固相多肽合成中王树脂和Fmoc/tBu酪氨酸成酯反应的研究

以Fmoc/tBu酪氨酸和王树脂为原料,分别探讨了对称酸酐法、活化酯法和2,6-二氯苯甲酰氯(DCB)法中各种因素对氨基酸与树脂成酯反应的影响。实验表明:对称酸酐法连接率低,而其它两种方法,通过筛选合适的反应介质,均能取得良好结果。在活化酯法中,使用强极性溶剂DMA,弱极性溶剂THF/DCM和混合溶剂45%DMF/THF,反应5h,连接率均可提高到90%以上;在DCB法中,使用弱极性溶剂THF时,反应3h,连接率可达99%。总之,DCB方法是酪氨酸和王树脂成酯反应的最好方法。     

N-(5-氯-2-羟苄基)氨基酸酯的合成、表征及抑菌活性

以5-Cl水杨醛和L-苯丙氨酸、L-亮氨酸及L-甘氨酸的脂肪酸酯为原料,通过碱催化的席夫碱缩合反应,合成了6种N-(5-氯-2-羟苄基)席夫碱氨基酸酯及其还原产物N-(5-氯-2-羟苄基)氨基酸酯。化合物的结构及组成经过IR、1HNMR和元素分析测试技术进行了表征。合成的席夫碱及其还原产物对革兰氏阴性菌、革兰氏阳性菌及真菌均有不同程度的抑制作用。质量分数为0.01%的N-(5-氯-2-羟苄基)席夫碱氨基酸酯对大肠杆菌的抑菌率达90%以上,而N-(5-氯-2-羟苄基)氨基酸酯对金黄色葡萄球菌的抑菌率也在90%以上,均为强抑菌活性,其中N-(5-氯-2-羟苄基)苯丙氨酸酯的抑菌率达98%以上。     

双环戊二烯苯酚树脂的合成新工艺

以双环戊二烯（DCPD）和苯酚为原料,甲磺酸为催化剂,合成了双环戊二烯苯酚树脂。适宜工艺条件:苯酚与DCPD摩尔比为5、反应温度120 ℃、反应时间5 h、催化剂质量分数为1.5%,收率89%。所得的双环戊二烯苯酚树脂（DPR）经催化加氢法在H2气压力1.5 MPa、催化剂Pd/Al2O3用量为原料质量分数的0.5%、反应温度80 ℃条件下对树脂进行脱色处理。 得到浅黄色双环戊二烯苯酚树脂,收率89%,经IR和1H NMR表征分析其为目的产物,产物指标达到国际同类产品的质量标准。     

碳酸酯把手改构Wang树脂及其性能

基于碳酸酯结构易于亲核脱除的原理, 使用氯甲酸氯甲酯改构Wang树脂, 并探究了改构树脂与首位氨基酸的缩合效率. 实验结果表明, 改构后的Wang树脂与20种Fmoc保护氨基酸均能达到70%以上的缩合效率; 且对于带有较大侧链基团的Fmoc保护氨基酸, 通过降低树脂取代度或延长反应时间可提高其连接率. 为了验证改构后的碳酸酯型树脂在裂解时侧链未受到影响, 设计合成了3种模型肽, 并用温和裂解剂3-吡啶甲醛肟铯盐进行裂解. 实验结果表明, 利用改构树脂能得到侧链全保护的肽片段, 可初步应用到长链困难肽的合成中.     

N-(5-氯-2-羟苯基)氨基酸酯的合成、表征及抑菌活性

以5-Cl水杨醛和L-苯丙氨酸、L-亮氨酸及L-甘氨酸的脂肪酸酯为原料,通过碱催化的席夫碱缩合反应,合成了6种N-（5-氯-2-羟苄基）席夫碱氨基酸酯及其还原产物N-（5-氯-2-羟苄基）氨基酸酯。 化合物的结构及组成经过IR、¹H NMR和元素分析测试技术进行了表征。 合成的席夫碱及其还原产物对革兰氏阴性菌、革兰氏阳性菌及真菌均有不同程度的抑制作用。 质量分数为0.01%的N-（5-氯-2-羟苄基）席夫碱氨基酸酯对大肠杆菌的抑菌率达90%以上,而N-（5-氯-2-羟苄基）氨基酸酯对金黄色葡萄球菌的抑菌率也在90%以上,均为强抑菌活性,其中N-（5-氯-2-羟苄基）苯丙氨酸酯的抑菌率达98%以上。     

