The N-terminal region of the starch-branching enzyme from Phaseolus vulgaris L. is essential for optimal catalysis and structural stability

Starch-branching enzymes (SBEs) play a pivotal role in determining the fine structure of starch by catalyzing the syntheses of alpha-1,6-branch points. They are the members of the alpha-amylase family and have four conserved regions in a central (beta/alpha)8 barrel, including the catalytic sites. Although the role of the catalytic barrel domain of an SBE is known, that of its N- and C-terminal regions remain unclear. We have previously shown that the C-terminal regions of the two SBE isozymes (designated as PvSBE1 and PvSBE2) from kidney bean (Phaseolus vulgaris L.) have different roles in branching enzyme activity. To understand the contribution of the N-terminal region to catalysis, six chimeric enzymes were constructed between PvSBE1 and PvSBE2. Only one enzyme (1Na/2Nb)-II, in which a portion of the N-terminal region of PvSBE2 was substituted by the corresponding region of PvSBE1, retained 6% of the PvSBE2 activity. The N-terminal truncated form (DeltaN46-PvSBE2), lacking 46 N-terminal residues of PvSBE2, lost enzyme activity and stability to proteolysis. To investigate the possible function of this region, three residues (Asp-15, His-24, and Arg-28) among these 46 residues were subjected to site-directed mutagenesis. The purified mutant enzymes showed nearly the same K(m) values as PvSBE2 but had lower V(max) values and heat stabilities than PvSBE2. These results suggest that the N-terminal region of the kidney bean SBE is essential for maximum enzyme activity and thermostability.     

肿瘤特异性蛋白B7-H4纳米抗体的筛选和鉴定

羊驼体内存在天然缺少轻链的重链抗体,克隆重链抗体可变区(VHH),即可构建单域抗体(single-domain antibodies,sdAbs),又称纳米抗体(nanobody,Nb)。利用非免疫羊驼噬菌体文库筛选肿瘤特异性蛋白B7-H4的纳米抗体,经过4轮淘选,ELASE鉴定阳性克隆噬菌体,测序获得其DNA序列后体外转录为mRNA,将修饰纯化后的mRNA转染到肿瘤细胞,利用细胞免疫荧光检测mRNA在肿瘤细胞内是否表达,Western印迹进一步验证其表达情况;通过CCK-8法鉴定其对肿瘤细胞的增殖抑制能力;划痕实验鉴定其对肿瘤细胞迁移能力的影响;Transwell法鉴定其对肿瘤细胞的侵袭能力的影响;裸鼠荷瘤模型瘤旁注射mRNA,鉴定其在体内实验对肿瘤组织的作用。结果显示,通过淘选获得1个高亲和性的噬菌体株菌H6;DNA测序并导出的氨基酸序列符合羊驼纳米抗体结构;将其mRNA导入肿瘤细胞,能有效表达出纳米抗体H6;转染H6-mRNA的肿瘤细胞(0.84±0.08)与未转染H6-mRNA的对照组(1.83±0.04)相比,其增殖能力明显受到抑制,P<0.01,其迁移和侵袭能力(78.60±5.36)明显低于空白对照组(197.80±21.04),效果优于B7-H4 mRNA的siRNA(95.40±16.56);在裸鼠乳腺癌模型中能有效抑制肿瘤生长,效果优于紫杉醇和B7-H4 mRNA的siRNA。这说明筛选所得抗B7-H4纳米抗体H6能特异结合B7-H4蛋白并封闭其功能,导致肿瘤细胞的增殖、迁移和侵袭受到抑制。该结果为利用B7-H4作为治疗癌症的靶点提供了实验基础。     

Butyrate-induced reversal of dexamethasone resistance in autonomous rat Nb2 lymphoma cells

