key: cord-0068435-wdq9os1n
authors: Liu, Wenxi; Cheng, Xianlong; Kang, Rong; Wang, Yadan; Guo, Xiaohan; Jing, Wenguang; Wei, Feng; Ma, Shuangcheng
title: Systematic Characterization and Identification of Saikosaponins in Extracts From Bupleurum marginatum var. stenophyllum Using UPLC-PDA-Q/TOF-MS
date: 2021-09-30
journal: Front Chem
DOI: 10.3389/fchem.2021.747987
sha: a59719385f12e4d77cb0ff989a12c6904ad8e264
doc_id: 68435
cord_uid: wdq9os1n

Saikosaponins comprise a large group of chemical components present in the Bupleurum species that have attracted attention in the field of medicine because of their significant biological activities. Due to the high polarity, structural similarity, and the presence of several isomers of this class of components, their structural identification is extremely challenging. In this study, the mass spectrometric fragmentation pathways, UV spectral features, and chromatographic behavior of different types of saikosaponins were investigated using 24 standard substances. Saikosaponins containing carbonyl groups (C=O) in the aglycone produced fragment ions by loss of 30 Da, and in addition, type IV saikosaponins could produce [aglycone−CH(2)OH−OH−H](−) and [aglycone−H(2)O−H](−) fragment ions through neutral losses at positions C(16) and C(17). The above characteristic ions can be used to identify saikosaponins. More notably, the identification process of saikosaponins was systematically summarized, and using this method, 109 saikosaponins were identified or tentatively characterized from the saikosaponins extract of Bupleurum marginatum var. stenophyllum (BMS) using UPLC-PDA-Q/TOF-MS with both data-dependent acquisition (DDA) and data-independent acquisition (DIA) modes, of which 25 were new compounds and 60 were first discovered from BMS. Further studies revealed that the saikosaponins profiles of BMS, Bupleurum chinense DC (BC), and Bupleurum marginatum Wall. ex DC (BMW) were very similar. This work is of great significance for the basic research of the Bupleurum species and provides strong technical support to solve the resource problems associated with Radix Bupleuri.

Radix Bupleuri (RB) is a classic herb from the Bupleurum species called "chaihu" in Chinese. As one of the most successful and widely used traditional Chinese medicines (TCMs) in Asia, RB is widely used clinically to treat liver disease, fever, chills, tumor, hypochondria, inflammation, and uterine prolapse and has a history of over 2000 years (Ashour and Wink, 2011) . According to the Chinese Pharmacopeia, Bupleurum chinense DC (BC) and Bupleurum scorzonerifolium Willd. are recognized as the official medicinal materials of RB, which are named "North Chaihu" and "South Chaihu," respectively. With the growing attention to improving health conditions, the development and utilization of RB resources have expanded rapidly, but actual RB resources have gradually decreased due to irrational harvesting and waning fields for forestry. Therefore, it is urgent to search for other Bupleurum species that can replace legal RB species as medicine for development and application.

Bupleurum marginatum var. stenophyllum (BMS) is a major Bupleurum species used in TCM in China and was first recorded in the Southern Yunnan Materia Medica. BMS was introduced from Tibet, due to its high yield, high content of saikosaponins, and low price, and it was widely planted in Gansu and other regions, gradually radiating to Shanxi, Qinghai, and other provinces across China. BMS is an abundant resource and has a long history of medicinal use; related studies have shown that the pharmacological effects of BMS are similar to those of BC Wang et al., 2020) , and the active ingredients are relatively similar to those of BC , so BMS is considered to be the preferred alternative Bupleurum species of BC with good development and application prospects. Thus, it is necessary to conduct detailed basic research on its main active ingredients, the saikosaponins.

Saikosaponins are the most important pharmacochemical components of the Bupleurum species with multiple pharmacological activities that cover nearly all aspects of the medicinal efficacy of Bupleurum medicinal materials (Abe et al., 1982; Zhao et al., 2019; Ren et al., 2019; Wang et al., 2013; Li et al., 2018) . There are a large variety of saikosaponins, and to date, over 100 saikosaponins have been isolated from the Bupleurum species, and their structures are mainly pentacyclic triterpenoid derivatives, which have mainly been classified into 7 different types based on the aglycone structure: epoxy ether at C 13 , C 28 -position (type I), isocyclic diene (type II), C 12 -ene (type III), homocyclic diene (type IV), C 12 -ene-C 28 -carboxylic acid (type V), isocyclic diene and C 30 -carboxylic acid (type VI), and C 18 -ene (type VII); the main structural formulas are shown in Figure 1 . The conjugated sugars are mainly glucose (Glu), rhamnose (Rha), furanose (Fuc), xylose (Xyl), and pentitol. Saccharide chains are usually attached to the aglycone at position C 3 , among which type I saikosaponins only exist in Bupleurum plants and consist of the highest content of native saikosaponins in the Bupleurum species (Sun et al., 2019; Jiang et al., 2020) .

Saikosaponins are not only diverse in structure but also very similar in polarity, and there are many isomers. It is tedious to purify, separate, and identify them using conventional phytochemical separation methods, and the experimental period is long. In recent years, ultra-performance liquid chromatography-mass spectrometry (UPLC-MS) has been widely used in many research fields due to its ability to obtain abundant sample information and efficient component separation, such as rapid identification of chemical components of TCM and drug quality control, speculated by aligning MS information and fragmentation patterns of target compounds with chemical standard substances or literature; the chemical components of TCM can be rapidly and accurately identified (Guo et al., 2016; Qing et al., 2017; Münger et al., 2018; Yang et al., 2019; Ye et al., 2019; Xia et al., 2021) . At present, there are still many saikosaponins with structural diversity present at low abundance that remain to be separated and identified by UPLC-MS.

In this study, an efficient sample-processing method was established to extract, purify, and enrich saikosaponins, especially trace saikosaponins at low abundance; we eliminated the interference of non-saikosaponin components and improved their detection efficiency and selectivity. Next, we established an UPLC-PDA-Q/TOF-MS method combined with both DDA and DIA modes to analyze 24 different saikosaponin standard substances with known structures, fully analyzed and summarized their properties such as fragment ions, retention time, and maximum UV wavelength, further applied its summary rules to reliably characterize and identify the total saikosaponin extract from BMS, and compared them with saikosaponins of two other commonly used Bupleurum species-BC (the legal RB) and Bupleurum marginatum Wall. ex DC (BMW, another major Bupleurum species, whose genetic relationship is close to BMS); the objective was to explore the similarities and differences of saikosaponins between BMS and them in order to provide essential data for related research. 