牛磺酸和甘氨酸在D290树脂上的离子交换平衡

研究了牛磺酸与甘氨酸在阴离子树脂D290上的离子交换平衡.采用静态法分别进行牛磺酸/氢氧根/D290树脂和甘氨酸/氢氧根/D290树脂体系的离子交换平衡实验并测定等温线;在不同的离子强度下进行了牛磺酸/甘氨酸/氢氧根/D290阴离子交换树脂体系的离子交换平衡实验,测定牛磺酸和甘氨酸在碱性条件下的竞争交换平衡等温线.实验结果表明,牛磺酸在D290阴离子交换树脂上的交换量大于甘氨酸的交换量,阴离子交换树脂对牛磺酸和甘氨酸的选择性系数分别为STau-,OH-=2.55,SGly-,OH-=1.65.在牛磺酸/甘氨酸/氢氧根/D290树脂体系中,D290树脂对牛磺酸/甘氨酸/氢氧根3种离子的选择性从高到底顺序是:牛磺酸＞甘氨酸＞氢氧根.树脂对牛磺酸的选择性要大于对甘氨酸的选择性.随着溶液中离子强度的增大,树脂对牛磺酸与甘氨酸之间的选择性下降.     

原位酸树脂催化合成丙烯酸高碳烷基酯

以原位酸树脂为催化剂合成了丙烯酸高碳烷基酯。探讨了酸醇摩尔比、催化剂用量、阻聚剂对苯二酚用量、反应温度、反应时间等对反应产物收率的影响。结果表明,高碳烷基醇与丙烯酸摩尔比1:1.2,催化剂和阻聚剂用量分别为高碳烷基醇质量的5.0%和0.8%,反应温度为140℃,反应时间为6h,产物收率为90.0%～97.0%,产物纯度为92.00%～98.00%。催化剂经甲醇活化,循环使用5次后产品收率为75.0%。该研究为丙烯酸高碳烷基酯的合成提供了一种新的方法。     

相转移催化法和手性催化加氢法立体选择性地合成Fmoc保护的(S)-3,5-二溴苯丙氨酸

通过两种不对称催化方法合成了(S)-3,5-二溴苯丙氨酸.一种方法是以二苯亚胺甘氨酸叔丁酯和3,5-二溴苄基溴为底物,在O-烯丙基-N-9-蒽甲基溴化辛可宁定催化下,经不对称烷基化反应得到了(S)-3,5-二溴苯丙氨酸的衍生物,ee值达到94.9%,重点优化了不对称相转移催化烷基化反应的条件,得到了最优反应条件.另一种方法是以2-乙酰胺基-3-(3,5-二溴苯基)丙烯酸为底物,在双(1,5-环辛二烯)-三氟甲磺酸铑(I)和(R)-N-二苯基膦-N-甲基-(S)-2-(二苯基膦)二茂铁基乙胺催化下加氢得到乙酰基保护的(S)-3,5-二溴苯丙氨酸,再进行水解反应,最终得到(S)-3,5-二溴苯丙氨酸.经Fmoc的保护,得到Fmoc保护的(S)-3,5-二溴苯丙氨酸,ee值达到94.7%.所述两种方法中,第一种方法产率较高,对映选择性也较高,适合应用于其他手性二卤代苯丙氨酸的合成.     

手性催化剂环二肽类化合物的微波合成

以L-苯丙氨酸或L-亮氨酸为起始原料,经过氨基保护和羧基酯化得到N-苄氧羰基-L-广苯丙氨酸-对硝基苯酯(4a)或N-苄氧羰基-L-亮氨酸-对硝基苯酯(4b);4在三乙胺作用下与L-组氨酸甲酯盐酸盐缩合得到直链二肽N-苄氧羰基-L-苯丙氨酸-L-组氨酸甲酯(5a)或N-苄氧羰基-L-亮氨酸-L-组氨酸甲酯(5b);Pd/C催化5脱掉保护基后在微波辐射下,经环化反应合成了手性催化剂环二肽(6a或6b),其结构经1H NMR和IR表征.重点考察了由5合成6的反应条件.结果表明,以甲醇为溶剂,于65 W辐射120 min,6a和6b的产率分别达到90%和68%.     

