3种黄酮醇ESI-ITMS准分子离子构型的密度泛函理论分析

采用密度泛函理论(Density functional theory,DFT)B3LYP方法,通过全几何结构优化、二面角柔性势能扫描,对山奈酚、槲皮素、杨梅素3种黄酮醇分子的优势构象及电喷雾离子阱质谱(ESI-ITMS)负离子模式下准分子离子的最优构型进行了研究,并从能量参数、构型参数、质谱实验角度对准分子离子的最优构型作出了确证。结果表明:山奈酚、槲皮素和杨梅素分子二面角D(1,2,1',6')均接近0°,分子的优势构象均为B环与A,C环处在同一平面上的构象;在负离子模式下,自动及手动扫描方式得到的山奈酚、槲皮素、杨梅素的二级质谱的复杂程度依次减弱,各分子失去羟基氢所形成的准分子离子结构共轭链增长、共轭效应加强;山奈酚存在两种低能量的准分子离子构型,即失去B环4'位羟基氢与失去A环7位羟基氢的构型,槲皮素与杨梅素失去B环4'位羟基氢的总能量最低、构型最稳定,且山奈酚、槲皮素、杨梅素准分子离子构型的稳定性依次增加。该研究可供进一步探索黄酮醇类化合物ESI-ITMS负离子模式下的质谱裂解规律参考。     

山奈酚的电喷雾质谱裂解途径

采用电喷雾质谱技术对山奈酚的质谱过程进行了表征,并用量子化学方法对山奈酚的质谱裂解途径进行了理论研究。 依据密度泛函理论,在B3LYP/6-31G(d)水平,对山奈酚的各质谱碎片离子进行了几何结构优化,确定了各碎片的稳定结构;然后,在ROB3LYP/ 6-311++G(2d,2p)水平计算了形成各碎片离子所需的键断裂能,进而推导出了山奈酚的质谱碎裂途径。 计算结果显示,山奈酚主要通过C环碎裂而发生裂解,出现碎片m/z 284.7、256.7、228.7、210.7、184.8、168.7和150.7,其中m/z 210.7的碎片离子键断裂能最小,m/z 150.7的碎片离子键断裂能最大,说明前者很容易由母离子碎片形成,后者较难由母离子碎片形成。     

4种儿茶素类化合物电喷雾质谱裂解规律的研究

利用离子阱飞行时间质谱仪的高质量精度、高分辨率及多级测定性能, 对儿茶素类化合物(二组对映异构体)质谱裂解进行研究, 并利用氢/氘交换法对裂解方式进行确证. 发现儿茶素对映异构体间具有相同的质谱裂解途径, 多级质谱无明显区别. 在二级质谱中, 表儿茶素/儿茶素(EC/C)丢失的CO₂发生在A环, 丢失的C₂H₂O发生在B环. ^1,4A^-, ^1,3A^-, ^1,2A^-和[M-H-B环]^-4个碎片离子为EC/C特征离子, 通过这4个离子质量数变化, 推测A环上的取代情况. 因表儿茶素没食子酸酯/儿茶素没食子酸酯(ECG/CG)结构上都含有没食子酸取代基, 在二级质谱中均可见m/z169特征峰, 此离子可用于ECG/CG和EC/C区分.     

电喷雾-离子阱-飞行时间质谱联用研究黄酮和异黄酮苷元C环上的裂解规律

采用电喷雾-离子阱-飞行时间串联质谱在负离子模式下分析了4个黄酮苷元和6个异黄酮苷元的质谱数据, 并总结了两类化合物C环上的裂解规律. 黄酮化合物C环以Rretro-Diels-Alder(RDA)裂解断裂为主, 形成A1,3-离子且相对丰度较高; 而异黄酮化合物C环断裂以碳0和碳3键的断裂为主, 形成B0,3-离子, 且相对丰度较高. 说明黄酮化合物的交叉共轭体系和异黄酮的非交叉共轭体系对C环的裂解影响较大, 而且黄酮化合物的B环和异黄酮化合物的A, B环上取代基的类型和位置对生成碎片离子的稳定性也有影响, 导致生成的碎片离子类型及其相对丰度不同, 根据其质谱数据(包括碎片离子的质荷比和相对离子丰度)可以推测黄酮类化合物的结构类型和取代状况, 为快速鉴定黄酮化合物和异黄酮化合物结构奠定了基础.     