The samples were pulverized and extracted with 10 times the volume in 70% ethanol (containing 0.05% ammonia water) twice for 4 h under reflux, followed by concentration under reduced pressure. The residue was extracted with petroleum ether, ethyl acetate, and water-saturated n-butanol, respectively; the watersaturated n-butanol part was recovered to extract. We dispersed the above extract by D101 macroporous resin column chromatography, eluting with water, 30% ethanol, 70% ethanol, and 95% ethanol in turn, and finally collected the 70% ethanol fraction to obtain the purified and enriched total saikosaponin extract of samples.

To obtain 20 mg of the prepared total saikosaponin extract, the materials were accurately weighed and added to a 10-ml brown volumetric flask, and methanol was added on a scale, sealed, and ice-bath sonicated for 5 min, and the solution was filtered using a 0.22-μm microporous filter membrane to obtain the sample solutions. The appropriate amount of each standard substance was weighed accurately and diluted with methanol to the desired concentrations, and the standard substance solutions were obtained.

We used the ultra-high performance LC System with a Q/TOF-MS, PDA detector, and Masslynx workstation (Waters MS Technologies, Manchester, United Kingdom) to acquire UPLC-high-resolution mass spectrometry (HRMS) raw data.

Chromatographic separation was performed on an ACQUITY BEH C 18 column (150 mm × 2.1 mm, 1.7 μm), maintained at 35°C. The flow rate was 0.3 ml/min, and the injection volume was 2 μL. The mobile phase consisted of (solvent A) 0.05% formic acid in acetonitrile (v/v) and (solvent B) 0.05% formic acid in water (v/ v), and the gradient elution was as follows: 0-4 min, 5%-15% A; 4-20 min, 15%-30% A; 20-30 min, 30% A; 30-40 min, 30%-44% A; 40-47 min, 44% A; 47-54 min, 44%-90% A; 54-55 min, 90%-98% A; 55-56 min, 98% A. The detection wavelength range of the PDA detector was set to 200-400 nm.

For MS conditions, the temperature of the electrospray ion (ESI) source was set to 120°C; the cone and capillary voltages were 30 V and 3.0 kV, respectively. High-purity nitrogen was selected as the desolvation gas with the desolvation temperature set to 450°C; high-purity argon was selected as the collision gas. The [M-H]ion of leucine enkephalin (LE) at m/z 554.2615 was selected as the lock mass in ESI -; the [M + H] + ion of LE at m/z 556.2771 was selected as the lock mass in ESI + . Sodium formate solution was mass-spectrometrically tuned to ensure the accuracy and reproducibility during the experiment. For the data acquisition mode, the MS E and DDA acquisition modes were selected, and the mass scan range was 100-1,500 Da. In the MS E continuous acquisition mode, the sample data were collected by setting high and low two different collision energy (CE) pathways alternately to obtain molecular ions and fragment ions of target compounds. In terms of the CE, the low CE channel was set to 8 V and the high CE channel was set to 20-70 V. The DDA acquisition mode was set to 5 ion acquisition channels, and other acquisition conditions were the same as the MS E mode.

Conventional sample-processing methods mostly use methanol to extract saikosaponins for detection, which presents shortcomings. First, numerous non-saikosaponin components present in the extraction solution, which are extracted together with saikosaponins during detection, interfere with the identification of saikosaponins. Second, the extraction efficiency is low, and many trace saikosaponins are not fully extracted, which results in the missed detection. In this study, an efficient sample-processing method was developed to extract, enrich, and purify saikosaponins (especially the trace saikosaponins), eliminate the interference of non-saikosaponin components, and improve their detection efficiency and selectivity.

The range of UV detection wavelengths was set at 200-400 nm based on the structure of the saikosaponins. The data acquisition modes of mass spectrometry included data-dependent acquisition (DDA) and data-independent acquisition (DIA, i.e., MS E ). The DDA mode reduces the existence of interfering ions because it uses a narrow m/z window to screen target ions. Therefore, it can provide high-quality fragment information, but Frontiers in Chemistry | www.frontiersin.org September 2021 | Volume 9 | Article 747987 when valuable ions cannot satisfy the target screening conditions or co-flow with high-intensity ions, these target ions cannot be selected for fragmentation, or the number of parent ions selected will be too large, and this will lead to insufficient acquisition of the total ion chromatograms or base peak ion chromatograms (BPI) of the primary mass spectrum. For the DIA (MS E ) mode, the primary mass spectrum of ions was obtained at the low CE channel, and fragment ion information was obtained at the CE channel. In theory, the fragment information of all ions can be obtained comprehensively without screening the parent ions in advance. However, if there are many ions flowing concurrently, it is difficult to directly analyze the primary mass spectra and fragment ions, that is, it is difficult to directly determine from which specific parent the fragment ions in the secondary mass spectrum (MS/MS) derive (Law and Lim, 2013; Bateman et al., 2014) . Because saikosaponin compounds present both structural diversity and high structural similarity, even under gradient elution, it is currently difficult to separate all saikosaponin compounds from the baseline completely, in which there are co-efflux components and many trace saikosaponins with a low response. Thus, we combined the DDA and DIA (MS E ) modes to complement each other to scan and analyze parent ions and product fragment ions of saikosaponins accurately and comprehensively. The ESImode provides more abundant structural information of saikosaponin compounds, while the ESI + spectra of saikosaponins provide less information and compounds are subjected to breakage in the low CE scanning channel, which results in more interference with the analysis but can also document the characteristic fragment ions in ESI + and contribute to the determination of the specific position of substituent groups in acetylated/malonylated saikosaponins . Thus, this approach was used to identify saikosaponins in the ESI -, whereas for the identified acetylated/malonylated saikosaponins in ESI -, their fragment ions in ESI + were combined to speculate on the specific position of the respective acetyl/malonyl groups.