新型光控保护基(2-重氮基-3-苯基-4H-磺酰基苯并噻喃)在氨基酸保护-光控脱保护反应中的应用

将新型磷酸基光控保护基(2-重氮基-3-苯基-4H-磺酰基苯并噻喃,PPG)应用于氨基酸［甘氨酸(1a), L 丙氨酸(1b), L 苯丙氨酸(1c)和L-脯氨酸(1d)］的保护 光控脱保护反应。产物结构经¹H NMR, ¹³C NMR和HR-FAB MS表征。研究了物料比r［n(PPG) : n(1a)］,催化剂和反应温度对2a收率的影响。结果表明：在最佳反应条件［1a 0.1 mmol, r=1.25,于室温反应65 h］下,2a收率80%。FL监测光控脱保护反应表明：反应在15 min内完成。     

1,3,5-Tri- and 1,3,4,5-tetra-substituted 1,4-diazepin-2-one solid-phase synthesis

Solid-phase syntheses of 1,3,5-tri-substituted and 1,3,4,5-tetra-substituted 1,4-diazepin-2-ones 15-18 have been accomplished by employing inexpensive commercially available alpha- and beta-amino acids on Wang resin. Reductive amination of the imine formed by condensation of Wang aldehyde resin respectively with beta-alaninate 2 and beta-homophenylalaninate 3, followed by aminoacylation with a set of alpha-N-Boc amino acids (Phe epsilon-( Z)-Lys, and Leu) gave tertiary amide resins 7 and 8. Exposure of resins 7 and 8 to an excess of vinyl magnesium bromide in the presence of copper cyanide gave the corresponding gamma,delta-unsaturated ketone resins 9 and 10 by way of a cascade addition. Diazepinones were made by Boc deprotection and intramolecular reductive amination. To diversify the heterocycle, N-alkylation was performed using a series of alkyl halides. Alternatively, diazepinones 15e-g were obtained from treatment of methyl beta-alaninate resins 4 and 20 under similar copper-catalyzed cascade conditions to afford the gamma,delta-unsaturated ketone 21, which was acylated using alpha-N-Fmoc-amino acids (Phe, Trp, gamma-(t-Bu)-Glu). Formation of diazepinones 15 followed a similar protocol, after Fmoc removal with piperidine. Cleavage of the heterocycles with TFA/TES 95:5 gave the N1-p-hydroxybenzyl diazepinones 15-18 in overall isolated yields from 6 to 24% after purification in purities ranging from 81 to 100% according to LCMS analysis.     

2-聚苯乙烯磺酰基乙醇树脂的合成及其在海因和脲固相成中的应用

合成了一种新型的聚合物载体—2-聚苯乙烯磺酰基乙醇，并研究其在固相有机合成中应用，聚苯乙烯亚磺酸钠树脂（1）在相转移催化剂BU4NI和助催化KI的作用下，与氯乙进行砜化反应，得到含羟基功能基的2-聚苯乙烯磺酰基乙醇树脂2。树脂2用Boc保护的氨基酯化，封闭树脂上未反应的羟基，用酸脱保护并用三乙胺中和，再与异（硫）氰酸苯酯反应生成聚合生物支载的脲树脂6树脂6用酸解脱得到海因和硫代海因化合物，用碱处理树脂6是得到取代的脲和硫脲，优化了合成反应的全过程，探讨了树脂在酸性和碱性条件下的解脱方法，结果表明，2-聚苯乙烯磺酰基乙醇树脂易与羧基形成含酯键的连接桥，连接桥在强酸性和碱性条件下均可解脱得到产物。     

Enantioselective Solid‐Phase Peptide Synthesis Using Traceless Chiral Coupling Reagents and Racemic Amino Acids