甘露糖磷酰氨基酸缀合物的ESI-MS研究

一系列全乙酰保护甘露糖-1-磷酰氨基酸酯缀合物的α构型和β构型异构体的ESI-MSn裂解规律研究表明, β构型异构体会出现一系列特征的m/z 433, 391, 371的碎片离子, 且［M-CH2CHCH3+Na］+碎片丰度较大. ［M-糖基+Na］+和［糖基+Na］+碎片相对丰度较小. α构型分子反之. 同时对全乙酰保护的［糖基+Na］+ m/z 353碎片离子进行三级碎裂, 其主要特征是消除CH2CO和AcOH中性分子的碎片离子, 而且其它位羟基构型的差异对质谱中碎裂方式影响不大.     

芦丁的电喷雾离子阱质谱分析

研究了芦丁在电喷雾离子阱质谱(ESI-MS)下的主要特征碎片离子及其裂解规律。应用电喷雾离子阱质谱技术研究芦丁的结构和正、负离子扫描条件下芦丁的主要特征碎片离子及其裂解规律。芦丁在正、负离子模式下均可得到较好的质谱信息,在正离子模式下,容易与Na+形成[M+Na]+的准分子离子,并裂解形成碎片m/z 605,487,331,325,313,185等,在负离子模式下,形成[M-H]-的准分子离子,并进一步碎裂形成碎片m/z 301,283,257,255,229,227,211等。分别阐明了芦丁在正、负离子模式下的电喷雾质谱碎裂规律,并对主要特征碎片离子进行归属,为进一步芦丁的结构优化和修饰提供了有价值的依据。     

大肠杆菌O152中wfgD基因编码的β-1,3-葡萄糖基转移酶产物结构的质谱表征

大肠杆菌O152抗原的寡糖重复单位中含葡萄糖-β-1,3-N-乙酰葡萄糖胺(Glc-β-1,3-GlсNAc)连接键。本研究采用电喷雾离子化多级串联质谱技术对以人工合成的天然受体底物的结构类似物苯氧基十一烷二磷酸-N-乙酰葡萄糖胺(GlcNAc-β-PO3-PO3-(CH2)11-O-phenyl(GlcNAc-PP-PhU))为受体底物,尿苷二磷酸葡萄糖(UDP-Glc)为给予体底物的酶促反应产物进行了详细的结构表征。电喷雾离子化多级串联质谱图中观察到的主要碎片源于磷酸二酯键部分和糖苷键的裂解。此外,由观察到的二糖产物非还原端碎片获得了序列信息;跨环断裂碎片及源于吡喃环取代基消除的‘内在’碎裂离子可提供组成产物的单糖残基连接方式信息。广泛的碎裂信息表明wfgD基因编码UDP-Glc:GlcNAc-pyrophosphate-lipid中的β-1-3葡萄糖基转移酶。     

小檗碱质谱碎片离子稳定性分析及碎裂机理的量子化学研究

用量子化学B3LYP/6-31G(d)方法, 研究了小檗碱质谱碎片离子的稳定性规律. 通过几何参数分析、 结合能计算和前线分子轨道分析, 研究碎片离子可能的活性部位及各部位相对反应活性, 并从理论上探讨了质谱碎裂机理. 结合能计算结果表明, 分子离子中C9所连甲氧基的C—O键比C10所连甲氧基的C—O键更容易断裂. 同时发现, 质谱碎裂过程中, 氢的解离促进了羰基的解离, 即质谱中常见的解离CO的过程.     

