Effect of metal ions on the activity of the catalytic domain of calcineurin

Calcineurin (CN) is a heterodimer, composed of a catalytic subunit (CNA) and a regulatory subunit (CNB). There are four functional domains present in CNA, which are catalytic domain (CNa), CNB-binding domain (BBH), CaM-binding domain (CBH) and autoinhibitory domain (AI). It has been shown previously that the in vitro activity of calcineurin is relied primarily on the binding of metal ions. Mn2+ and Ni2+ are the most crucial cation-activators for this enzyme. In order to determine which domain(s) in CN is functionally regulated by metal ions, the rat CNA alpha subunit and its catalytic domain (CNa) were cloned and expressed in E. coli. The effects of Mn2+, Ni2+ and Mg2+ on the catalytic activity of these purified proteins were examined. Our results demonstrate that all the metal ions tested in this study activated either CNA or CNa. However, the activation degree of CNa by the metal ions was much higher than that of CNA. In term of different metal ions, the activating extents to CNA and CNa were different. To CNA, the activating order from high to low was Mg2+ > > Ni2+ > Mn2+, but Mn2+ > Ni2+ > > Mg2+ to CNa. No effect of CaM/Ca2+ and CNB/Ca2+ on the activity of CNa was observed in our experiments. Moreover, a weak interaction (or untight coordination binding) between metal ions and the enzyme molecule was also identified. These results suggest that the activation of these enzymes by the exogenous metal ions might be via both regulating fragment of CNA (including BBH, CBH and AI) and catalytic domain (CNa), and mainly via regulating fragment to CNA and mainly via catalytic domain to CNa. The activating extents of metal ions via catalytic domain were higher than that via regulating fragment. The results obtained in this study should be very useful for understanding the molecular mechanism underlying the interaction between calcineurin and metal ions, especially Mn2+, Ni2+ and Mg2+.     

利用蛋白质限制性水解法解析大肠杆菌T蛋白的独立结构域

为了解析分支酸变位酶和预苯酸脱氢酶在大肠杆菌T蛋白的定位,根据T蛋白限制性水解结果,分段克隆分支酸变位酶和预苯酸脱氢酶.T蛋白限制性水解结果显示,第93位氨基酸是大片段的N端,分段克隆的1～93 片段测定得到分支酸变位酶活性,96～373片段得到了预苯酸脱氢酶活性.研究表明,大肠杆菌T蛋白由两个独立结构域组成,N端93个氨基酸组成了分支酸变位酶,C端277个氨基酸组成了预苯酸脱氢酶.     

几种脊椎动物宽频带心电图波形与心电向量环特点的比较

对小鼠、家鸽、蟾蜍、鲫鱼4种脊椎动物宽频带心电图Ⅱ导联的波形特点及QRS额面心电向量环的位置、形态特点进行了比较研究。结果发现,(1)宽频带心电图Ⅱ导联QRS波群小鼠、蟾蜍、鲫鱼QRS波群的主波均向上,而家鸽的主波向下;(2)QRS波群时程(ms)小鼠88±09,家鸽365±14,蟾蜍790±110,鲫鱼283±57;(3)QRS心电向量环的位置家鸽的位于-90°～-180°象限内,这是家鸽心电图Ⅱ导联QRS波群主波向下的根本原因;小鼠、蟾蜍、鲫鱼的均位于0°～90°象限内,与它们的QRS波群主波向上相一致;(4)QRS心电向量环的形状;小鼠的QRS向量环较其它3种动物的要大,蟾蜍的最小。鲫鱼的不规则,有的呈三角形,有的呈“8”字形,还有的呈半圆形,这是导致鲫鱼的QRS波群出现较多切迹和扭挫的原因。     

利用真菌纤维素结合域(CBD)保守性序列进行草菇木聚糖酶cDNA的克隆

木聚糖是植物细胞壁的主要组分,它是木糖以β1 ,4 木糖苷键形成主链,乙酰基,阿拉伯糖基等为附链组成的复合多聚糖.木聚糖酶可以降解木聚糖主链,在木聚糖的生物降解中起着非常重要的作用[1 ] .根据木聚糖酶催化域(catalyticdomain ,CD)氨基酸序列的相似性,木聚糖酶可分为两个家     

FMDV整联蛋白受体b1亚基的克隆及其配体黏附区多抗的制备

采用RT-PCR技术从牛气管组织扩增出2400 bp的b1基因, 回收纯化连入PGEM-T载体, 测序。用Expasy软件对b1基因的抗原性进行分析, 选取胞外区334~861 bp的配体结合区与6×His融合, 在大肠杆菌中大规模诱导表达, 并经Ni2+亲和柱层析纯化。通过SDS-PAGE鉴定后, 应用纯化蛋白免疫新西兰家兔, 获得效价在1:12 800以上的多抗, Western blotting鉴定表明此抗体可特异性的与表达的融合蛋白作用。     

Transmembrane domain interactions affect the stability of the extracellular domain of the human NTPDase 2

