氨基酸酰胺类化合物的合成

阐述了氨基酸氨基保护的常用方法和试剂,氨基酸酰胺类化合物合成的基本原理和方法以及在合成中需要注意的问题。重点阐述了氨基酸酰胺类化合物的合成机理和合成方法。展望了氨基酸酰胺类衍生物的合成方向。     

非蛋白氨基酸的生物合成及其生物学作用

解释了蛋白氨基酸和非蛋白氨基酸,并着重论述了非蛋白氨基酸的生物合成及其生物学作用。非蛋白氨基酸的生物合成主要通过基本氨基酸合成后的修饰、代谢及消旋作用产生,其生物学作用主要表现在能合成其他含氮物质、储藏氮和运输氮、储能、组成细菌细胞壁、毒性作用及药物作用等方面。     

氨基酸Shiff碱金属配合物的研究进展

本文概述了近年来国内外在氨基酸Ｓｃｈｉｆｆ碱金属配合物的研究进展,简介了它们的合成方法和在金属离子分析、药物化学、生物模拟、氨基酸的合成及拆分上的应用 。     

苯环取代苯丙氨酸的合成及拆分

以苯胺类化合物为起始原料 ,经重氮化、丙烯酸加成、氨解等反应合成了 7种消旋苯环取代苯丙氨酸类氨基酸 ,并采用α 糜蛋白酶或枯草杆菌蛋白酶对所有氨基酸进行了拆分 ,其结构分别通过红外光谱、核磁共振、元素分析、熔点、旋光等分析得到确证。该法可以较大规模合成此类氨基酸。     

非天然氨基酸细胞工厂的构建与应用

非天然氨基酸在医药、农药、材料等领域得到广泛应用,其绿色、高效合成越来越受到关注.近年来,随着合成生物学的快速发展,微生物细胞工厂为非天然氨基酸的制造提供了重要手段.文中从合成途径的重构、关键酶的设计改造及与前体的协同调控、竞争性旁路途径的敲除、辅因子循环系统的构建等方面介绍了 一系列非天然氨基酸细胞工厂构建与应用的研...     

非天然氨基酸及非天然蛋白合成的研究进展

非天然氨基酸是天然氨基酸的衍生物,其具有重要的生理和药理功能.由非天然氨基酸合成的非天然蛋白同样具有特别的功能与活性.非天然氨基酸插入蛋白质中的研究为新型生物材料和蛋白质药物等的合成和应用提供了新的指导方向.基于此,本文综述了非天然氨基酸的生物合成方法,分析了非天然氨基酸生物合成目前存在的难点,总结了非天然氨基酸插入蛋...     

氨基酸生物合成抑制剂类除草剂作用机理及耐除草剂转基因植物研究进展

氨基酸是植物体内必不可少的物质,在植物的生长代谢中发挥着重要作用。与动物不同,植物的氨基酸供给全部靠自身来合成,一旦植物的氨基酸合成受阻,植物便难以继续生存。因此,植物氨基酸合成中的关键酶一直是新型除草剂研发中重要的靶标酶。在目前已经商品化的除草剂中,通过抑制植物氨基酸生物合成中的关键酶活性而发生作用的除草剂占很大比重;与此同时,随着植物转基因技术的不断发展完善,大批耐氨基酸生物合成抑制剂类除草剂转基因植物相继问世,成为了耐除草剂类转基因植物的主体。本文综述了常用的耐氨基酸生物合成抑制剂类除草剂、作用机理及耐除草剂转基因植物的研究进展。     

内消旋-二氨基庚二酸脱氢酶不对称合成非天然手性D-氨基酸的研究进展

内消旋-二氨基庚二酸脱氢酶不对称合成非天然的手性D-氨基酸是目前生物催化领域的研究热点。内消旋-二氨基庚二酸脱氢酶具有优良的立体选择性,利用其进行酶催化不对称合成光学纯的手性D-氨基酸,被广泛用于医药、食品、化妆品、精细化学品等领域。为了促进生物催化法在合成手性D-氨基酸方向的进一步发展,本文对内消旋-二氨基庚二酸脱氢酶催化合成D-氨基酸的现状进行了综述。重点介绍了Corynebacterium glutamicum、Ureibacillus thermosphaericus、Symbiobacterium thermophilum来源的内消旋-二氨基庚二酸脱氢酶在新酶的挖掘、催化性能、晶体结构解析、分子改造、功能与催化机制、合成D-氨基酸新途径等方面的研究进展,并对内消旋-二氨基庚二酸脱氢酶的未来研究方向及策略进行了展望。本综述将进一步加深人们对内消旋-二氨基庚二酸脱氢酶的认识,也为具有挑战性的生物合成任务提供信息借鉴。     

