一种重组抗胰蛋白酶单体人胰岛素突变体的设计、制备和鉴定

用缺口双链DNA的定向突变方法分别将胰岛素前体中B链第 2 2、2 8、2 9和 3 0位改变为Asp、Lys、Pro和Lys,酵母分泌表达的前体经胰蛋白酶直接酶切 ,得到重组 [B2 2Asp、B2 8Lys、B2 9Pro、B3 0Lys]人胰岛素。它与受体的结合能力约为猪胰岛素的 6% ,而体内生物活力保留 5 0 %。通过FPLC分子筛测定其自身结合能力 ,在生理条件下浓度达 10 -4mol/L时它以单体形式存在。作为可抗胰蛋白酶酶解的单体胰岛素类似物 ,它可能具有一定的应用前景     

[B10,22-Asp,B25-Tyr-NH2]-去β链C端五肽胰岛素的合成和性质

本文报道了[B10,22-Asp,B25-Tyr-NH2]-去B链羧端五肽胰岛素的制备及其生物活性。结果表明,这一类似物的生物活力比去五肽胰岛素(DPI)的活力高一倍,但却比Gerald所报道的[B10-Asp,B25-Tyr-NH_2]-DPI的活力低很多,说明后者的高活性可能依赖于分子中B22-Arg的存在。     

重组单链胰岛素的连接肽与其生物功能的关系

为研究重组单链胰岛素的生物活性与连接肽之间的关系,用基因定点突变的方法分别以二肽A-K,七肽A-A-A-A-A-A-K和十二肽A-A-A-A-A-A-A-A-A-A-A-K连接胰岛素的B30和A1,得到3个单链胰岛素分子PIP,[A]₅PIP和[A]₁₀PIP.它们的受体结合能力分别为胰岛素的0.14%, 14.3% 和11.1%, 体内生物活性与受体结合能力一致,而它们的促生长活性分别为胰岛素的17%,116.3%和38%.结果表明:(ⅰ)单链胰岛素也具有胰岛素的促代谢和促生长功能;(ⅱ)单链胰岛素与胰岛素受体的结合能力与连接肽的长度和氨基酸组成密切相关, 其受体结合能力随连接肽的改变,可由无到100%,进一步说明胰岛素与其受体结合时,B链C端远离A链N端是必需的;(ⅲ)单链胰岛素的促细胞生长能力也与连接肽长度和组成密切相关,且比其自身的促代谢能力强.     

胰岛素蛋白质工程: [B16Ala]胰岛素和[B26Ala]胰岛素——两个新型的速效人胰岛素

用大动物(猪)降血糖实验证明[B16Ala]胰岛素和[B26Ala]胰岛素是快速降血糖胰岛素. 它们的前体[B16Ala]PIP和[B26Ala]PIP, 在甲醇酵母体系中的分泌表达量分别为650和130 mg/L. 由于它们是新型的分别保留全部和几乎全部胰岛素体内生物活力的速效胰岛素, 且在甲醇酵母表达体系中得到比较高的表达量, 所以具有很好的临床应用前景.     

猪B_0L-丙氨酰胰岛素和猪B_1L-亮氨酰胰岛素的制备及性质研究

 猪胰岛素经与MSC·ONsu选择性反应,得到[MSC]A_(21)B_(29)胰岛素,再与BOC-L-Ala·TTT缩合,去保护后得到[L-Ala]B_0胰岛素,将得到的[MSC]A_(21)B_(29)胰岛素经Edman降解,再与BOC-L-Leu·TTT缩合、去保护后得到[L-Leu]B_1胰岛素。样品经N-末端分析,醋酸纤维素薄膜电泳、氨基酸组成分析和紫外吸收光谱鉴定,确定它们分别为均一的[L-Ala]B_0胰岛素和[L-Leu]B_1胰岛素。放射免疫法分析[L-Al_a]B_0肽岛素和[L-Leu]B_1胰岛素的免疫活性分别相当于天然胰岛素的30％和47％,小鼠惊厥法分析表明[L-Ala]B_6胰岛素与[L-Leu]B_1胰岛素的生物活力为19.7国际单位/mg和19.1国际单位/mg,相当于天然胰岛素的76％和73％。     