苦参生物碱电喷雾质谱分析

用电喷雾离子阱质谱(ESI-ITMS)研究了苦参碱和氧化苦参碱一级质谱电离规律和二级质谱裂解规律。实验结果显示,苦参碱和氧化苦参碱电喷雾一级质谱中均易产生聚合及加合离子,二级质谱中易产生环逐步裂解碎片离子,即结构相似的苦参碱和氧化苦参碱具有相似的电喷雾质谱行为。苦参碱的特征碎片为m/z148和150,氧化苦参碱的特征碎片为m/z248([M H-17] )、m/z247([M H-18] )以及m/z148、m/z150。对苦参对照药材的甲醇提取物进行了电喷雾质谱分析,由一级质谱的准分子离子及其二级质谱碎裂信息对各已知组分进行了结构认证。     

大黄酸ESI-IT MS质谱行为及碎片离子的量子化学研究

采用电喷雾-离子阱质谱(ESI-IT MS),获取大黄酸分子的一级质谱和多级质谱碰撞诱导解离下的碎片离子,以量子化学计算大黄酸分子及其主要碎片离子的质谱行为。通过对质谱离子几何参数、键断裂能、电荷变化、自旋密度以及前线分子轨道的分析,可得到m/z 282.8、256.9、238.9、210.8、192.8、182.8、166.8离子的稳定构型以及质谱裂解途径,从而较系统地解释了大黄酸分子在ESI-IT MS中的裂解行为。     

Structural characterization of neutral oligosaccharide mixtures through a combination of capillary electrochromatography and ion trap tandem mass spectrometry

A CEC/ESI-MS/MS combined system has been developed for the separation and on-line structural analysis of neutral oligosaccharides. Various types of isomeric oligosaccharides were first successfully separated by CEC using polar monolithic columns, while the on-line tandem mass spectrometry has been explored to differentiate and elucidate the structures of isomeric oligosaccharides. The experimentally obtained tandem spectra usually provide sequence, branching, and linkage information. Oligosaccharide isomers with a different monomeric composition and branching showed different patterns of glycosidic linkage cleavage (B- and Y-ion series), allowing us to deduce their sequence and branching points. Isomers with different linkages were distinguished by identifying cross-ring fragment ions (A-ion series). While (1-->4) linkages yielded dominant (0,2)A ions, (1-->6) linkages showed an extensive and complete cross-ring cleavage series: (0,2)A, (0,3)A, and (0,4)A ions. Although the anomeric configurations and monosaccharide identification are rarely obtained from tandem MS, the relevant mixture components can be completely resolved with high-efficiency CEC columns featuring a polar functionality.     

Collisionally activated dissociation and electron capture dissociation provide complementary structural information for branched permethylated oligosaccharides

Doubly charged sodiated and permethylated linear malto-oligosaccharides ({Glc}6-{Glc}9), branched N-linked glycans (high-mannose type GlcNAc2Man5-9, and complex asialo- and disialylated-biantennary glycans) were analyzed by tandem mass spectrometry using collisionally-activated dissociation (CAD) and "hot" electron capture dissociation (ECD) available in a custom-built ESI FTICR mass spectrometer. For linear permethylated malto-oligosaccharides, both CAD and "hot" ECD produced glycosidic cleavages (B, Y, C, and Z ions), cross-ring cleavages (A- and X-type), and internal cleavages (B/Y and C/Y type) to provide sequence and linkage information. For the branched N-linked glycans, CAD and "hot" ECD provided complementary structural information. CAD generated abundant B and Y fragment ions by glycosidic cleavages, whereas "hot" ECD produced dominant C and Z ions. A-type cross-ring cleavages were present in CAD spectra. Complementary A- and X-type cross-ring fragmentation pairs were generated by "hot" ECD, and these delineated the branching patterns and linkage positions. For example, 0, 4An and 3, 5An ions defined the linkage position of the major branch as the 6-position of the central core mannose residue. The internal fragments observed in CAD were more numerous and abundant than in "hot" ECD spectra. Since the triply charged (sodiated) molecular ion of the permethylated disialylated-biantennary N-linked glycan has relatively high abundance, it was isolated and fragmented in a "hot" ECD experiment and extensive fragment ions (glycosidic and complementary pairs of cross-ring cleavages) were generated to fully confirm the sequence, branching, and linkage assignments for this glycan.     