In this study, fragment ions were named according to the nomenclature rules of Domon and Costello (Supplementary Figure S1 ) (Domon and Costello, 1988) . A total of 24 saikosaponin standard substances (classified as types I-IV according to their aglycone structures and their acetylated derivatives were classified separately as one group for analysis) were subjected to analysis and the information obtained regarding the chromatographic, fragmentation behavior and maximum UV wavelength was summarized, their structures are shown in Figure 1 , and chromatography, UV absorption, and MS spectrum details for each standard substance are shown in Supplementary Table S1 .

SSa (β-OH at position C 16 ) and SSd (α-OH at position C 16 ) were a pair of epimers, with the same molecular ion ([M−H] − ) at m/z 779; their fragmentation behaviors were similar. In the ESImode, the fragment ions of the MS/MS spectrum (Supplementary Table  S1 ) were analyzed, and the Y 1 (m/z 617) ion corresponding to the [M-H]lost a fragment of 162 Da, indicating that a glucosyl group (Glu, 162 Da, C 6 H 10 O 5 ) at the end of the saccharide chain was lost. The X 0 (m/z 541) ion was produced by the breakage of the Y 1 (m/z 617) ion, corresponding to the Y 1 ion with a lost fragment of 76 Da (C 3 H 8 O 2 ), which represented the intracyclic breakage of furanose (0, 3-bond breakage). The [Y 1 −76−H] -(m/z 541) fragment ion was produced when the furanose (Fuc, 146 Da, C 6 H 10 O 4 ) was directly attached to the aglycone in the structure of saikosaponins; conversely, the presence of the [Y 1 −76−H]fragment ion was not detected for saikosaponins without furanose. Thus, a fragment of 76 Da (C 3 H 8 O 2 ) was lost as the specific fragmentation pathway of furanose, which was consistent with previous reports (Huang et al., 2008) . (Zhao et al., 1996) . The fragmentation pathway of SSa/SSd is shown in Figure 2A . Similarly, the fragmentation pathways of SSe, Prosaikogenin f, Prosaikogenin g, and other type I saikosaponins are similar to those of SSa/SSd. For SSc, the aglycone structure is different from that of SSa; the group at position C 23 is methyl (CH 3 ), and its fragmentation pathway is shown in Figure 2B .

23-Hydroxy-13β,28β-epoxyolean-11-ene-16-one 3-O-β-Dglucopyranosyl-(1→3)-β-D-fucopyranoside presents a carbonyl group (C O) in the aglycone moiety and its characteristic fragment ions appeared at m/z 407 ([aglycone−CH 3 OH−30−H] − ) in the ESImode, corresponding to the [aglycone−H] − , and lost a fragment of 30 Da. It was speculated that the C 13 ,C 28 -epoxy ether bond was broken first and was followed by a rearrangement reaction of the C O group at the C 16 position and breakage. The fragmentation pathway is shown in Supplementary Figure S2 .

Retention times of type I saikosaponins showed (Supplementary Table S1 ) that for a pair of epimers, the retention time of β-OH at position C 16 was earlier than that of the α-OH epimer (such as SSa/SSd and Prosaikogenin g/Prosaikogenin f). For the type I saikosaponins, their aglycones present only one double bond (no conjugation), so their maximum UV wavelengths were generally around at the terminal ends (190-220 nm); the representative UV spectra are shown in Figure 8A .

Epimers SSb 1 (β-OH at position C 16 ) and SSb 2 (α-OH at position C 16 ) are converted from SSa and SSd, respectively. In the ESImode, the fragmentation behavior of the two epimers was similar to that of SSa/SSd, and they also produced the following Compared with SSa/SSd (type I), SSb 1 /SSb 2 lost a CH 2 OH group at position C 17 and a hydroxyl (OH) group at position C 16 in the aglycone, simultaneously, and generated the m/z 423 ([aglycone−48−H] − ) fragment ion, which was consistent with the fragmentation behavior found by Liu et al. . Because SSf presented a single double bond of aglycone and did not produce a m/z 409 ([aglycone−48−H] − ) fragment ion, it can be inferred that this fragmentation pathway only occurred when two double bonds were conjugated. Interestingly, it was worth noting that this experiment found that the abundance of m/z 423 ([aglycone−CH 2 OH−OH−H] − ) fragment ion produced by SSb 1 having the β-OH at the C 16 position was greater than that of the m/z 439 ([aglycone−CH 3 OH−H] − ) fragment ion, while the abundance of the m/z 423 fragment ion produced by the SSb 2 with the α-OH at position C 16 was lower than that of the m/z 439 fragment ion produced. As shown in Supplementary Figure S3 , it is helpful to distinguish between the same pair of epimers in type II saikosaponin. These rules and findings were also applicable to other type II saikosaponins such as Prosaikogenin a, Prosaikogenin d, SSh, etc. The fragmentation pathway of SSb 1 /SSb 2 is shown in Figure 3 . The fragmentation pathway of SSh (the group at the C 23 position is CH 3 ) is shown in Supplementary Figure S4 and also produced a m/z 407 ([aglycone−CH 2 OH−OH−H] − ) fragment ion. Thus, the [aglycone−48−H] − could be considered diagnostic fragment ions of type II saikosaponins, while the loss of 48 Da (neutral loss of CH 2 OH and OH groups) may also be considered a characteristic loss of type II saikosaponins.

Retention times of type II saikosaponins are reported in Supplementary Table S1 . For the pair of epimers, the retention time of β-OH at the C 16 position was later than that of the α-OH epimer (such as SSb 1 /SSb 2 and Prosaikogenin a/Prosaikogenin d), which was contrary to that of type I saikosaponins. For the type II saikosaponins, the aglycones presented two double bonds (isocyclic diene conjugation), and the maximum UV wavelengths were generally around 250 nm; the representative UV spectra are shown in Figure 8B .