一种人胰岛素类似物的制备、鉴定与活性研究

采用PCR方法,将人胰岛素分子B链B10位His突变为Glu,在B25和B26位之间插入Glu,构建了［B10 Glu,B25-Glu-B26］胰岛素原融合蛋白基因.利用通用型质粒pBV220构建表达载体,在大肠杆菌DH5α中表达,表达蛋白为包含体形式,约占菌体总蛋白的20%～30%.经过复性、凝胶过滤等步骤得到胰岛素原融合蛋白.用胰蛋白酶和羧肽酶B酶切,经过DEAE离子交换和RP-HPLC纯化得到胰岛素突变体类似物,并经过质谱测定鉴定.凝胶过滤法测定了蛋白质分子自身的缔合性质,圆二色谱（CD）测定了构象的变化.并分别测定了放免活性、受体结合活性及小白鼠低血糖惊厥实验.结果表明,突变体分子缔合性明显下降.放免活性和受体结合活性分别约为标准胰岛素的63.5%和114.4%, 整体活力略高于天然胰岛素.     

Insulin and insulin mutants stimulate glucose uptake in rat adipocytes

A simple method to determine the in vitro biological activity of insulin by measuring glucose uptake in the rat adipocytes is presented here. In the presence of insulin, the glucose uptake is 5-6 times more than the basal control. And the uptake of D-[3-3H]-glucose is linear as the logarithm of insulin concentration from 0.2 μg/L to 1.0 μg/L. Glucose and 3-O-methyl-glucose inhibit D-[3-3H]-glucose uptake into adipocytes. By this method, the in vitro biological activity of [B2-Lys]-insulin and [B3-Lys]-insulin was measured to be 61.6% and 154% respectively, relative to that of insulin.     

胰岛素受体家族的结构与功能研究

胰岛素（insulin）与胰岛素样生长因子-1（IGF-1）分别是由胰岛β细胞和肝细胞分泌的 多肽类激素.它们通过结合并激活位于细胞膜上的受体酪氨酸激酶(RTKs),发挥重要的生理作用. 作为起始信号传导的第一步,胰岛素与IGF-1是如何与各自受体的膜外区域（ectodomain） 结合并进一步激活受体的细胞膜内酪氨酸激酶活性一直属于科学研究的关键基础问题.本文 概述了胰岛素受体家族（IR和IGF-1R）及其配体的结构与功能的特点和关系,并重点介绍 了近年来国内外在胰岛素受体家族复合体结构和功能上的研究手段和取得的突破性进展.     

TyrB26位点改变的人类胰岛素类似物的化学合成与体外活性

摘要：为了研究人类胰岛素B链第26位的酪氨酸对胰岛素和受体之间的结合的影响,包括单独的氨基酸替换或化合物替换的不同的胰岛素类似物被合成,其中化合物替代的类似物的B链C末端都减少了4个氨基酸。在对它们与胰岛素受体的亲和力进行研究中,结果发现它们与胰岛素受体的亲和力没有丢失, HisB26类似物和N-MeHisB26类似物的结合能力与胰岛素相比改变不大,分别是胰岛素的72 %和107 %。N-MeGluB26类似物,AadB26类似物和Phe (4-carboxy) B26类似物的结合能力有很大的提高,分别是130 %, 234 %和160 %。     

胰岛素信号转导障碍与胰岛素抵抗的形成

胰岛素生理作用的发挥,起始于胰岛素与其受体的结合,并由此引起细胞内一系列信号转导,最终到达各效应器产生各种生理效应。胰岛素信号转导在胰岛素生理作用的发挥中起着至关重要的作用。胰岛素信号转导减弱或受阻,使得胰岛素生理作用减弱,导致胰岛素抵抗形成。本文综述了胰岛素信号转导失调在胰岛素抵抗形成中的作用。     