Systematic identification of N-acetylheparosan oligosaccharides by tandem mass spectrometric fragmentation

Recently, a useful procedure for the preparation of both even- and odd-numbered series of N-acetylheparosan (NAH) oligosaccharides was established. The present report describes findings when these NAH oligosaccharides were subjected to comparative mass spectrometry (MS)/MS fragmentation analysis by matrix-assisted laser desorption/ionization (MALDI)-LIFT-time-of-flight (TOF)/TOF-MS/MS, and electrospray ionization (ESI) collision-induced dissociation (CID) MS/MS. The resultant fragment ions were systematically assigned to elucidate fragmentation characteristics. In the MALDI-LIFT-MS/MS experiments, all the NAH oligosaccharides underwent unique glycosidic cleavages that included B-Y ion cleavages (nomenclature system of Domon and Costello, Glycoconjugate J. 1988; 5: 397) at the C-1 side, and C-Z ion cleavages at the C-4 side, with respect to glucuronic acid (GlcA). In addition, (0,2)A and/or (0,2)X cross-ring cleavages were observed for relatively small oligosaccharides. The former observation clearly reflects the occurrence of a GlcA-N-acetylglucosamine (GlcNAc) alternating structure of NAH, while the latter feature implies the occurrence of the -beta-1-4-glucuronide linkage. Extensive glycosidic cleavages were also observed in the ESI-CID-MS/MS fragmentation, though cleavage specificity was less evident than in the case of MALDI-LIFT-TOF/TOF-MS/MS. The information obtained in this study should be valuable for understanding both biosynthetic and degradation processes of NAH and its derivatives including heparin and heparan sulfate, as well as artificially modified NAH oligosaccharides.     

Ultraviolet photodissociation of chromophore-labeled oligosaccharides via reductive amination and hydrazide conjugation

The fragmentation patterns of hydrazide-conjugated and reductively aminated oligosaccharides, including lacto-N-fucopentaoses and lacto-N-difucohexaoses, produced on collisionally induced dissociation (CID) and ultraviolet photodissociation (UVPD) in a quadrupole ion trap are presented. The two derivatization methods generate different cross-ring cleavages on UVPD and CID. UVPD of hydrazide-conjugated oligosaccharides yield predominant (2, 4)A-type cross-ring cleavage ions. In contrast, UVPD of aminated oligosaccharides results mainly in (0, 1)A-type ions. Moreover, more extensive dual-cleavage pathways (i.e. internal fragment ions) were observed on UVPD.     

Tandem MS can distinguish hyaluronic acid from N-acetylheparosan

Isobaric oligosaccharides enzymatically prepared from hyaluronic acid (HA) and N-acetylheparosan (NAH), were distinguished using tandem mass spectrometry. The only difference between the two series of oligosaccharides was the linkage pattern (in HA 1-->3 and in NAH 1-->4) between glucuronic acid and N-acetylglucosamine residues. Tandem mass spectrometry afforded spectra in which glycosidic cleavage fragment ions were observed for both HA and NAH oligosaccharides. Cross-ring cleavage ions 0,2An and 0,2An-h (n is even number) were observed only in GlcNAc residues of NAH oligosaccharides. One exception was an 0,2A2 ion fragment observed for the disaccharide from HA. These cross-ring cleavage fragment ions are useful to definitively distinguish HA and NAH oligosaccharides.     

Evidence for linkage position determination in known feruloylated mono- and disaccharides using electrospray ion trap mass spectrometry