Human NTPDase2 and chicken NTPDase8 are cell surface nucleotidases that contain two transmembrane domains (TMD) and five apyrase conserved regions (ACRs). ACR1 is located near the N-terminal TMD whereas ACR5 is located near the C-terminal TMD. The human NTPDase2 activity is decreased by low concentration of NP-40 and at temperatures higher than 37 °C, and undergoes substrate inactivation, whereas the chicken NTPDase8 activity is not. When freed from membrane anchorage, the soluble human NTPDase2 is no longer inactivated by detergents, high temperature, and substrate. These characteristics are retained in the hu-ck ACR1,5 chimera in which the extracellular domain is anchored to the membrane by the two TMDs of the chicken NTPDase8. The hu-ck ACR1,5 chimera is the first chimeric NTPDase reported that shows a resistance to membrane perturbation and substrate inactivation. Our results indicate that the strengths of interaction of the respective TMD pairs of the human NTPDase2 and chicken NTPDase8 determine their different responses to membrane perturbation and substrate.     

A novel catalytic mechanism for ATP hydrolysis employed by the N-terminal nucleotide-binding domain of Cdr1p, a multidrug ABC transporter of Candida albicans

Although essentially conserved, the N-terminal nucleotide-binding domain (NBD) of Cdr1p and other fungal transporters has some unique substitutions of amino acids which appear to have functional significance for the drug transporters. We have previously shown that the typical Cys193 in Walker A as well as Trp326 and Asp327 in the Walker B of N-terminal NBD (NBD-512) of Cdr1p has acquired unique roles in ATP binding and hydrolysis. In the present study, we show that due to spatial proximity, fluorescence resonance energy transfer (FRET) takes place between Trp326 of Walker B and MIANS [2-(4-maleimidoanilino) naphthalene-6-sulfonic acid] on Cys193 of Walker A motif. By exploiting FRET, we demonstrate how these critical amino acids are positioned within the nucleotide-binding pocket of NBD-512 to bind and hydrolyze ATP. Our results show that both Mg²⁺ coordination and nucleotide binding contribute to the formation of the active site. The entry of Mg²⁺ into the active site causes the first large conformational change that brings Trp326 and Cys193 in close proximity to each other. We also show that besides Trp326, typical Glu238 in the Q-loop also participates in coordination of Mg²⁺ by NBD-512. A second conformational change is induced when ATP, but not ADP, docks into the pocket. Asn328 does sensing of the γ-phosphate of the substrate in the extended Walker B motif, which is essential for the second conformational change that must necessarily precede ATP hydrolysis. Taken together our results imply that the uniquely placed residues in NBD-512 have acquired critical roles in ATP catalysis, which drives drug extrusion.     

Murein (peptidoglycan) structure, architecture and biosynthesis in Escherichia coli

The periplasmic murein (peptidoglycan) sacculus is a giant macromolecule made of glycan strands cross-linked by short peptides completely surrounding the cytoplasmic membrane to protect the cell from lysis due to its internal osmotic pressure. More than 50 different muropeptides are released from the sacculus by treatment with a muramidase. Escherichia coli has six murein synthases which enlarge the sacculus by transglycosylation and transpeptidation of lipid II precursor. A set of twelve periplasmic murein hydrolases (autolysins) release murein fragments during cell growth and division. Recent data on the in vitro murein synthesis activities of the murein synthases and on the interactions between murein synthases, hydrolases and cell cycle related proteins are being summarized. There are different models for the architecture of murein and for the incorporation of new precursor into the sacculus. We present a model in which morphogenesis of the rod-shaped E. coli is driven by cytoskeleton elements competing for the control over the murein synthesis multi-enzyme complexes.     

Structural stability of GlcV, the nucleotide binding domain of the glucose ABC transporter of Sulfolobus solfataricus

GlcV is the nucleotide binding domain of the ABC-type glucose transporter of the hyperthermoacidophile Sulfolobus solfataricus. GlcV consists of two domains, an N-terminal domain containing the typical nucleotide binding-fold and a C-terminal β-barrel domain with unknown function. The unfolding and structural stability of the wild-type (wt) protein and three mutants that are blocked at different steps in the ATP hydrolytic cycle were studied. The G144A mutant is unable to dimerize, while the E166A and E166Q mutants are defective in ATP hydrolysis and dimer dissociation. Unfolding of the wt GlcV and G144A GlcV occurred with a single transition, whereas the E166A and E166Q mutants showed a second transition at a higher melting temperature indicating an increased stability of the ABCα/β subdomain. The structural stability of GlcV was increased in the presence of nucleotides suggesting that the transition corresponds to the unfolding of the NBD domain. Unfolding of the C-terminal domain appears to occur at temperatures above the unfolding of the NBD which coincides with the aggregation of the protein. Analysis of the domain organization of GlcV by trypsin digestion demonstrates cleavage of the NBD domain into three fragments, while nucleotides protect against proteolysis. The cleaved GlcV protein retained the ability to bind nucleotides and to dimerize. These data indicate that the wt GlcV NBD domain unfolds as a single domain protein, and that its stability is modified by mutations in the glutamate after the Walker B motif and by nucleotide binding.