高受体结合和低免疫原性的［B1—Ala，B2—Ala］－胰岛素

通过化学半合成从天然猪胰岛素得到［Ｂ１－Ａｌａ,Ｂ２－Ａｌａ］胰岛素。这一胰岛素类似物经聚丙烯酰胺凝胶电泳和ＨＰＬＣ鉴定证明是均一的,氨基酸组成与理论值相符生物活性测定结果表明：［Ｂ１－Ａｌａ,Ｂ２－Ａｌａ］－胰岛素的体内活力与天然猪胰岛素相同,而与人胎盘细胞膜胰岛素受体的结合能力为天然猪胰岛素的１３２％。这一结果进一步说明胰岛素Ｂ链Ｎ端肽段参子与受体相互作用。此外,［Ｂ１－Ａｌａ,Ｂ２－Ａｌａ］－胰岛素的免疫活性很低,远小于天然猪胰岛素的４％。     

Receptor binding and biological activity of [SerB24]-insulin, an abnormal mutant insulin

[SerB24]-insulin, the second structurally abnormal mutant insulin, and [SerB25]-insulin were semisynthesized and were studied for receptor binding and biological activity. Receptor binding and biological activity determined by its ability to increase 2-deoxy-glucose uptake in rat adipocytes were 0.7-3% of native insulin for [SerB24]-insulin and 3-8% for [SerB25]-insulin. Negative cooperative effect of these analogues was also markedly decreased. Immunoreactivity of [SerB24]-insulin was decreased whereas that of [SerB25]-insulin was normal. Markedly decreased receptor binding of [SerB24]-insulin appeared to be due to substitution of hydrophobic amino acid, Phe, with a polar amino acid, Ser, at B24.     

Supernormal insulin: [D-PheB24]-insulin with increased affinity for insulin receptors

[D-Phe^B24]- and [D-Phe^B25]-human insulin were semisynthesized from porcine insulin by enzyme assisted coupling method. Receptor binding ability of [D-Phe^B24]- and [D-Phe^B25]-insulin was 180% and 4%, respectively, of that of human insulin. Increased affinity of [D-Phe^B24]-insulin was ascribed to markedly decreased dissociation rate in binding to human cultured lymphocytes. Negative cooperative effect of [D-Phe^B24]insulin was also increased to twice of that of human insulin. Biological activity of these analogues was assessed by 2-deoxy-glucose uptake studies in isolated adipocytes and the ability of [D-Phe^B24]- and [D-Phe^B25]-insulin was 140% and 4%, respectively, of that of human insulin. These findings suggest that B25 L-Phe is more crucial for receptor binding and that [D-Phe^B24]-insulin is the first semisynthetic insulin to show increased affinity for insulin receptors.     

Insulin analogues with modifications at position B26. Divergence of binding affinity and biological activity

In this study, we prepared several shortened and full-length insulin analogues with substitutions at position B26. We compared the binding affinities of the analogues for rat adipose membranes with their ability to lower the plasma glucose level in nondiabetic Wistar rats in vivo after subcutaneous administration, and also with their ability to stimulate lipogenesis in vitro. We found that [NMeHisB26]-DTI-NH 2 and [NMeAlaB26]-DTI-NH 2 were very potent insulin analogues with respect to their binding affinities (214 and 465%, respectively, compared to that of human insulin), but they were significantly less potent than human insulin in vivo. Their full-length counterparts, [NMeHisB26]-insulin and [NMeAlaB26]-insulin, were less effective than human insulin with respect to binding affinity (10 and 21%, respectively) and in vivo activity, while [HisB26]-insulin exhibited properties similar to those of human insulin in all of the tests we carried out. The ability of selected analogues to stimulate lipogenesis in adipocytes was correlated with their biological potency in vivo. Taken together, our data suggest that the B26 residue and residues B26-B30 have ambiguous roles in binding affinity and in vivo activity. We hypothesize that our shortened analogues, [NMeHisB26]-DTI-NH 2 and [NMeAlaB26]-DTI-NH 2, have different modes of interaction with the insulin receptor compared with natural insulin and that these different modes of interaction result in a less effective metabolic response of the insulin receptor, despite the high binding potency of these analogues.     