Various feruloylated arabinose- and galactose-containing mono- and disaccharides with known linkage configurations (2-O-(trans-feruloyl)-L-arabinopyranose, 5-O-(trans-feruloyl)-L-arabinofuranose, O-[2-O-(trans-feruloyl)-alpha-L-arabinofuranosyl]-(1-->5)-L-arabinofuranose, and O-[6-O-(trans-feruloyl)-beta-D-galactopyranosyl]-(1-->4)-D-galactopyranose) were analyzed by electrospray ionization mass spectrometry using an ion trap or a quadrupole time-of-flight (Q-TOF) mass analyzer. Collision-induced dissociation (CID) experiments using the two mass analyzers generated similar tandem mass spectrometric (MS/MS) fragmentation patterns. However, the ester-bond cleavage ions were more abundant using the Q-TOF mass analyzer. Compared with the positive ion mode, the negative ion mode produces simpler and more useful CID product-ion patterns. For arabinose-containing feruloylated compounds, results obtained with both analyzers show that it is possible to assign the location of the feruloyl group to the O-2 or O-5 of arabinosyl residues. In the characterization of the 2-O-feruloyl and 5-O-feruloyl linkages, the relative abundance of the cross-ring fragment ions at m/z 265 (-60 u or -62 u after 18O-labelling) and at m/z 217 (-108 u or -110 u after 18O-labelling) play a relevant role. For galactose-containing feruloylated compounds, losses of 60, 90 and 120 Da observed in MS3 experiment correspond to the production of 0,2A1, 0,3A1 and (0,2A1-60 Da) cross-ring cleavage ions, respectively, fixing the location of feruloyl group at the O-6 of the galactose residue.     

Structural characterization by both positive and negative electrospray ion trap mass spectrometry of oligogalacturonates purified by high-performance anion-exchange chromatography

The off-line coupling of high-performance anion-exchange chromatography to electrospray ion trap mass spectrometry (ESI-IT-MS) is described. Two sets of isocratic conditions were optimised for the semi-preparative purification of oligogalacturonates of degree of polymerisation from 4 to 6 by monitoring eluates with either pulsed amperometric detection or evaporative light scattering detection in the presence of an online Dionex Carbohydrate Membrane Desalter (CMD). In these conditions, purified oligogalacturonate solutions were suitable, without further desalting steps, for infusion ESI-IT-MS experiments. This paper provides some interesting features of positive and negative ESI-IT-multiple MS (MSn) of these acidic oligosaccharides. The spectra acquired in both ion modes show characteristic fragments resulting from glycosidic bond and cross-ring cleavages. Under negative ionization conditions, the fragmentation of the singly-charged [M-H]- ions, as well as the Ci-, and Zi-, fragment ions through sequential MSn experiments, was always dominated by product ions from C- and Z-type glycosidic cleavages. All spectra also displayed 0.2 A-type cross-ring cleavage ions which carry linkage information. Collision-induced dissociation (CID) spectra of sodium-cationized species obtained under positive ionization conditions were more complex. Successive MSn experiments also led to the 0.2 A-type cross-ring cleavage ions observed together with B- and Y-type ions. The presence of the 0.2 A ion series was related to Mr 60 (C2H4O2) losses. Combined with the absence of the Mr 30 (CH2O) and the Mr 90 (C3H6O3) ions, these ions were indicative of 1-4 type glycosidic linkage.     

Electrospray mass spectrometry and fragmentation of N-linked carbohydrates derivatized at the reducing terminus

Derivatives were prepared from N-linked glycans by reductive amination from 2-aminobenzamide, 2-aminopyridine, 3-aminoquinoline, 2-aminoacridone, 4-amino-N-(2-diethylaminoethyl)benzamide, and the methyl, ethyl, and butyl esters of 4-aminobenzoic acid. Their electrospray and collision-induced dissociation (CID) fragmentation spectra were examined with a Q-TOF mass spectrometer. The strongest signals were obtained from the [M + Na]+ ions for all derivatives except sugars derivatized with 4-amino-N-(2-diethylaminoethyl)benzamide which gave very strong doubly charged [M + H + Na]2+ ions. The strongest [M + Na]+ ion signals were obtained from the butyl ester of 4-aminobenzoic acid and the weakest from 2-aminopyridine. The most informative spectra were recorded from the [M + Li]+ or [M + Na]+ ions. These spectra were dominated by ions produced by sequence-revealing glycosidic cleavages and "internal" fragments. Linkage-revealing cross-ring cleavage ions were reasonably abundant, particularly from high-mannose glycans. Although the nature of the derivative was found to have little effect upon the fragmentation pattern, 3-aminoquinoline derivatives gave marginally more abundant cross-ring fragments than the other derivatives. [M + H]+ ions formed only glycosidic fragments with few, if any, cross-ring cleavage ions. Doubly charged molecular ions gave less informative spectra; singly charged fragments were weak, and molecular ions containing hydrogen ([M + 2H]2+ and [M + H + Na]2+) fragmented as the [M + H]+ singly charged ions with no significant cross-ring cleavages.     