The parental rat Nb2 lymphoma is a prolactin (PRL)-dependent T cell line. Exposure of a PRL-independent subline, Nb2-SFJCD1, to sodium butyrate (NaBT) causes transient reversal of their growth factor-independent proliferation in association with constitutive expression of protooncogenes pim-1and c-myc. In the present study, we investigated the effect of NaBT treatment on the sensitivity of Nb2-SFJCD1 cells to dexamethasone (DEX)-induced apoptosis. Pretreatment with NaBT (2 mM, 72 h) partially reversed resistance to apoptosis in Nb2-SFJCD1 cells exposed to DEX (100 nM) for 12 h, assessed by flow cytometric analyses of DNA fragmentation. However, the cytolytic effect of DEX was abrogated by PRL i n a time- and concentration-dependent manner. Eval uati on of apoptosis-associated gene expression in NaBT-pre-treated cultures incubated with DEX or DEX+PRL indicated that the apoptosis resistance did not stem from altered bcl-2 or bax expression. However, there was a strong correlation between the resistance to DEX-activated apoptosis and their enhanced expression of pim-1 mRNA and protein. The results show that it is possible to reverse DEX-induced apoptosis of Nb2 pre-T cells and suggest the pim-1 gene product has an important role as a suppressor of this process, perhaps functioning as a mediator of PRL action. This revised version was published online in June 2006 with corrections to the Cover Date.     

Antibodies and protein misfolding: From structural research tools to therapeutic strategies

Protein misfolding disorders, including the neurodegenerative conditions Alzheimer's disease (AD) and Parkinson's disease (PD) represent one of the major medical challenges or our time. The underlying molecular mechanisms that govern protein misfolding and its links with disease are very complex processes, involving the formation of transiently populated but highly toxic molecular species within the crowded environment of the cell and tissue. Nevertheless, much progress has been made in understanding these events in recent years through innovative experiments and therapeutic strategies, and in this review we present an overview of the key roles of antibodies and antibody fragments in these endeavors. We discuss in particular how these species are being used in combination with a variety of powerful biochemical and biophysical methodologies, including a range of spectroscopic and microscopic techniques applied not just in vitro but also in situ and in vivo, both to gain a better understanding of the mechanistic nature of protein misfolding and aggregation and also to design novel therapeutic strategies to combat the family of diseases with which they are associated. This article is part of a Special Issue entitled: Recent advances in molecular engineering of antibody.     

PURIFICATION AND BIOLOGICAL CHARACTERIZATION OF BACTERIALLY EXPRESSED RECOMBINANT BUFFALO PROLACTIN

Recombinant prolactin (PRL) from water buffalo (Bubalus bubalis) has been cloned and expressed in a prokaryotic expression system. The hormone was also successfully refolded into a biologically active form. Total RNA was purified from buffalo pituitaries and the buPRL cDNA was synthesized using primers designed on bovine PRL sequence. This prolactin cDNA was cloned in a pET 28a vector and expressed in Escherichia coli strain BL21(DE3)pLysS. Most of the expressed protein was present as insoluble inclusion bodies. The inclusion bodies were solubilized and buPRL was purified by Ni-NTA column. The purified protein was refolded by gradually decreasing the concentration of denaturant during dialysis. Total yield of the refolded and soluble prolactin was 22 mg/L from 100 mL bacterial culture in LB medium. The recombinant prolactin was as active as native prolactin in stimulating growth of Nb2 lymphoma cells.     

纳米抗体筛选技术研究进展

纳米抗体(nanobody, Nb)是在骆驼科血清中发现的一种新型抗体,具有体积小、特异性强、稳定性高、易于表达和能识别隐藏的抗原表位等优势,在各个领域具有广泛的应用价值。本文介绍了纳米抗体筛选与优化过程,包括纳米抗体文库构建、体外展示和亲和力成熟3个重要技术阶段的分类与特点。其中,简要描述了天然、免疫及半合成/合成文库的制备方法与重要参数,并系统介绍了应用噬菌体、酵母、细菌、核糖体/mRNA和真核细胞等表面展示系统,以及酵母双杂交、高通量测序和质谱鉴定方法,共8种不同体外展示技术进行快速筛选的方法及其优缺点,汇总用于提升纳米抗体功能可靠性的体外及计算机辅助亲和力成熟技术平台,为综合运用各种技术手段快速获得稳定、可靠、特异的纳米抗体类药物或诊断制剂提供了参考。     