SSb 3 (β-OH at position C 16 ) and SSb 4 (α-OH at position C 16 ) with the aglycone structure of C 11 -OCH 3 are epimers. According to the fragment ions produced in the ESImode, the aglycone was released at the C 11 position, one molecule of CH 3 OH (32Da) was lost and produced an aglycone with C 8 -C 11 double bonds, and the m/z 471 ([aglycone−CH 3 OH−H] − ) fragment ion was produced. Thus, there were two double bonds (Δ 8,11 and Δ 12,13 ) in the aglycone due to the diene bond conjugation, the CH 2 OH group at position C 17 and the OH group at position C 16 , which could be lost simultaneously (loss of 48 Da), which produced the m/z 423 ([aglycone−CH 3 OH−CH 2 OH−OH−H] − ) fragment ion. The loss of C 4 -CH 3 OH produced the fragment ion m/z 391 ([aglycone−2CH 3 OH−CH 2 OH−OH−H] − ). Based on the m/z 439 ([aglycone −2CH 3 OH−H] − ), another fragmentation pathway of the aglycone produced the loss of C 11 -CH 3 OH and C 4 -CH 3 OH in turn; the fragmentation pathway of SSb 3 /SSb 4 is shown in Figure 4 . Similarly, for SSf, Ne-SSk, and 11α-methoxy-SSf, the fragmentation pathways were similar and are shown in Supplementary Figures S5-S7. Thus, the fragment ions produced by loss of a 48-Da fragment ([aglycone−CH 2 OH−OH−H] − ) were also a diagnostic fragment ion of type III saikosaponins in the ESI − mode.

The fragmentation behavior of Tibesaikosaponin V with the carbonyl (C O) group was similar to that of SSb 3 /SSb 4 , but the characteristic fragment ions were produced by the loss of 30 Da (neutral loss of CH 2 O), such as m/z 473 ([aglycone-30-H] − ). This behavior was the same for 23-hydroxy-13β,28βepoxyolean-11-ene-16-one 3-O-β-D-glucopyranosyl-(1→3)β-D-fucopyranoside (type I), and all had a carbonyl (C O) group in the aglycone moiety. The fragmentation pathway is shown in Figure 5 . Thus, the characteristic fragment ions produced by loss of 30 Da could be considered the diagnostic fragment ions of saikosaponins containing carbonyl groups in the ESI − mode. This study analyzed and summarized the characteristic fragment ions and fragmentation pathways of saikosaponins containing the C O group for the first time, which is of great significance and benefit for the identification of these types of saikosaponins. Table S1 ) that in the pair of epimers, the retention time of β-OH at position C 16 was earlier than that of the α-OH epimer. For type III saikosaponins, similar to type I saikosaponins, the aglycones also had a single double bond (no conjugation), and the respective maximum UV wavelengths were also approximately 190-220 nm. The representative UV spectra are shown in Figure 8C .

SSg was compared with the type II saikosaponin SSb 1 (isomer of SSg) generated fragment ions that were essentially the same in ESI -, which could produce m/z 423 ([aglycone−CH 2 OH−OH−H] − ) and other fragment ions of SSb 1 . However, this is the first study to observe the m/z 453 ([aglycone-18-H] − ) fragment ion from SSg, while the isomer SSb 1 (type II) or SSa (type I) did not produce the same fragment. It was speculated that due to the homocyclic diene conjugation effect, the OH group can be lost alone; the fragmentation pathway was shown in Figure 6 . Thus, in addition to the [aglycone−CH 2 OH−OH−H] − , the characteristic fragment ions such as [aglycone−H 2 O−H] − produced by loss of 18 Da could be considered a diagnostic fragment ion of type IV saikosaponins in the ESI − mode.

For type IV saikosaponins, the aglycone moieties present two double bonds (homocyclic diene conjugation), so their maximum UV wavelengths were generally around 282 nm, and the representative UV spectra are shown in Figure 8D .

The maximum UV wavelengths, characteristic fragment ions, and fragmentation pathways of type IV saikosaponins were analyzed and summarized for the first time, and we compared differences in fragmentation patterns with other types of Frontiers in Chemistry | www.frontiersin.org September 2021 | Volume 9 | Article 747987 saikosaponins, which is of great significance and contributes to the identification of type IV saikosaponins.

In Table S1 ), corresponding to the loss of one acetyl (CH 2 CO) group and the loss of one CH 3 COOH group, respectively. Subsequently, a series of fragment ions of the prototype saikosaponins mentioned above were produced.

As an example, 6″-O-acetyl-SSa fragmentation is shown in Supplementary Figure S8 . Prior studies have reported (Huang et al., 2008) For acetylated/malonylated saikosaponins in the ESImode, the fragment ions of the aglycone-substituted and saccharide-substituted saikosaponins were the same, which made them difficult to distinguish; but in the ESI + mode, their fragment ions differed so that they could easily be distinguished. In the ESI + mode, 6″-O-acetyl-SSb 3 , 2″-Oacetyl-SSa, 6″-O-acetyl-SSa, and 6″-O-acetyl-SSd, whose acetyl groups are substituted by the saccharide chain, were analyzed. The fragment ions produced are shown in Supplementary Table S2 Figure 7 , while that of 6″-O-acetyl-SSb 3 in the ESI + mode is shown in Supplementary Figure S10 . These rules and findings were also applicable to malonylated saikosaponins (the malonyl group is substituted by the saccharide chain) according to the related literature and also produce [aglycone-nH 2 O + H] + (n 1 or 2 or 3) in the ESI + mode, while the fragment ions m/z 497 ([aglycone+42-H 2 O + H] + ) and m/z 479 ([aglycone+42-2H 2 O + H] + indicate that the acetyl group is substituted by the aglycone. For example, the fragmentation pathway in the ESI + mode of 23-O-acetyl-SSa (the malonyl group is substituted by the aglycone) is shown in Supplementary Figure S11 .