氨基酸脱氢酶的催化机理、分子改造及合成应用

氨基酸脱氢酶催化可逆的氨基酸氧化脱氨和酮酸的不对称还原胺化反应,热力学上反应平衡倾向于生成氨基酸方向,从原子经济学和对环境影响的角度来看,是具有极大优势的氨基酸合成方法之一。本文将主要阐述近年来在?-氨基酸脱氢酶催化机理、分子改造和合成应用方面的研究进展。     

β-氨基酸的电化学合成

<正> 一绪言α-氨基酸(以下简称为氨基酸)的合成研究的历史是很久的,甚至被认为与有机化学的诞生同步。早在1820年开始从蛋白质水解制取氨基酸。1850年在实验室内用化学方法合成了氨基酸。经过100多年感到一般的合成法已经用尽,直到1957年人们才找到新的方法:用微生物使糖类发酵直接生产谷氨酸,同时大大推动了其他氨基酸的发酵研究和生产的发展。氨基酸是食品和饲料中必需的组分。稻麦中主要缺乏苏氨酸和赖氨酸,如添加这些氨基酸就能提高营养价值。半胱氨酸具有抗辐射和治疗放射病的作用。天门冬氨基酸治疗心脏机     

Synthesis ofγ,δ-unsaturated amino acids via ester enolate Claisen rearrangement of chelated allylic esters

Summary Deprotonation ofN-protected amino acid allylic esters with LDA at –78°C and subsequent addition of a metal salt presumably results in the formation of a chelated metal enolate which undergoes Claisen rearrangement upon warming up to room temperature, giving rise to unsaturated amino acid. Many different metal salts can be used for chelation, but in general the best results are obtained with zinc chloride. Due to the fixed enolate geometry, as a result of chelate formation, and a strong preference for thechair like transition state, the rearrangement proceeds with a high degree of diastereoselectivity. This methodology can be applied to acyclic as well as to cyclic substrates, and even to peptides, and allows for the synthesis of amino acids containing quaternary carbon centers.     

植物对氨基酸的吸收及其生理效应

<正> 在古代的农业系统中,所用的肥料都是有机肥,人们并不知道植物依赖于何种物质得以生长繁衍。自1840年,德国化学家李比希(J.U.Liebig)发表了《化学在农业和植物生理学上应用》一书后,人们对植物的营养有了新的认识,认识到矿物质对植物的重要性。李比希在书中指出:“土壤中矿物质是一切绿色植物唯一的养料。植物可以完全依赖于无机物质而生长发育。这一观点即为“植物的矿质营养学说”。该学说后来为生产实践所充分证明,并成为农业化学     

Light directed massively parallel on-chip synthesis of peptide arrays with t-Boc chemistry

Peptide and peptidomimetic molecule arrays are emerging powerful tools for parallel screening of binding in proteomics and pharmaceutical discovery research. Up to now the common method of preparing peptide arrays was based on spotting on glass using a library of presynthesized peptides. However, due to the large number of monomers (amino acids) it is not possible to have combinatorial libraries which include all combinations of natural and synthetic amino acids. We describe a very flexible on-chip oligopeptide synthesis method which uses the well developed t-Boc based solid state synthesis chemistry. A very high degree of flexibility is achieved by using light photo generated acids and maskless projection lithography for spatially directed deprotection. Use of microfluidic chips enables moderately high densities, short reaction times and off-the-shelf chemicals. Examples are given from synthesis of metal ion binding peptides and epitope binding assays.     

A biomimetic approach towards synthesis of zinc oxide nanoparticles

Using natural processes as inspiration, the present study demonstrates a positive correlation between zinc metal tolerance ability of a soil fungus and its potential for the synthesis of zinc oxide (ZnO) nanoparticles. A total of 19 fungal cultures were isolated from the rhizospheric soils of plants naturally growing at a zinc mine area in India and identified on the genus, respectively the species level. Aspergillus aeneus isolate NJP12 has been shown to have a high zinc metal tolerance ability and a potential for extracellular synthesis of ZnO nanoparticles under ambient conditions. UV–visible spectroscopy, Fourier transform infrared spectroscopy, X-ray diffraction analysis, transmission electron microscopy, and energy dispersive spectroscopy studies further confirmed the crystallinity, morphology, and composition of synthesized ZnO nanoparticles. The results revealed the synthesis of spherical nanoparticles coated with protein molecules which served as stabilizing agents. Investigations on the role of fungal extracellular proteins in the synthesis of nanoparticles indicated that the process is nonenzymatic but involves amino acids present in the protein chains.     