Influence of the labeling group on ionization and fragmentation of carbohydrates in mass spectrometry

The ionization and fragmentation behaviors of carbohydrate derivatives prepared by reaction with 2-aminobenzamide (AB), 1-phenyl-3-methyl-5-pyrazolone (PMP), and phenylhydrazine (PHN) were compared under identical mass spectrometric conditions. It has been shown that the intensities of signals in MS spectra depend on the kind of saccharides investigated and reducing end labels used. PMP sialyllactose, when ionized by ESI/MALDI, produced a mixture of [M + H]+, [M + Na]+, [M - H + 2Na]+ ions in the positive mode and [M - H]-, [M + Na - 2H]- ions in the negative mode. The AB and PHN derivatives formed abundant [M + H]+ and [M - H]- ions in ESI, and by matrix-assisted laser desorption/ionization (MALDI) produced abundant [M + Na]+ ions. PMP- and reduced AB-sialyllactose produced only Y-type fragment ions under both MS/MS sources. In the electrospray ionization (ESI)-MS/MS spectrum of PHN-sialyllactose, abundant ions corresponded to B, Z cleavages and in its MALDI-MS/MS spectrum, the abundant ions were consistent with Y glycosidic cleavages with the concurrence of B, C, and cross-ring fragment ions. In the MALDI-MS spectra of oligosaccharides acquired immediately after derivatization, it was possible to detect only PHN derivatives. After purification, spectra of all three types of derivatives showed high signal-to-noise ratios with the most abundant ions observed for AB reduced saccharides. [M + Na]+ ions were the dominant products and their fragmentation patterns were influenced by the type of the labeling and the kind of oligosaccharide considered. In the MALDI-PSD and -MS/MS spectra of AB-derivatized glycans, higher m/z fragment ions corresponded to B and Y cleavages and the loss of bisecting GlcNAc appeared as a weak signal or was not detected at all. Fragmentation patterns observed in the spectra of hybrid/complex PHN and PMP glycans were more comparable-higher m/z fragments corresponded to B and C glycosidic cleavages. For PHN glycans, the abundance of ions resulting from the loss of bisecting GlcNAc depended on the number of residues linked to the 6-positioned mannose. Also, PHN and PMP derivatives produced cross-ring cleavages with abundances higher than observed in the spectra of AB derivatized oligosaccharides. For high-mannose glycans, the most informative cleavages were provided by AB and PHN type of labeling. Here, PMP produced dominant Y-cleavages from the chitobiose while other ions produced weak signals.     

Electron detachment dissociation of dermatan sulfate oligosaccharides

The structural characterization of glycosaminoglycans (GAG) oligosaccharides has been a long-standing challenge in the field of mass spectrometry. In this work, we present the application of electron detachment dissociation (EDD) Fourier transform mass spectrometry to the analysis of dermatan sulfate (DS) oligosaccharides up to 10 residues long. The EDD mass spectra of DS oligosaccharides were compared with their infrared multiphoton dissociation (IRMPD) mass spectra. EDD produces more abundant fragmentation than IRMPD with far less loss of SO3 from labile sulfate modifications. EDD cleaves all glycosidic bonds, yielding both conventional glycosidic bond fragmentation as well as satellite peaks resulting from the additional loss of 1 or 2 hydrogen atoms. EDD also yields more cross-ring fragmentation than IRMPD. For EDD, abundant cross-ring fragmentation in the form of A- and X-ions is observed, with 1,5Xn cleavages occurring for all IdoA residues and many of the GalNAc4S residues, except at the reducing and nonreducing ends. In contrast, IRMPD produces only A-type cross-ring fragmentation for long oligosaccharides (dp6-dp10). As all the structurally informative fragment ions observed by IRMPD appear as a subset of the peaks found in the EDD mass spectrum, EDD shows great potential for the characterization of GAG oligosaccharides using a single tandem mass spectrometry experiment.