Retention times were analyzed according to standard substances and according to that reported in the literature (Zhao et al., 1996; Huang et al., 2008) . The retention time of acetylated saikosaponins is later than that of the prototype saikosaponins. The acetyl substituent at different positions of 

Among the isomers, several pairs of epimeric saikosaponins such as SSa/SSd, SSb 3 /SSb 4 , SSb 1 /SSb 2 , Prosaikogenin a/Prosaikogenin d, and Prosaikogenin g/Prosaikogenin f differed only in the configuration of the OH group at position C 16 . Of these, saikosaponins with only one double bond in the aglycone moiety (types I and III), and the retention time of β-OH at the C 16 position was earlier than that of the α-OH epimer, such as SSa/SSd, SSb 3 /SSb 4 , and Prosaikogenin g/Prosaikogenin f. In contrast, for type II saikosaponins (whose aglycone is an isocyclic diene), the retention time of β-OH at position C 16 was later than that of the α-OH epimer, such as SSb 1 /SSb 2 and Prosaikogenin a/Prosaikogenin d. For acetylated (or malonylated) saikosaponins, the combination of retention times is helpful to infer The maximum UV absorption wavelengths of saikosaponins can be summarized as follows: saikosaponins (such asSSa/SSd/ SSc/SSb 3 /SSb 4 /SSe/SSf) with the aglycone as the monoene (types I and III) generally located around the terminal ends, ranged 190-220 nm; saikosaponins (such as SSb 1 /SSb 2 /SSc/SSh) with the aglycone as the isocyclic diene (type II), approximately Frontiers in Chemistry | www.frontiersin.org September 2021 | Volume 9 | Article 747987 10 250 nm; saikosaponins (such as SSg/SSi) with the aglycone as the homocyclic diene (type IV), approximately 282 nm. The representative UV spectra are shown in Figure 8 .

The characteristic mass losses and typical fragmentation pathways for different types of saikosaponins can be summarized as follows: all compounds produced a base peak at [M-H] − , and the molecular formula of each compound could be determined based on its exact mass. In addition to maximum UV absorption wavelengths, the type of aglycones could be inferred through their characteristic neutral losses of the aglycone moiety, such as type II and III (characteristic loss of 48 Da) and type IV (characteristic loss of 48 and 18 Da). The number and sequences of saccharide chains could be inferred through the characteristic neutral losses of sugar moieties, such as rhamnose (Rha, 146 Da), furanose (Fuc, 146 and 76 Da), xylose (Xyl, 132 Da), and glucose (Glu, 162 Da). Other typical losses were those such as OCH 4 (32 Da), H 2 O (18 Da), CH 3 OH (32 Da), CH 2 O (30 Da), AcOH/C 2 H 2 O (60 Da/42 Da), and C 3 H 2 O 3 /CO 2 (80 Da/44 Da), which corresponded to the presence of an OCH 3 group, an OH group, a CH 2 OH group, a C O group, an acetyl group, and a malonyl group, respectively. Figure 9 illustrates the strategy for identification of saikosaponins.

In the ESImode, the base peak ion (BPI) chromatogram of the total saikosaponin extract from BMS is shown in Figure 10 . Types I, II, III, and IV and some other types of saikosaponins were identified and initially characterized from the total saikosaponin extract of BMS, and when combined with the respective retention times and fragment ions in the ESI + mode, the specific position of the acetyl/malonyl substituent of acetylated/malonylated saikosaponins could be deduced. A total of 109 saikosaponin compounds were structurally identified and characterized, and the information on their identification, chromatographic retention time (RT), molecular formula, fragment ions, and maximum UV wavelengths is provided in Table 1 . A total of 22 saikosaponin compounds were confirmed by saikosaponin standards (marked with "*" in Table 1 ), 25 saikosaponins were new compounds (marked with "##" in Table 1 ), and 60 saikosaponins were first discovered in BMS (marked with "##" in Table 1 ).

Characterization of Compounds 40, 42, 58, and 71 (Type I) According to the fragment ions, retention times, and maximum UV wavelength of compounds 40, 42, 58, and 71 (Table 1) , their characteristic mass losses and UV maximum absorption wavelengths (190-220 nm) are consistent with those of type I saikosaponins, so it was inferred that these compounds had the same aglycones or similar aglycones (with the morehydroxyl substituents at different positions) as type I saikosaponins. 11 type I saikosaponins were identified in this study, including saikosaponin compounds compared with type I related standard substances (acetylated/malonylated type I saikosaponins were described separately below and not included).

In Frontiers in Chemistry | www.frontiersin.org September 2021 | Volume 9 | Article 747987 which indicated that it comprised one more hydroxyl substituent at the aglycone moiety compared with SSa, compound 42 was identified as clinoposaponin XIV based on a literature review (Miyase and Matsushima, 1997) ; the fragmentation pathway is shown in Supplementary Figure S12 . The same analytical procedure was employed to identify compounds 40, 58, and 71. Compounds 40 and 58 were identified as Sandrosaponin VII (Sánchez-Contreras et al., 2000) and Clinoposaponin XII (Cui et al., 2014) . Compound 71 was initially identified as Bupleruoside I or Buddlejasaponin IV (Barrero et al., 2000; Zhu et al., 2018) ; the two differed only in the order of the saccharide chain and could not be distinguished temporarily. The structures of compounds 40, 58, and 71 are shown in Supplementary Figure S13. Frontiers in Chemistry | www.frontiersin.org September 2021 | Volume 9 | Article 747987 12 4590,761.4481,617.4086,541.3417,471.3444,439.3147 (SS Saikosaponin. "*" indicated that it was compared with a corresponding reference substance; "#" indicated that it was detected in BMS for the first time; "##" indicated that it was a new compound; because the sensitivity of the PDA detector is lower than that of the TOF-MS detector, the UV maximum absorption wavelength of some trace saikosaponins was not detected.). 13, 38, 31, 33, 2, 14, 7, 50, 76, 17, 77, and 79 (Type II) According to the fragment ions, retention times, and maximum UV wavelength (254 nm around), for compounds 13, 38, 31, 33, 2, 14, 7, 50, 76, 17, 77, and 79 (Table 1) , their characteristic mass losses (characteristic loss of 48 Da) and UV maximum absorption wavelengths (approximately 250 nm) are consistent with those of type II saikosaponins, so they have the same aglycones or similar aglycone structures (probably with the more OH or C O substituents at different positions) as type II saikosaponins. 15 type II saikosaponins were identified in this study, including saikosaponin compounds compared with related type II standard substances (acetylated/malonylated type II saikosaponins were described separately below and not included).

In (characteristic loss of type II saikosaponins), it was concluded that these compounds had the same aglycone moieties as SSb 1 / SSb 2 . Based on the combined order of their retention times and the abundance of the m/z 423 fragment ion of compound 31, which was smaller than the m/z 439 fragment ion, and compound 33 showing opposite fragments, it was inferred that compound 31 was SSs (α-OH at position C 16 ) and compound 33 was SSn (β-OH at position C 16 ) (Fang et al., 2017) . The fragmentation pathway is shown in Supplementary Figure S14 . The same analytical procedure was employed to identify compounds 13 and 38 (having the same molecular formula), and compounds 13 and 38 were identified as SSl (α-OH at position C 16 ) and Tibesaikosaponin IV (β-OH at position C 16 ), respectively (Yu et al., 2013; Fang et al., 2017) ; their fragmentation pathways are shown in Supplementary Figure S15 .