Synthesis and characterization of metal binding pseudotripeptides.

Metal complexes with peptide or pseudopeptide type ligands can serve as good model compounds for a deeper understanding of enzymatic catalysis, but ligands with a high selectivity for different transition metal cations are hard to find due to the rather flexible nature of peptides. Since such ligands would be the sine qua non condition for the synthesis of heterodinuclear peptide metal complexes with catalytic activity, the search for small, affine and selective metal chelating sequences is of interest. Using four different amino acids (His, Lys, Asp, Glu) a set of 16 pseudotripeptides of the common structure Bz-AS1-Sar-AS2-NH2 has been synthesized, purified and characterized by mass spectrometry and 1H-NMR. Their ability to form metal complexes has been investigated leading to short motifs capable of selectively binding only one or two transition metal cations with high affinity. As expected, the complexation of transition metal cations by pseudotripeptides is strongly dependent not only on the amino acid composition, but also on the sequence with regard to the stability of the resulting complexes, as well as the selectivity of the ligands towards Cu2+, Co2+, Ni2+, Zn2+ and Mn2+.     

Ternary complexes of palladium (II) with levamisole and L-amino acids

The complexes of general formula [(LMS)2Pd(amino acid)]Cl with LMS = levamisole, and amino acid = L-alanine, L-phenylglycine, L-phenylalanine, L-valine, L-methionine, and L-proline, were synthesized by the interaction of [(LMS)2PdCl2] with the sodium salts of L-amino acids. The newly synthesized complexes are characterized by elemental analysis, conductivity, magnetic susceptibility, optical rotation measurements, and UV-Vis, IR and 13C NMR spectral data. Levamisole is coordinated to palladium via the N-7 nitrogen and the amino acids through the amino nitrogen and carboxylate oxygen, except for L-methionine which binds the metal via nitrogen and sulfur atoms. Optically active [(LMS)2Pd(amino acid)]Cl complexes are obtained when L-amino acids or D,L-amino acids are used for the synthesis of these complexes. L-Methionine and L-proline complexes induce new cell forms in Baker's yeast (Saccharomyces cerevisiae) cells.     

Conjugation of DOTA-like chelating agents to peptides and radiolabeling with trivalent metallic isotopes

Peptides can be labeled with various trivalent radiometals for imaging or targeted radionuclide-therapy applications. The peptide is first conjugated to a chelating agent that is able to form stable complexes with the radionuclide of interest. This conjugation step can be carried out as part of the solid-phase peptide synthesis, or it can be undertaken in the solution phase after synthesis and purification of the peptide. The latter route, described here, involves reacting a molar excess of the activated tri-tert-butyl ester-derivatized chelator with a designated free amino group of a peptide analog, in which all other reactive amines are protected, in the presence of a coupling agent. The conjugate molecule is then purified prior to deprotection and further purification by HPLC. The product can be radiolabeled by addition of a suitable metal salt, followed, if necessary, by removal of the unchelated metal. The entire process of conjugation, purification and radiolabeling should take approximately 12.5 h.     

The interplay between inorganic phosphate and amino acids determines zinc solubility in brain slices

Inorganic phosphate (Pi) is an important polyanion needed for ATP synthesis and bone formation. As it is found at millimolar levels in plasma, it is usually incorporated as a constituent of artificial CSF formulations for maintaining brain slices. In this paper, we show that Pi limits the extracellular zinc concentration by inducing metal precipitation. We present data suggesting that amino acids like histidine may counteract the Pi-induced zinc precipitation by the formation of soluble zinc complexes. We propose that the interplay between Pi and amino acids in the extracellular space may influence the availability of metals for cellular uptake.     

Synthesis and application of an Nδ-acetyl-Nδ-hydroxyornithine analog: identification of novel metal complexes of deferriferrichrysin

Synthesis of Fmoc-protected N(δ)-acetyl-N(δ)-(tert-butoxy)-l-ornithine has revealed it to be a metal-chelating amino-acid precursor. This protected amino acid was compatible with the preparation of ferrichrome peptides by standard Fmoc-based solid-phase peptide synthesis. Evaluation of deferriferrichrysin for metal ion chelation revealed that zirconium(IV) and titanium(IV) formed complexes with deferriferrichrysin.