Inhibition of the proliferation of Nb2 cells by femtomolar concentrations of cholera toxin and partial reversal of the effect by 12-O-tetradecanoyl-phorbol-13-acetate

One hour of exposure to cholera toxin is sufficient to elicit a significant delay in the initiation of DNA synthesis and cell division in lactogenic hormone-dependent Nb2-11C lymphoma cells. The inhibitory effect occurs already at very low concentrations of cholera toxin (5-50 fM), at which it is not accompanied by a detectable increase in intracellular cAMP, or ADP-ribosylation of the alpha subunit of Gs, the stimulatory guanine nucleotide binding protein of adenylate cyclase; IBMX, the phosphodiesterase inhibitor, acts synergistically to cholera toxin, indicating that a minute increase in cAMP may be sufficient for the inhibition. This indication is substantiated by the finding that dibutyryl cAMP also inhibits cell proliferation. Phorbol diester reverses partially the inhibitory activity of cholera toxin. It is most likely that this effect does not result from blocking the increase in cAMP, but rather from some subsequent, yet unidentified, events. The inhibitory effect of cholera toxin is not dependent on the concentration of the proliferation-stimulating lactogenic hormone and cannot be abolished or reduced by excess of the hormone. Cholera toxin also inhibits the autonomous proliferation of a lactogenic hormone-independent cell line (Nb2-SP); however, in this case the inhibition is not affected by TPA.     

Mechanistic analysis of allosteric and non-allosteric effects arising from nanobody binding to two epitopes of the dihydrofolate reductase of Escherichia coli

Although allosteric effector antibodies are used widely as modulators of receptors and enzymes, experimental analysis of their mechanism remains highly challenging. Here, we investigate the molecular mechanisms of allosteric and non-allosteric effector antibodies in an experimentally tractable system, consisting of single-domain antibodies (nanobodies) that target the model enzyme dihydrofolate reductase (DHFR) from Escherichia coli. A panel of thirty-five nanobodies was isolated using several strategies to increase nanobody diversity. The nanobodies exhibit a variety of effector properties, including partial inhibition, strong inhibition and stimulation of DHFR activity. Despite these diverse effector properties, chemical shift perturbation NMR epitope mapping identified only two epitope regions: epitope α is a new allosteric site that is over 10 Å from the active site, while epitope β is located in the region of the Met20 loop. The structural basis for DHFR allosteric inhibition or activation upon nanobody binding to the α epitope was examined by solving the crystal structures of DHFR in complex with Nb113 (an allosteric inhibitor) and Nb179 (an allosteric activator). The structures suggest roles for conformational constraint and altered protein dynamics, but not epitope distortion, in the observed allosteric effects. The crystal structure of a β epitope region binder (ca1698) in complex with DHFR is also reported. Although CDR3 of ca1698 occupies the substrate binding site, ca1698 displays linear mixed inhibition kinetics instead of simple competitive inhibition kinetics. Two mechanisms are proposed to account for this apparent anomaly. Evidence for structural convergence of ca1698 and Nb216 during affinity maturation is also presented.     

Plasminogen activator in prostatic tumors of Nb rats

Using a fluorometric assay, nonspecific proteolytic activity and plasminogen activator were measured in transplantable tumors of the dorsal prostate of Nb rats. Nonspecific proteolytic activity in prostatic tumors did not differ significantly from that measured in normal dorsal prostate, whereas plasminogen activator activity, undetectable in the latter tissue, was readily measurable in the tumors. Furthermore, plasminogen activator in prostatic tumors characterized by hormone-insensitive growth was 8-fold higher than in tumors characterized by androgen-stimulated growth. In both types of tumors, the plasminogen activator activity per mg protein was highest in the lysosomal fractions. The result indicate that plasminogen activator may be a useful marker for discriminating between androgen-stimulated and autonomous prostatic tumors.