The enantioselective condensing reagent 4,6‐dimethoxy‐1,3,5‐triazine (DMT)/strychnine/BF$\rm{{_{4}^{-}}}$ was obtained by treatment of 2‐chloro‐4,6‐dimethoxy‐1,3,5‐triazine (CDMT) with strychnine tetrafluoroborate. The reagent was useful under typical conditions of solid‐phase peptide synthesis (SPPS) with enantiomerically homogeneous substrates. By SPPS, desired dipeptides were obtained in 84–94% yield using 4 equiv. of racemic Fmoc‐Ala, Fmoc‐Phe, and/or Fmoc‐Tyr for 1 equiv. of Wang resin loaded with Gly, Ala, Leu, Phe, Glu(^tBu), and/or Pro, respectively. For all three Fmoc‐protected amino acids, the configuration of the enantiomer preferred under SPPS conditions was independent of the structure of the acylated component and identical to that established in condensations proceeding in solution. In all cases, the enantiomer ratios L /D (er) were in a similar range, and varied from 9 : 92 to 2 : 98 for alanine, and from 90 : 10 to 100 : 0 for aromatic amino acids. The synthesis of Ac‐L ‐Lys(Ac)‐D ‐Ala‐D ‐Ala‐OH from racemic Fmoc‐Ala gave an L /D ratio of 10 : 90 for the esterification of Wang resin, and 0 : 100 for the formation of peptide bonds.     

Solid-Phase Total Synthesis of Bacitracin A

An efficient solid-phase method for the total synthesis of bacitracin A is reported. This work was undertaken in order to provide a general means of probing the intriguing mode of action of the bacitracins and exploring their potential for use against emerging drug-resistant pathogens. The synthetic approach to bacitracin A involves three key features: (1) linkage to the solid support through the side chain of the L-asparaginyl residue at position 12 (L-Asn(12)), (2) cyclization through amide bond formation between the alpha-carboxyl of L-Asn(12) and the side chain amino group of L-Lys(8), and (3) postcyclization addition of the N-terminal thiazoline dipeptide as a single unit. To initiate the synthesis, Fmoc L-Asp(OH)-OAllyl was attached to a PAL resin. The chain of bacitracin A was elaborated in the C-to-N direction by sequential piperidine deprotection/HBTU-mediated coupling cycles with Fmoc D-Asp(OtBu)-OH, Fmoc L-His(Trt)-OH, Fmoc D-Phe-OH, Fmoc L-Ile-OH, Fmoc D-Orn(Boc)-OH, Fmoc L-Lys(Aloc)-OH, Fmoc L-Ile-OH, Fmoc D-Glu(OtBu)-OH, and Fmoc L-Leu-OH. The allyl ester and allyl carbamate protecting groups of L-Asn(12) and L-Lys(8), respectively, were simultaneously and selectively removed by treating the peptide-resin with palladium tetrakis(triphenylphosphine), acetic acid, and triethylamine. Cyclization was effected by PyBOP/HOBT under the pseudo high-dilution conditions afforded by attachment to the solid support. After removal of the N-terminal Fmoc group, the cyclized peptide was coupled with 2-[1'(S)-(tert-butyloxycarbonylamino)-2'(R)-methylbutyl]-4(R)-carboxy-Delta(2)-thiazoline (1). The synthetic peptide was deprotected and cleaved from the solid support under acidic conditions and then purified by reverse-phase HPLC. The synthetic material exhibited an ion in the FAB-MS at m/z 1422.7, consistent with the molecular weight calculated for the parent ion of bacitracin A (MH(+) = C(73)H(84)N(10)O(23)Cl(2), 1422.7 g/mol). It was also indistinguishable from authentic bacitracin A by high-field (1)H NMR and displayed antibacterial activity equal to that of the natural product, thus confirming its identity as bacitracin A. The overall yield for the solid-phase synthesis was 24%.     