Structural and Functional Study of the GlnB22-Insulin Mutant Responsible for Maturity-Onset Diabetes of the Young

The insulin gene mutation c.137G>A (R46Q), which changes an arginine at the B22 position of the mature hormone to glutamine, causes the monogenic diabetes variant maturity-onset diabetes of the young (MODY). In MODY patients, this mutation is heterozygous, and both mutant and wild-type (WT) human insulin are produced simultaneously. However, the patients often depend on administration of exogenous insulin. In this study, we chemically synthesized the MODY mutant [GlnB22]-insulin and characterized its biological and structural properties. The chemical synthesis of this insulin analogue revealed that its folding ability is severely impaired. In vitro and in vivo tests showed that its binding affinity and biological activity are reduced (both approximately 20% that of human insulin). Comparison of the solution structure of [GlnB22]-insulin with the solution structure of native human insulin revealed that the most significant structural effect of the mutation is distortion of the B20-B23 β-turn, leading to liberation of the B chain C-terminus from the protein core. The distortion of the B20-B23 β-turn is caused by the extended conformational freedom of the GlnB22 side chain, which is no longer anchored in a hydrogen bonding network like the native ArgB22. The partially disordered [GlnB22]-insulin structure appears to be one reason for the reduced binding potency of this mutant and may also be responsible for its low folding efficiency in vivo. The altered orientation and flexibility of the B20-B23 β-turn may interfere with the formation of disulfide bonds in proinsulin bearing the R46Q (GlnB22) mutation. This may also have a negative effect on the WT proinsulin simultaneously biosynthesized in β-cells and therefore play a major role in the development of MODY in patients producing [GlnB22]-insulin.     

Hydrolysis of monomolecular layers of synthetic sphingomyelins by sphingomyelinase of Staphylococcus aureus.

Human [LeuB-24]- and [LeuB-25]-insulins were semi-synthesized from porcine insulin by an enzyme-assisted coupling method. The receptor-binding ability of [LeuB-24]- and [LeuB-25]-insulins was 30--48% and 2--5% respectively of that of human insulin. There was no significant difference in degradation between human insulin and these analogues on incubation with isolated adipocytes. The decreased affinity of these analogues was due to an increased dissociation rate rather than a change in the association rate of their binding to human cultured lymphocytes. The negative co-operative effect of [LeuB-24]- and [LeuB-25]-insulin was decreased to 50 and 1% respectively of that of human insulin at a concentration of 100 ng/ml. The ability of [LeuB-24]- and [LeuB-25]-insulin to stimulate 2-deoxyglucose uptake in isolated rat adipocytes was 35 and 4% respectively of that of human insulin. These analogues did not have an antagonistic effect on the biological activity of human insulin. The immunoreactivity of [LeuB-25]insulin was similar to that of porcine or human insulin, whereas [LeuB-24]insulin demonstrated decreased binding to anti-(porcine insulin) antibodies. These findings suggest that B-chain phenylalanine-25 residue is more crucial for receptor binding and negative co-operativity, whereas the B-chain phenylalanine-24 residue may play a more important role in binding to anti-insulin antibody.     

Non-equivalent role of inter- and intramolecular hydrogen bonds in the insulin dimer interface

Apart from its role in insulin receptor (IR) activation, the C terminus of the B-chain of insulin is also responsible for the formation of insulin dimers. The dimerization of insulin plays an important role in the endogenous delivery of the hormone and in the administration of insulin to patients. Here, we investigated insulin analogues with selective N-methylations of peptide bond amides at positions B24, B25, or B26 to delineate their structural and functional contribution to the dimer interface. All N-methylated analogues showed impaired binding affinities to IR, which suggests a direct IR-interacting role for the respective amide hydrogens. The dimerization capabilities of analogues were investigated by isothermal microcalorimetry. Selective N-methylations of B24, B25, or B26 amides resulted in reduced dimerization abilities compared with native insulin (K(d) = 8.8 μM). Interestingly, although the N-methylation in [NMeTyrB26]-insulin or [NMePheB24]-insulin resulted in K(d) values of 142 and 587 μM, respectively, the [NMePheB25]-insulin did not form dimers even at high concentrations. This effect may be attributed to the loss of intramolecular hydrogen bonding between NHB25 and COA19, which connects the B-chain β-strand to the core of the molecule. The release of the B-chain β-strand from this hydrogen bond lock may result in its higher mobility, thereby shifting solution equilibrium toward the monomeric state of the hormone. The study was complemented by analyses of two novel analogue crystal structures. All examined analogues crystallized only in the most stable R(6) form of insulin oligomers (even if the dimer interface was totally disrupted), confirming the role of R(6)-specific intra/intermolecular interactions for hexamer stability.     

