorescent protein (GFP) has popularized the use of translational fusions of GFP with actin filament (F-actin) side-binding proteins to visualize in vivo actin organization in plants. The most recent of these live cell F-actin reporters are GFP fusions to the actin-binding domain 2 (ABD2) of Arabidopsis fimbrin 1 (ABD2-GFP). To improve ABD2-GFP fluorescence for enhanced in vivo F-actin imaging, transgenic Arabidopsis plants were generated expressing a construct with GFP fused to both the C- and N-termini of ABD2 under the control of the CaMV 35S promoter (35S::GFP-ABD2-GFP). The 35S::GFP-ABD2-GFP lines had significantly increased fluorescence compared with the original 35S::ABD2-GFP lines. The enhanced fluorescence of the 35S::GFP-ABD2-GFP-expressing lines allowed the acquisition of highly resolved images of F-actin in different plant organs and stages of development because of the reduced confocal microscope excitation settings needed for data collection. This simple modification to the ABD2-GFP construct presents an important tool for studying actin function during plant development.     

Multiple Tissue Transformation in Adult Zebrafish by Gene Gun Bombardment and Muscular Injection of Naked DNA

The efficiency of two direct gene transfer methods, gene gun (or particle bombardment) and intramuscular injection, in transforming adult zebrafish tissues in vivo was examined by a noninvasive approach using green fluorescent protein (GFP) reporter gene driven by the ubiquitously expressed human cytomegalovirus promoter. Particle bombardment of adult zebrafish caused internalization and expression of the plasmid only in the superficial layer such as epithelial cells, pigment cells, endothelial cells, and neurons, whereas direct injection primarily transformed muscle fibers of several bundles near or around the injection site. Expression was also evident in several nonmuscle tissues, such as skin epithelia, pigment cells, blood vessel cells, and neuron-like cells. GFP expression persisted for more than 50 days with both methods. These observations indicate the potential of these methods for functional analysis of tissue-specific promoters, delivery of DNA vaccine, and muscular expression of other useful genes. Received June 12, 2000; accepted September 12, 2000     

绿色荧光蛋白及其在植物研究中的应用

绿色荧光蛋白（ＧＦＰ）是海洋生物水母（Ａｅｑｕｏｒｅａｖｉｃｔｏｒｉａ）体内的一种发光蛋白,分子量２７ｋＤ,由２３８个氨基酸组成。该蛋白６５～６７位ＳｅｒＴｙｒＧｌｙ三种氨基酸环化加氧形成特殊的生色团结构。野生型ＧＦＰ发光较弱,而且ｇｆｐｃＤＮＡ含有隐蔽型剪切位点,而加工改造的ＧＦＰ在植物中能够正常表达并且加强了荧光信号。ＧＦＰ作为新的报告基因和遗传标记被广泛应用于植物研究之中。     

Construction of a Binary Vector for Knockout and Expression Analysis of Rice Blast Fungus Genes

We developed an efficient method to analyze gene function and expression of the rice blast fungus. We constructed a GATEWAY binary vector, which generates a gene-targeted disruptant carrying a green fluorescent protein gene under the native promoter of the target gene. Using this method, the knockout efficiency and expression patterns of two hypothetical genes were determined.     

Soluble,highly fluorescent variants of green fluorescent protein (GFP) for use in higher plants

Green fluorescent protein (GFP) from Aequorea victoria has rapidly become a standard reporter in many biological systems. However, the use of GFP in higher plants has been limited by aberrant splicing of the corresponding mRNA and by protein insolubility. It has been shown that GFP can be expressed in Arabidopsis thaliana after altering the codon usage in the region that is incorrectly spliced, but the fluorescence signal is weak, possibly due to aggregation of the encoded protein. Through site-directed mutagenesis, we have generated a more soluble version of the codon-modified GFP called soluble-modified GFP (smGFP). The excitation and emission spectra for this protein are nearly identical to wild-type GFP. When introduced into A. thaliana, greater fluorescence was observed compared to the codon-modified GFP, implying that smGFP is brighter because more of it is present in a soluble and functional form. Using the smGFP template, two spectral variants were created, a soluble-modified red-shifted GFP (smRS-GFP) and a soluble-modified blue-fluorescent protein (smBFP). The increased fluorescence output of smGFP will further the use of this reporter in higher plants. In addition, the distinct spectral characters of smRS-GFP and smBFP should allow for dual monitoring of gene expression, protein localization, and detection of in vivo protein-protein interactions.