An Orthogonally Protected alpha,alpha-bis(aminomethyl)-beta-alanine building block for the construction of glycoconjugates on a solid support

Synthetic glycoclusters are extensively used as mimetics of naturally occurring, multivalent carbohydrate ligands in various glycobiological applications. Their preparation, however, is far from trivial, and it still is a limiting factor in the study of carbohydrate binding. We herein report the synthesis of an orthogonally protected building block, N-Alloc-N'-Boc-N' '-Fmoc-alpha,alpha-bis(aminomethyl)-beta-alanine (1), and its use in the preparation of triantennary peptide glycoclusters (21-24) on a solid support. The assembly of the clusters involves removal of the amino protections of the solid-supported branching unit 1 in the order Fmoc, Boc, and Alloc, and subsequent coupling of peracetylated O-(glycopyranosyl)-N-Fmoc-L-serine pentafluorophenyl esters (galactose, glucose, mannose, and ribose) to each amino group exposed.     

Towards a selective Boc deprotection on acid cleavable Wang resin

Deprotection of the Boc group of an amino acid attached to the Wang resin has been investigated. Several conditions, including bases, solvents and reaction time, were studied. Quantitative yield of Boc deprotection was achieved with less than 10% loss of resin loading with trimethylsilyltriflate. This reagent allows the replacement of tert-butyl to TMS group, leading to a new temporary urethane protection readily hydrolyzed.     

Fmoc solid phase synthesis of polyamides containing pyrrole and imidazole amino acids

[structure: see text]. Polyamides containing N-methylimidazole (Im) and N-methylpyrrole (Py) amino acids are synthetic ligands that have an affinity and specificity for DNA comparable to those of many naturally occurring DNA binding proteins. A machine-assisted Fmoc solid phase synthesis of polyamides has been optimized to afford high stepwise coupling yields (>99%). Two monomer building blocks, Fmoc-Py acid and Fmoc-Im acid, were prepared in multigram scale. Cleavage by aminolysis followed by HPLC purification affords up to 200 mg quantities of polyamide with purities and yields greater than or equal to those reported using Boc chemistry. A broader set of reaction conditions will increase the number and complexity of minor groove binding polyamides which may be prepared and help ensure compatibility with many commercially available peptide synthesizers.     

Solid-supported synthesis of cryptand-like macrobicyclic peptides

A straightforward method for the solid-supported synthesis of cryptand-like bicyclic peptides (1-5) on a backbone amide linker has been described. For the branching, two novel easily available building blocks, viz. N-(4-methoxytrityl)-N-(2-nitrobenzenesulfonyl)-protected N,N-bis(2-aminoethyl)-beta-alanine (6) and N-(9-fluorenylmethoxycarbonyl) protected iminodiacetic acid monoallyl ester (7), have been employed. The key steps of the synthesis are as follows: (i) stepwise coupling of one amino acid and 6 to the secondary amino group of the linker; (ii) removal of the 2-nitrobenzenesulfonyl group and SPPS by the Fmoc chemistry, using 7 as the penultimate and tert-butoxycarbonyl (Boc) protected glycine as the last amino acid; (iii) removal of the 4-methoxytrityl protection and subsequent SPPS by the Fmoc chemistry; (iv) removal of the allyl and Fmoc groups, followed by cyclization; and (v) removal of the Boc and tert-butyl groups, followed by cyclization. Final cleavage from the support and removal of benzyl-derived protecting groups gives the desired bicyclic products.     

Practical and Efficient Synthesis of Orthogonally Protected α‐2,3‐Diaminopropionic Acid (2,3‐Dap), 2,4‐Diaminobutanoic Acid (2,4‐Dab), and their N‐Methylated Derivatives

The synthesis of orthogonally protected Fmoc‐Dap/Dab (Boc/Z/Alloc)‐OH starting from Fmoc‐Asp/Glu has been described. The salient features of our synthetic strategy involved formation of Fmoc‐Asp/Glu‐5‐oxazolidinone acids, conversion of acid function to acyl azides, Curtius rearrangement, and hydrolysis of the oxazolidinone group.     

硅胶催化的选择性去除N-Boc保护基

发现了在回流的甲苯中, 以硅胶为催化剂, 多种N-Boc保护的伯胺、仲胺、氨基酸的氨基都可以迅速脱除Boc. 该方法具有条件温和、操作简便、反应时间短和产率高等优点. 同时, 其它常用的保护基Cbz和Fmoc等在同样的条件下不受影响.