Employing the same analytical procedure to analyze the characteristic fragment ions and formulas of compounds 2, 14, 7, 50, and 76, their saccharide chains and aglycone structures could be deduced. Through a literature review, compounds 2 and 14 were identified as SSq or its isomer (Huang et al., 2008) , and the fragmentation pathway of SSq is shown in Supplementary  Figure S16 . Compound 7 was identified as SSr (Barrero et al., 2000) . The fragment ions and formula of compound 50 were the same as those of SSh, which was identified as Saponin BK1 (isomer of SSh) (Sinha et al., 2021) . As for compound 76, its formula and fragment ions were the same as those of SSe (Compound 90, confirmed by the standard substance) and was identified as SSm (Shan et al., 2018) . The structures of compounds 7, 50, and 76 are shown in Supplementary  Figure S17 . ; it was inferred that compounds 17 and 77 had a C O group on the aglycone moiety. Based on other fragment ions, their saccharide chains and aglycone structures could be deduced, and through a review of the related literature, they were identified as Tibesaikosaponin II or its isomer (Fang et al., 2017) ; the fragmentation pathway is shown in Supplementary  Figure S18 . For compound 79, its formula and fragment ions were the same as those of compound 99 (23-hydroxy-13β,28βepoxyolean-11-ene-16-one 3-O-β-D-glucopyranosyl-(1-3)-β-Dfucopyranoside, confirmed by the standard substance), combined with the maximum UV wavelength (250 nm) and a review of the related literature (Li et al., 2015) ; it was identified as 3β,23,28-trihydroxyolean-11,13 (18)-diene-16-one 3-O-β-Dglucopyranosyl-(1-3)-β-D-fucopyranoside, and its structure is shown in Supplementary Figure S19 . 8, 30, 3, 51, 54, 25, and 27 (Type III) According to the fragment ions, retention times, and maximum UV wavelength of compounds 8, 30, 3, 51, 54, 25, and 27 (Table 1) , their characteristic mass losses (characteristic loss of 48 Da) and UV maximum absorption wavelengths (190-220 nm) are consistent with those of type III saikosaponins, and it was inferred that these compounds have the same aglycones or similar aglycones as type III saikosaponins. 13 type III saikosaponins were identified in this study, including saikosaponin compounds compared with related type III standard substances (acetylated/ malonylated type III saikosaponins were described separately below and not included).

Compounds 8 (Liang et al., 2014) . The structure is shown in Supplementary Figure S21 .

Compound 3, based on the fragment ions and formula, was identified as Rotundioside P by reviewing the related literature (Fujioka et al., 2006) , and its fragmentation pathway is shown in Supplementary Figure S22 . The same analytical procedure was employed to identify compounds 25 and 27, which presented an additional hydroxyl substituent at the aglycone moiety compared with compounds SSa/SSd, and combined with the order of the respective retention times, it was speculated that compound 25 was hydroxysaikosaponin a and compound 27 was hydroxysaikosaponin d (Huang et al., 2008) ; both structures are shown in Supplementary Figure S23 . Compounds 51 and 54 shared the same molecular formula and fragment ion pattern as SSf (compound 52, confirmed by the standard substance) and were identified as the isomer of SSf, in which we speculated that the position of the double bond was different from that of SSf.

Characterization of Compounds 6, 9, and 10 (Types IV and VI) (282 nm), it was inferred that compound 6 had a similar aglycone moiety to type IV saikosaponins and was speculated to be an isomer of Bupleuroside V, with the following structure, 3β, 16α, 23,28-Tetrahydroxy-olean-9,12 (13)-dien-29-oic acid 3-O-β-D-glucopyranosyl-(1-3)-β-Dfucopyranoside. Its fragmentation pathway is shown in Supplementary Figure S24 . 3 type IV saikosaponins were identified in this study, including saikosaponin compounds compared with related type IV standard substances.

For compound 10, the number and sequence of its saccharide chain was deduced from the fragment ions (Table 1) , and combined with its maximum UV wavelength (251 nm) and formula, it was identified as Bupleuroside V using a literature review (Yoshikawa, 1997) . Its fragmentation pathway is shown in Supplementary Figure  S25 . The same analytical procedure was employed to identify compound 9, which was identified as 3β,16α,23,28-tetrahydroxyolean-11,13 (18)-dien-30-oicacid-3-O-β-D-glucopyranosyl-(1-2)-β-D-glucopyranosyl-(1-3)-β-D-fucopyranoside (Liang et al., 2013) ; its structure is shown in Supplementary Figure S26 . Compounds 9 and 10 belonged to the type VI saikosaponins.

Characterization of Compounds 1, 5, [11] [12] [15] [16] [19] [20] [21] [22] [23] 26, 29, 32, 35, 41, [44] [45] 49, 60, 68, 72, 74, [94] [95] [96] According to the formula, fragment ions, retention times, and maximum UV wavelength of compounds 1, 5, 11-12, 15-16, 19-23, 26, 29, 32, 35, 41, 44-45, 49, 60, 68, 72, 74, and 94-96 (Table 1) , the number and sequences of the saccharide chain can be deduced. In addition, the structures of the aglycone can be identified through further analysis of their fragment ions.

For compound 1, its molecular ion and fragment ions were 18 Da more than those of compound 8 (SSt), and combined with its formula, this suggested it had an additional hydroxyl substituent at the aglycone moiety compared with SSt; thus, compound 1 was tentatively identified as hydroxysaikosaponin t. Its fragmentation pathway is shown in Supplementary Figure  S27 . The same analytical procedure was employed to identify compounds 23, 11, 35, 44, 60, and 49 . Compound 23 had an additional hydroxyl substituent at the aglycone moiety compared with SSh (compound 56, confirmed by the standard substance); thus, compound 23 was tentatively identified as hydroxysaikosaponin h (11α-hydroxy-SSh). Similarly, compounds 11, 35, 44, and 60 had an additional hydroxyl substituent at the aglycone moiety compared with SSc (compound 47, confirmed by the standard substance); thus, they were tentatively identified as hydroxysaikosaponin c (11αhydroxy-SSc) or its isomer (Ebata et al., 1996) ; for compound 49, its retention time followed that of hydroxysaikosaponin a and hydroxysaikosaponin d ( Compounds 4, 12, 16, 19, and 20 shared the same molecular formula and fragment ions, and they could be deduced to have one less double bond than SSq (compounds 2 and 14), so they were identified as dihydro-SSq or its isomer (such as 11,12dihydro-SSq, 13,18-dihydro-SSq, and other possible isomers); their possible structures are shown in Supplementary Figure S33 .