Radioautographic and quantitative study of insulin binding sites in the rat brain

In the present study, we describe the specificity and the autoradiographic distribution of insulin binding sites in the rat central nervous system (CNS) after in vitro incubation of brain sections with [125I]-14A insulin. Increasing concentrations of unlabeled insulin produced a dose-dependent inhibition of [125I]-insulin binding which represented 92 +/- 2% displacement with 3 X 10(-5) M, whatever the brain sections tested. Half-maximum inhibition with native insulin was obtained with 2.2 X 10(-9) M, with 10(-7) M proinsulin whereas glucagon had no effect. Under our experimental conditions, no degradation of [125I]-insulin was observed. Autoradiograms obtained by apposition of LKB 3H-Ultrofilm showed a widespread distribution of [125I]-insulin in rat CNS. However, quantitative analysis of the autoradiograms with 10(-10) M of labeled insulin, showed a high number of [125I]-insulin binding sites in the choroid plexus, olfactory areas, in both cerebral and cerebellar cortices, the amygdaloid complex and in the septum. In the hippocampal formation, the dorsal dentate gyrus and various subfields of CA1, CA2 and CA3 were labeled. Moreover, arcuate, dorso- and ventromedial nuclei of the hypothalamus contained high concentrations of [125I]-insulin whereas a low density was observed in the mesencephalon. The metabolic role of insulin in the CNS is supported by the large distribution of insulin binding sites in the rat brain. However, the presence of high affinity binding sites in selective areas involved in perception and integrative processes as well as in the regulation of both feeding behavior and neuroendocrine functions, suggests a neuromodulatory role of insulin in the brain.     

Semisynthetic des-(B27-B30)-insulins with modified B26-tyrosine

Semisynthetic des-(B27-B30)-insulins containing modified B26-tyrosine residues were prepared to refine the understanding of the importance of position B26 with regard to biological and structural properties of the hormone. The following shortened insulin analogues were synthesized by trypsin-catalysed peptide-bond formation between the C-terminal amino acid ArgB22 of des-(B23-B30)-insulin and synthetic tetrapeptides as amino components: des-(B27-B30)-insulin, des-(B27-B30)-insulin-B26-methyl ester, -B26-carboxamide with varying C-terminal hydrophobicity of the B-chain, and [Tyr(NH2)B26]-, [Tyr(NO2)B26]-, [Tyr(I2)B26]-, [D-TyrB26]des-(B27-B30)-insulin-B26-carboxamide containing non-proteinogenic amino acids in position B26. Starting from insulin and an excess of synthetic Gly-Phe-Phe-Tyr-OMe as nucleophile, des-(B27-B30)-insulin-B26-methyl ester--the formal transpeptidation product at ArgB22--was formed in one step. Biological in vitro properties (binding to cultured human IM-9 lymphocytes, relative lipogenic potency in isolated rat adipocytes) of all semisynthetic analogues are reported, ranging from slightly decreased to two-fold receptor affinity and nearly three-fold biopotency relative to insulin. If the C-terminal tetrapeptide B27-B30 is removed, full relative insulin activity is still preserved, while the shortening results in the loss of ability to associate in solution. Only after carboxamidation or methyl esterification of TyrB26 the self-association typical of native insulin can be observed, and the CD-spectral effects in the near UV spectrum related to association and hexamerization of the native hormone are qualitatively reestablished. The results of this investigation underline the importance of position B26 to the modulation of hormonal properties and solution structure of the shortened insulins.