Using the same approach, compound 41 was deduced to have one less double bond than Tibesaikosaponin I (compound 29), and combined with the maximum UV wavelength (254 nm), it was tentatively identified as Δ 21,22 -Tibesaikosaponin I; the structure is shown in Supplementary Figure S34 . For compounds 29 and 94, it was speculated that their fragmentation pathways were similar to that of Tibesaikosaponin II, but there were no fragment ions produced by the loss of 30 Da, and thus, they were identified as Tibesaikosaponin I or its isomer (Fang et al., 2017) , and presumably the C O group was conjugated with the adjacent olefinic bond, which stabilized the C O group and was not easy to lose; its fragmentation pathway is shown in Supplementary  Figure S35 .

Based on the analysis of the formulas, fragment ions, retention times, and maximum UV wavelengths, combined with a review of the literature, compound 21 was identified as Magnoside B (Haddad et al., 2012) , and its fragmentation pathway is shown in Supplementary Figure S36 . Compound 22 was identified as 3-O-[α-L-Rhamnopyranosyl (1-4)-β-D-glucopyranosyl] oleanolic acid 28-O-β-D-glucopyranosyl ester (Achouri et al., 2017) . Compounds 5 and 15 were identified as (3β,21β,22α)-28-[[2-O-(6-Deoxy-α-L-mannopyranosyl)-β-D-glucopyranosyl]oxy]-21,22-dihydroxyolean-12-en-3-yl 6-O-β-D-glucopyranosyl-β-Dglucopyranoside or its isomers (Xiao et al., 2013) . Compound 68 was identified as (3β,4α,16α)-3,16,23-trihydroxyoleanan-28-yl O-6-deoxy-α-L-mannopyranosyl-(1-4)-O-[β-D-glucopyranosyl-(1-6)]-β-D-glucopyranoside (Luo and Jin, 1991) . Compound 95 was identified as Bupleuroside XI (Yoshikawa, 1997) . All structures are shown in Supplementary Figure S37 .

Characterization of Compounds 18, 36, 39, 43, 46, 53, 55, 57, 59, [61] [62] [63] 66, 67, 69, 78, [80] [81] [82] [83] 85, [87] [88] [91] [92] [93] 98, [100] [101] [102] [103] [104] [106] [107] [108] [109] The mass spectra fragmentation information of the acetylated/ malonylated saikosaponins in the ESI + mode is shown in Supplementary Table S3 . 35 acetylated/malonylated saikosaponins were identified in this study, including saikosaponin compounds compared with related standard substances.

Compounds 18, 53, 55, 57, 59, 61-63, 66-67, 69,78, 80-83, 85, 87-88, 92-93, 98, 100, 102-104, and ), the remaining fragment ions of compounds 81, 87, 88, and 92 were the same as those of SSa/SSd, and their retention times followed those of SSa but were before SSd; thus, they were identified as acetylated derivatives of SSa. For SSa, SSd, SSb 1 , and SSb 2 , the OH group at the 1″ position of the terminal glucose of the saccharide chain was attached to rhamnose, and only four OH groups at positions 2″, 3″, 4″, and 6″ were substituted by an acetyl group. Based on the order of their respective retention times, compounds 81, 87, 88, and 92 were identified as 2″-O-acetyl-SSa, 3″-O-acetyl-SSa, 4″-O-acetyl-SSa, and 6″-O-acetyl-SSa, respectively. Of these, compounds 81 and 92 were confirmed by the standard substance. Similarly, the retention times of compounds 102, 103, 104, and 109 followed SSd, and compound 109 was 6″-O-acetyl-SSd by comparison with the standard substance; according to the order of retention times, the compounds 102, 103, and 104 were inferred to be 2″-O-acetyl-SSd, 3″-O-acetyl-SSd, and 4″-O-acetyl-SSd, respectively. For compounds 78, 83, 93, 98, and 100, the abundance of the m/z 423 fragment ion was smaller than that of the m/z 439 fragment ion, indicating that they were acetylated derivatives of SSb 2 . Combined with the order of their retention times, compounds 78, 83, 98, and 100 were 2″-O-acetyl-SSb 2 , 3″-O-acetyl-SSb 2 , 4″-Oacetyl-SSb 2 , and 6″-O-acetyl-SSb 2 , respectively. The abundance of the m/z 423 fragment ion of compound 93 was slightly higher than that of m/z 439, which indicated that it was an acetylated derivative of SSb 1 (O-acetyl-SSb 1 ). The structures of these acetylated saikosaponins are shown in Supplementary Figure S38 . Figure S40 .

Based on the fragment ions, compounds 67, 70, 80, and 85 were acetylated derivatives of SSb 3 /SSb 4 , and according to their fragment ions in the ESI + mode (Supplementary Table S3) , their acetyl groups were substituted by saccharide chains. Of these, compound 67 had the shortest retention time, which was 2″-Oacetyl-SSb 3 . After comparison with the standard substance, compound 80 was deduced to be 6″-O-acetyl-SSb 3 , while compound 85 had a retention time that followed that of compound 80 and was thus deduced to be 6″-O-acetyl-SSb 4 ; both structures are shown in Supplementary Figure S41 .

The same analytical procedure was employed to identify compounds 36, 39, and 46 in the ESImode, and the abundance of the m/z 423 ([aglycone−48−H] − ) fragment ion was smaller than that of the fragment ion m/z 439 ([aglycone −32−H] − ) for all compounds; thus, they were identified as acetylated derivatives of SSs (α-OH at position C 16 ). Combined with their fragment ions in the ESI + mode (Supplementary Figure S28) , the acetyl groups were all substituted by the terminal glucose of the saccharide chain. According to the order of the respective retention times, compounds 36, 39, and 46 were identified as three of 2‴-Oacetyl-SSs, 3‴-O-acetyl-SSs, 4‴-O-acetyl-SSs, and 6‴-O-acetyl-SSs, and the respective structures are shown in Supplementary Figure S42 . With 6‴-O-acetyl-SSs as a representative example, the fragmentation pathway in ESIis shown in Supplementary  Figure S43 . Similarly, compound 18 was identified as O-acetyl-Bupleuroside V. For compound 61, based on its formula and fragment ions in the ESImode, it was speculated that the C 11 position had an additional OCH 3 substituent at the aglycone compared with O-acetyl-SSs, according to its fragment ion pattern in ESI + (Supplementary Table S3) , which indicated that an acetyl group was substituted by the aglycone; it was identified as 23-O-acetyl-(11α-methoxyl-SSs), and its fragmentation pathway in the ESImode is shown in Supplementary Figure S44 .

Compounds 106 , and the remaining fragment ions were the same as those of SSa/SSd, which indicated that they were diacetyl derivatization products of SSa/SSd. Supplementary Table S3 indicated that their acetyl groups were all substituted by the saccharide chain; according to their retention times, compounds 106 and 108 all followed the SSd; thus, they were identified as O-diacetyl-SSd.

For compounds 82 and 101 in the ESImode, m/z 821 ([M−44−H] -) and m/z 779 ([M−86−H] -) fragment ions were produced, and the remaining fragment ions were the same as those of SSa/SSd, which indicated that they were malonylated derivatives of SSa/SSd. As shown in Supplementary Table S3 , the malonyl groups were all substituted by the saccharide chain, and after assessing their retention time, compound 82 followed SSa and preceded SSd, and compound 101 followed SSd; thus, compound 82 was O-malonyl-SSa and compound 101 was O-malonyl-SSd. Similarly, compound 43 was identified as O-malony-hydroxysaikosaponin c.

Compounds 91 Table S3 indicated that their malonyl and acetyl groups were substituted by the saccharide chain. Analyzing their retention times, compound 91 followed SSa and preceded SSd, and compound 107 followed SSd; thus, the former was O-malonylacetyl-SSa, and the latter was O-malonyl-acetyl-SSd.

The same sample processing and UPLC-PDA-Q/TOF-MS detection methods were applied to identify saikosaponins of BC and BMW, which were then compared with BMS, to explore the similarities and differences of saikosaponins from three Bupleurum species. As shown in Supplementary Figure  S45 , except for a few individual saikosaponins (compounds 15, 84, and 96 were not found in BC, while compounds 15, 83, 84, 96, and 108 were not found in BMW), the saikosaponins in BMS were almost the same as those in BC and BMW, which have a material basis as an alternative variety of BC and BMW.

In this study, we used UPLC-PDA-Q/TOF-MS technology to identify saikosaponins from Bupleurum species. In previous studies on identification of saikosaponins by UPLC-MS, most of the sample-processing methods used organic reagents such as methanol to crudely extract the saikosaponins from samples, and the saikosaponin components were not further enriched and purified, which may cause omission and interference in the detection of saikosaponin components. In most studies, only a small amount of saikosaponin standards (0-12 standards) were used for analysis; the fragmentation pathways, characteristic loss, retention times, and UV spectral features of saikosaponin standards were not thoroughly analyzed and comprehensively summarized, so not only could some saikosaponins and their isomers not be accurately distinguished and structurally identified but also the types and numbers of saikosaponins identified in Bupleurum species were not many, usually dozens of them, and new saikosaponins are rarely found. Compared with previous studies on the identification of saikosaponins by UPLC-MS, the significance and advantages of our established method are summarized below. First, an effective sample-processing method was established, which not only purifies and enriches the saikosaponins but can also eliminate the interference of non-saikosaponins for subsequent analysis. Second, we combined DDA and DIA modes to complement each other and more accurately and comprehensively scanned and analyzed parent ions and product fragment ions of saikosaponins. Third, our study was the most comprehensive characterization of saikosaponins in Bupleurum species to date. In this study, the mass spectrometric fragmentation rules, UV spectral features, and chromatographic behaviors of different types of saikosaponins were first investigated and fully summarized using as many as 24 saikosaponin standard substances, the reliability of isomer structures was greatly improved, and a total of 109 saikosaponins were identified, of which 25 were new compounds. Fourth, this paper analyzed and summarized the characteristic fragment ions and fragmentation pathways of saikosaponins containing carbonyl groups and type IV saikosaponins for the first time, based on which these types of saikosaponins were identified, which is of great significance to the expansion of the identification of saikosaponin types.

Saikosaponins are the most important and prominent medicinal components in Bupleurum medicinal materials; thus, it is important to identify and analyze saikosaponins in BMS and other Bupleurum species. In this study, the fragmentation pathways of different types of saikosaponins were investigated by UPLC-PDA-Q/TOF-MS. Based on accurate exact mass and the elemental compositions of the fragment ions of 24 standard substances, the mass spectrometric fragmentation pathways, UV spectral features, and chromatographic behaviors were proposed and applied to identify the saikosaponins in extracts from BMS. A total of 109 saikosaponins were identified and characterized, of which 25 were new compounds and 60 were first discovered in BMS. Further studies revealed that the saikosaponins in BMS were almost the same as those in BC and BMW, which indicates that there is a rationale for BMS to be used as an alternative to BC and BMW as medicine. This study provided a foundation for further quality control, pharmacological and pharmacodynamic studies, and the development and application of saikosaponins extracted from BMS and present in other Bupleurum species. In the future, we will also conduct detailed study regarding the remaining components of BMS, such as flavonoids, volatile oils, and polysaccharides.

The original contributions presented in the study are included in the article/Supplementary Material; further inquiries can be directed to the corresponding authors.

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WL conceived, designed, and performed the experiments, analyzed the data, and wrote the manuscript. RK, XG, YW, and WJ assisted in performing the experiments. XC, FW, and SM revised the manuscript. All authors read and approved the manuscript. 

The Supplementary Material for this article can be found online at: https://www.frontiersin.org/articles/10.3389/fchem.2021.747987/ full#supplementary-material Conflict of Interest: The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest.