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Review

Apiaceae Medicinal Plants in China: A Review of Traditional Uses, Phytochemistry, Bolting and Flowering (BF), and BF Control Methods

by
Meiling Li
1,
Min Li
1,
Li Wang
2,
Mengfei Li
1,* and
Jianhe Wei
3,*
1
State Key Laboratory of Arid Land Crop Science, Gansu Agricultural University, Lanzhou 730070, China
2
Genome Analysis Laboratory of the Ministry of Agriculture and Rural Affairs, Agricultural Genomics Institute at Shenzhen, Chinese Academy of Agricultural Sciences, Shenzhen Branch, Guangdong Laboratory of Lingnan Modern Agriculture, Shenzhen 518120, China
3
Institute of Medicinal Plant Development, Chinese Academy of Medical Sciences and Peking Union Medical College, Beijing 100193, China
*
Authors to whom correspondence should be addressed.
Molecules 2023, 28(11), 4384; https://doi.org/10.3390/molecules28114384
Submission received: 30 April 2023 / Revised: 20 May 2023 / Accepted: 25 May 2023 / Published: 27 May 2023
(This article belongs to the Special Issue Analysis and Identification of Natural Product Extracts for Use in Medicine, Public Health and Agriculture)
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Abstract

:
Apiaceae plants have been widely used in traditional Chinese medicine (TCM) for the removing dampness, relieving superficies, and dispelling cold, etc. In order to exploit potential applications as well as improve the yield and quality of Apiaceae medicinal plants (AMPs), the traditional use, modern pharmacological use, phytochemistry, effect of bolting and flowering (BF), and approaches for controlling BF were summarized. Currently, about 228 AMPs have been recorded as TCMs, with 6 medicinal parts, 79 traditional uses, 62 modern pharmacological uses, and 5 main kinds of metabolites. Three different degrees (i.e., significantly affected, affected to some extent, and not significantly affected) could be classed based on the yield and quality. Although the BF of some plants (e.g., Angelica sinensis) could be effectively controlled by standard cultivation techniques, the mechanism of BF has not yet been systemically revealed. This review will provide useful references for the reasonable exploration and high-quality production of AMPs.

Graphical Abstract

1. Introduction

Apiaceae (syn. Umbelliferae) is one of the largest angiosperm families. It includes 300 genera (3000 species) globally and 100 genera (614 species) in China [1]. Apiaceae plants have been widely used in healthcare, nutrition, the food industry, and other fields [2]. Currently, 55 genera (230 species) of Apiaceae plants have been used as medicinal plants, and over 20 species have been widely used as traditional Chinese medicines (TCMs) [3]. Extensive studies have demonstrated that Apiaceae medicinal plants (AMPs) present a variety of pharmacological properties for the treatment of central nervous system, cardiovascular, and respiratory system diseases, amongst others [1,4]. These pharmacological activities are largely associated with metabolites such as polysaccharides, alkaloids, phenylpropanoids (simple phenylpropanoids and coumarins), flavonoids, and polyene alkynes [1,5,6].
In China, Apiaceae plants have been primarily used as traditional medicines for relaxing tendons, activating blood, relieving superficial wounds, treating colds, etc. [1,2]. For example, rhizomatous and whole plants are mainly used for the treatment of common colds, coughs, asthma, rheumatic arthralgia, ulcers, and pyogenes infections; fruits are mainly used for regulating vital energy, promoting digestion, relieving abdominal pain, and treating parasites [1,2].
The occurrence of bolting and flowering (BF) plays a critical role in the transition from vegetative growth to reproductive development in the plant life cycle [7]. However, BF significantly reduces the accumulation of metabolites in vegetative organs, which ultimately leads to the lignification of rhizomes and/or roots such as sugar beet [8], lettuce [9], and Chinese cabbage [10]. In particular, it common that BF significantly reduces the yield and quality of the rhizomatous AMPs [11]. Extensive studies have demonstrated that BF is regulated by both internal factors (e.g., germplasm resource, seedling size, and plant age) and external factors (e.g., vernalization, photoperiodism, and environmental stresses) [12]. To date, the BF of most rhizomatous AMPs have not been effectively controlled [11,13].
In order to form a comprehensive understanding of the current status of AMPs in China, herein, the progress on traditional use, phytochemistry, BF, and controlling approaches are summarized. This review will provide useful references for the efficient cultivation and quality improvement of AMPs.

2. Materials and Methods

Information on AMPs was attained using scientific databases (i.e., PubMed, Web of Science, Springer, and CNKI), using the following keywords: Apiaceae plant, traditional use, phytochemistry, BF, and lignification. Additional information was collected from ethnobotanical studies that mainly focused on the “Flora of China” and local classical literature, such as “Divine Husbandman’s Classic of the Materia Medica (Shen Nong Ben Cao Jing)”, “Compendium of Materia Medica”, “Illustrated Book on Plants”, “Collection of National Chinese Herbal Medicine”, and “Pharmacopoeia of the People’s Republic of China” (2020). The names of all plants correspond to the database Catalogue of Life China. Chemical structures were drawn using ChemDraw 21.0.0 software.

3. Apiaceae Medicinal Plants (AMPs)

Apiaceae plants have been traditionally used as medicines in China for ca. 2400 years (Figure 1). In 390–278 BC, three Apiaceae plants, including Angelica dahurica, Ligusticum chuanxiong, and Cnidium monnieri, were first recorded as medicines in “Sorrow after Departure” [1,2]. With the progress of Chinese civilization, ca. 100 Apiaceae plants were historically recorded as medicines. Specifically, 12 AMPs (e.g., Angelica decursiva, Bupleurum chinense, and Centella asiatica) were recorded in the known herbal text of China, the “Divine Husbandman’s Classic of the Materia Medica (Shen Nong Ben Cao Jing)” in 1st and 2nd century AD [14]. In 1578 and 1848, 24 and 31 AMPs were respectively recorded in the “Compendium of Materia Medica and Illustrated Book on Plants” [15]. In the 21st century, the number of AMPs has been continually increasing, up to 93 species recorded in the “Flora of China” in 2002 [16], and 96 species in the “Collection of National Chinese Herbal Medicine” in 2014 [17]. In recent years, 22 species were recorded in the “Pharmacopoeia of the People’s Republic of China” [18]. Specifically, 18 species are used with rhizomes and/or roots (Table 1).

4. Classification of AMPs Species

To our best knowledge, a total of 228 AMPs used as TCMs were collected from previously published studies and books (Table 1). Based on the traditionally used medicinal parts, the 228 AMPs were categorized into six classes, including 51 species (21 genera) used with the whole plants (i.e., rhizome and/or root, stem, and leaf), 184 species (44 genera) used with rhizomes and/or roots, 5 species (5 genera) used with stems, 9 species (8 genera) used with leaves, 17 species (14 genera) used with fruits, and 1 species (single genus) used with seeds.
Specifically, the 51 species (21 genera) used with the whole plants include Anethum, Anthriscus, Apium, Bupleurum, Centella, Conium, Coriandrum, Cryptotaenia, Eryngium, Ferula, Foeniculum, Hydrocotyle, Oenanthe, Peucedanum, Pimpinella, Pleurospermum, Pternopetalum, Sanicula, Sium, Spuriopimpinella, and Torilis genera. In particular, Sanicula (e.g., S. astrantiifolia, S. caerulescens, S. chinensis), Hydrocotyle (e.g., H. himalaica, H. hookeri, and H. nepalensis), and Pimpinella (e.g., P. candolleana, P. coriacea, and P. diversifolia) genera plants are usually used as whole plants.
The 184 species (44 genera) used with the rhizomes and/or roots, which make up the majority of AMPs, include Angelica, Anthriscus, Apium, Archangelica, Bupleurum, Carum, Changium, Chuanminshen, Cicuta, Cnidium, Conioselinum, Daucus, Eriocycla, Ferula, Foeniculum, Glehnia, Heracleum, Hymenidium, Kitagawia, Levisticum, Libanotis, Ligusticopsis, Ligusticum, Meeboldia, Nothosmyrnium, Oenanthe, Osmorhiza, Ostericum, Peucedanum, Phlojodicarpus, Physospermopsis, Pimpinella, Pleurospermum, Pternopetalum, Sanicula, Saposhnikovia, Selinum, Semenovia, Seseli, Seselopsis, Spuriopimpinella, Tongoloa, Torilis, and Vicatia genera. Specifically, Angelica (e.g., A. biserrata, A. dahurica, and A. sinensis), Bupleurum (e.g., B. bicaule, B. chinense, and B. scorzonerifolium), and Ligusticum (L. chuanxiong, L. jeholense, and L. sinense) genera plants are usually used as rhizomes and/or roots.
The 5 species (5 genera) used with the stems include Aegopodium (A. alpestre), Coriandrum (C. sativum), Foeniculum (F. vulgare), Ligusticum (L. chuanxiong), and Oenanthe (O. javanica); the 9 species (8 genera) used with the leaves include Aegopodium (A. alpestre), Anethum (A. graveolens), Angelica (A. morii), Anthriscus (A. nemorosa and A. sylvestris), Carum (C. carvi), Daucus (D. carota), Foeniculum (F. vulgare), and Ligusticum (L. chuanxiong); the 17 species (14 genera) used with the fruits include: Ammi (A. majus), Carum (C. buriaticum and C. carvi), Cnidium (C. monnieri), Coriandrum (C. sativum), Cuminum (C. cyminum), Cyclorhiza (C. peucedanifolia), Daucus (D. carota L. and D. carota var. Carota), Pimpinella (P. anisum), Trachyspermum (T. ammi), and Visnaga (V. daucoides) genera; the single genera used with the seeds is Ferula (F. bungeana) (Table 1).

5. Traditional Uses

As is shown in Table 1, distinct traditional uses of the 228 AMPs were recorded. Based on their clinical agents, a total of 79 traditional uses are enriched, with 40 species contributing to the treatment of relieving pain, 36 species to the treatment of dispelling wind; and 21 species to the treatment of eliminating dampness (Figure 2).
Moreover, the AMPs were also widely used as “ethnodrugs” for ethnic minorities in China. For example, Carum carvi was used as Tibetan medicine for the treatment of dispelling wind and eliminating dampness, as well as treating cat fever and joint pain [86]; Trachyspermum ammi [236] was used as Uygur medicine for the treatment of eliminating cold damp, dispelling coldness, and promoting digestion; Angelica acutiloba was used in Korean medicine for the treatment of strengthening the spleen, enriching blood, stopping bleeding, and promoting coronary circulation [237]; Angelica sinensis was used as medicine for the Tujia minority for the treatment of enriching the blood, treating dysmenorrheal, and relaxing the bowel [238]; and Chuanminshen violaceum was used as a geo-authentic medicine of Sichuan province for the treatment of moistening the lungs, treating phlegm, and nourishing the spleen and stomach [89].
Meanwhile, AMPs combined with other herbs have also been applied for thousands of years [239]. For example, the Decoction of Notopterygium for Rheumatism is a famous Chinese prescription and is composed of Notopterygium incisum, Angelica biserrata, Ligusticum sinense, Eryngium foetidum, and Ligusticum chuanxiong, etc.; it has been widely used for the treatment of exopathogenic wind-cold, rheumatism, headache, and pantalgia [94]. The Xinyisan that is composed of Yulania liliiflora, Actaea cimicifuga, Angelica dahurica, Eryngium foetidum, Ligusticum sinense, etc., has been widely used for the treatment of deficiency of pulmonary qi and nasal obstruction due to wind-cold pathogens and damp-heat in the lung channel [94,168]. The Shiquan Dabu Wan of Angelica sinensis that is recorded in the “Pharmacopoeia of the People’s Republic of China” has been mainly used for the treatment of pallor, fatigability, and palpitations [240]. The Juanbi Tang of Notopterygium incisum and Angelica biserrata that is recorded in “Medical Words” (Qing dynasty) has been mainly used for treatment of arthralgia due to wind cold-dampness [121].

6. Modern Pharmacological Uses

Modern pharmacological research on the 228 AMPs is summarized in Table 1. Based on the pharmacological effects, a total of 62 modern uses are identified (Figure 3), with 36 species showing anti-inflammatory activity, 20 species showing antioxidant activity, and 16 species showing antitumor activity. In addition, other modern uses are also identified, such as antitumor, bacteriostatic, and analgesic. These modern pharmaceutical properties have been demonstrated to be associated with bioactive metabolites, and several metabolites have been found to be co-existent in the TCMs [241,242].
Specifically, sesquiterpene-coumarin, such as (3′S, 5′S, 8′R, 9′S, 10′R)-kellerin, gummosin, galbanic acid, and methyl galbanate from Ferula sinkiangensis resin, showed anti-neuroinflammatory effects and might be a potential natural therapeutic agent for Alzheimer’s disease [243]. The supercritical carbon dioxide extracts from Apium graveolens showed antibacterial effects, with the highest inhibitory activity against Bacillus cereus [244,245]. In vitro, the antitumor activity of AMPs have been identified; for example, the ferulin B and C in Ferula ferulaeoides rhizomes could restrain the multiplication of HepG2 stomach cancer cell lines, and 2,3-dihydro-7-hydroxyl-2R*, 3R*-dimethyl-2-[4,8-dimethyl-3(E),7-nonadienyl]-furo [3,2-c] coumarin could restrain the proliferation of HepG2, MCF-7, and C6 cancer cell lines [107,246]. In addition, the osthole in Angelica biserrata could restrain the multiplication of human gastric cancer cell lines MKN-45 and BGC-823, human lung adenocarcinoma cell line A549, human mammary carcinoma cell line MCF-7, and human colon carcinoma cell line LOVO [247]. The antioxidative activity of AMPs has been also identified; for example, the imperatorin, oxypeucedanin hydrate, and bergaptol in Angelica dahurica exhibited DPPH scavenging activity [30], hydromethanolic extracts from Pimpinella anisum exhibited free radical scavenging activity [248], and water-soluble polysaccharides in Chuanminshen violaceum scavenged DPPH, hydroxyl, and superoxide anion radicals [91].

7. Phytochemistry

As is shown in Table 1, hundreds of bioactive metabolites have been identified from the 228 AMPs [1,249]. Based on their chemical structures, these metabolites can be categorized into five main classes: (1) polysaccharides, (2) alkaloids, (3) phenylpropanoids, (4) flavonoids, and (5) terpenoids (Figure 4).
Among the 22 AMPs recorded in the “Pharmacopoeia of the People’s Republic of China” [18], 18 secondary metabolites in the 17 AMPs (e.g., Angelica biserrata, Bupleurum chinense DC., and Centella asiatica) (Figure 5) were described as quality control indicators, which include: 10 phenylpropanoids (i.e., osthole, columbianadin, imperatorin, isoimperatorin, nodakenin, ferulic acid, trans-anethole, notopterol, praeruptorin A, and praeruptorin B), 4 terpenoids (i.e., saikosaponin a, saikosaponin d, asiaticoside, and madecassoside), 2 chromones (i.e., prim-O-glucosylcimifugin and 5-O-methylvisammioside), and 2 phthalides (i.e., ligustilide and levistilide A); a specific quality marker has not been reported for the other 5 AMPs (e.g., Changium smyrnioides, Daucus carota L., and Glehnia littoralis) (Table 2).

7.1. Polysaccharides

Polysaccharides are the largest components of biomass and account for ca. 90% of the carbohydrates in plants [250]. Studies have demonstrated that polysaccharides in medicinal plants are indispensable bioactive compounds, presenting uniquely pharmacological effects such as immunomodulatory, hypoglycemic, antitumor, anti-diabetic, and antioxidant effects, amongst others, with few side effects or adverse drug reactions [251,252]. To date, polysaccharides in the 228 AMPs have also been identified, showing multiple pharmacological effects. For example, polysaccharides in Angelica sinensis present hematopoietic, antitumor, and liver protection effects [239,253]; polysaccharides in Angelica dahurica protect spleen lymphocytes, natural killer cells, and procoagulants [254,255]; and polysaccharides in Bupleurum chinense and Bupleurum smithii present the effect of macrophage modulation, kidney protection, and inflammatory alleviation [256,257,258].

7.2. Alkaloids

About 27,000 alkaloids presenting as water-soluble salts of organic acids, esters, and combined with tannins or sugars have been found in plants [259]. Many alkaloids are valuable medicinal agents that can be utilized to treat various diseases, including malaria, diabetes, cancer, cardiac dysfunction, blood clotting–related diseases, etc. [260,261,262]. Alkaloids in the 228 AMPs mainly exist in the Ligusticum, Apium, Conium, and Cuminum genera [249]. Pharmacological studies have demonstrated that alkaloids in Ligusticum chuanxiong show the activity of inhibiting myocardial fibrosis, protecting ischemic myocardium, and relieving cerebral ischemia-reperfusion injury [151,263,264]. A novel alkaloid 2-pentylpiperidine known as conmaculatin in Conium maculatum shows strong peripheral and central antinociceptive activity [265]. Some alkaloids have been identified to show antidepressant activity, such as berberine in Berberis aristata, strictosidine acid in Psychotria myriantha, and Anonaine in Annona cherimolia; these could be explored as an emerging therapeutic alternative for the treatment of depression.

7.3. Phenylpropanoids

Phenylpropanoids are a large class of secondary metabolites biosynthesized from amino acids, phenylalanine, and tyrosine [266]. Over 8000 aromatic metabolites of the phenylpropanoids have been identified in plants. These include simple phenylpropanoids (propenyl benzene, phenylpropionic acid, and phenylpropyl alcohol), coumarins, lignins, lignans, and flavonoids [267].

7.3.1. Simple Phenylpropanoids

To date, limited simple phenylpropanoids have been identified from AMPs, including three phenylpropanoids (trans-isoelemicin, sarisan, and trans-isomyristicin) in the roots of Ligusticum mutellina [268]. Ferulic acid, one of the phenylpropionic acids, is an important bioactive metabolite of AMPs; it mainly exists in Angelica, Ligusticum, Ferula, and Pleurospermum genera [239,269,270]. Pharmacological studies have demonstrated that the ferulic acid in Angelica sinensis shows strong properties in inhibiting platelet aggregation, increasing coronary blood flow, and stimulating smooth muscle [271,272]; the ferulic acid in Angelica acutiloba shows antidiabetic, immunostimulant, antiinfammatory, antimicrobial, anti-arrhythmic, and antithrombotic activity [273]; and the ferulic acid in Ligusticum tenuissimum shows anti-melanogenic and anti-oxidative effects [274].

7.3.2. Coumarins

Coumarins are the most widespread in 20 genera of AMPs (e.g., Angelica, Bupleurum, and Peucedanum) and mainly include simple coumarins, pyranocoumarins, and furocoumarins [56,275,276]. In recent years, distinct coumarins have been identified from AMPs, such as 99 coumarins in Ferula [277], 116 coumarins in Angelica decursiva and Peucedanum praeruptorum [180], and 9 coumarins in Angelica dahurica [278]. Furthermore, 8 coumarins were selected as quality markers, including osthole (1) in Angelica biserrata and Cnidium monnieri; columbianadin (2) in Angelica biserrata; imperatorin (3) in Angelica dahurica and Angelica dahurica cv. Hangbaizhi; isoimperatorin (4) in Angelica dahurica, Angelica dahurica cv. Hangbaizhi, Notopterygium franchetii, and Notopterygium incisum; nodakenin (5) in Angelica decursiva, Notopterygium franchetii, and Notopterygium incisum; notopterol (8) in Notopterygium franchetii and Notopterygium incisum; and praeruptorin A (9) and praeruptorin B (10) in Peucedanum praeruptorum (see Table 2 and Figure 5) [18].
To date, various biological activities of coumarins have been demonstrated, including antifungal, antimicrobial, antiviral, anti-cancerous, antitumor, anti-inflammatory, anti-filarial, enzyme inhibitory, antiaflatoxigenic, analgesic, antioxidant, and oestrogenic [279,280,281,282]. For example, coumarins are recognized as the main bioactive constituents in Peucedani genus and play critical roles in relieving cough and asthma, strengthening heart function, as well as preventing and treating cardiovascular diseases such as nodakenin, (+)-praeruptorin B, and praeruptorin C [283]; imperatorin oxypeucedanin hydrate, xanthotoxol, bergaptol, 5-methoxy-8-hydroxypsoralen, isoimperatorin, phelloptorin, and pabularinone in Angelica dahurica exhibit moderate DPPH scavenging activity, strong ABTS·+ scavenging activity, and significant inhibition on HepG2 cells, which could be explored as new and potential natural antioxidants and cancer prevention agents [30]; pabulenol and osthol extracts from Angelica genuflexa show anti-platelet and anti-coagulant components [38]; and decursinol angelate in Angelica gigas shows platelet aggregation and blood coagulation activity [38].

7.4. Flavonoids

Flavonoids are a group of the most abundant secondary metabolites in plants [266]. Generally, flavonoids can be further categorized into eight subgroups, including flavones (e.g., apigenin, luteolin, and baicalein), flavonols (e.g., kaempferol, quercetin, and myricetin), flavanones (e.g., naringenin, hesperitin, and liquiritigenin), flavanonols (e.g., dihydrokaempferol, dihydromyricetin, and dihydroquercetin), isoflavones (e.g., daidzein, purerarin, and peterocarpin), aurones, anthocyanidins, and proanthocyanidins [284,285,286]. In recent years, flavonoids have been identified from AMPs, such as 6 flavonoids (e.g., luteolin, isoquercitrin, and rutin) in Ferula [107], 12 flavonoids (e.g., quercetin-3-O-rutinoside, kaempferol-3,7-di-O-rhamnoside, quercetin-3-O-arabinoside) in Bupleurum [287], and 18 flavonoids (e.g., rutin, quercetin, and quercitrin) in Hydrocotyle [135].
To date, various biological activities of flavonoids have been demonstrated, including antioxidant, antiinflammatory, antidiabetic, anticancer, antiobesity, and cardioprotective [284,288]. For example, the apigenin in Apium graveolens shows anticancer properties [21], flavonoids in Pimpinella diversifolia DC., Anthriscus sylvestris, and Sanicula astrantiifolia show antioxidant effects [197,289], and quercetin and its metabolites show vasodilator effects, with selectivity toward the resistance vessels [290].

7.5. Terpenoids

About 25,000 terpenoids have been reported in plants; they are diverse secondary metabolites containing three subgroups, including monoterpenoids, sesquiterpenes, and triterpenoids [291]. To date, terpenoids have been also identified in AMPs, such as 4 terpenoids (e.g., angelicoidenol, pregnenolone, and β-sitosterol) in Pleurospermum [142], 75 terpenoids (e.g., myrcene, farnesene, and xiongterpene) in Ligusticum [141], 109 terpenoids (e.g., nerolidol, guaiol, and ferulactone A) in Ferula [277], and 13 triterpenoids (e.g., ranuncoside, oleanane, and barrigenol) in Hydrocotyle sibthorpioides Lam. [136]. Specifically, saikosaponin triterpenes constitute the main class of secondary metabolites in the genus Bupleurum, with more than 90 saponins (e.g., saikosaponin a, b, and c) isolated [64,292].
Studies have found that terpenoids possess various biological activities, including anti-inflammatory, anti-oxidative, anti-fibrosis, antitumor, anti-Alzheimer’s disease, and anti-depression activities [293,294]. For example, the xiongterpene in Ligusticum chuanxiong shows insecticide effects [151], the asiaticoside in Centella asiatica shows antitumor properties [295], and the saikosaponin d in Bupleurum chinense DC. and Bupleurum scorzonerifolium show the effects of reducing blood glucose, inhibiting inflammation, and reducing insulin resistance [296].

7.6. Other Compounds

Chromones and phthalides also exist in AMPs and show pharmacological properties. Specifically, phthalides (e.g., ligustilide, n-butylidenephthalide, and Z-ligustilide) in Angelica sinensis show the effect of inhibiting vasodilation, decreasing platelet aggregation, as well as exerting analgesic, anti-inflammatory, and anti-proliferative effects [239]; butylphthalide in Ligusticum sinense shows anti-inflammatory and antithrombus effects, dilates blood vessels, and improves brain microcirculation and anti-myocardial ischemia [155].
In terms of chromones, 3 chromones (i.e., 5 thydroxy 2 [(angebyloxy) mehyI] fuan [3, 2′: 6, 7] chrmone, angeliticin A, and noreugenin) in Angelica polymorpha [297], 10 chromones (e.g., cnidimoside A, cnidimol B, and peucenin) in Cnidiummonnieri (L.) Cuss. [93], and 22 chromones (e.g., edebouriellol, hamaudol, and 3′(R)-(+)-hamaudol) in Saposhnikovia divaricate [218] have been identified. Studies have found that two chromones 3′S-(-)-O-acetylhamaudol and (±)-hamaudol in Angelica morii show the effect of inhibiting Ca2+ influx of vascular smooth muscle [298], prim-O-glucosylcimifugin and 5-O-methylvisammioside show antipyretic, analgesic, and anti-inflammatory effects [299], and chromones in Bupleurum multinerve show analgesic effects [300].

8. Effect of Bolting and Flowering (BF) on Yield and Quality

Previous studies have repeatedly emphasized that BF reduces the yield and quality of plants, especially in rhizomatous medicinal plants [11]. Here, a total of 38 rhizomatous plants that have been reported in the 228 AMPs are associated with BF (Table 3). Based on the effect degree of BF on the yield and quality, 38 rhizomatous AMPs belonging to 17 genera can be categorized into 3 classes: (1) BF significantly affects the yield and quality of 14 AMPs (i.e., Angelica acutiloba, Angelica biserrata, Angelica dahurica, Angelica dahurica cv. Hangbaizhi, Angelica decursiva, Angelica polymorpha, Angelica sinensis, Daucus carota, Heracleum hemsleyanum, Heracleum rapula, Libanotis iliensis, Libanotis seseloides, Peucedanum praeruptorum, and Saposhnikovia divaricata), and their rhizomes and/or roots are wholly lignified and cannot be used for clinical application; (2) BF affects the yield of 11 AMPs (i.e., Angelica gigas, Bupleurum chinense, Bupleurum scorzonerifolium, Changium smyrnioides, Chuanminshen violaceum, Glehnia littoralis, Ligusticum chuanxiong, Ligusticum jeholense, Ligusticum sinense, Notopterygium franchetii, and Notopterygium incisum), though their rhizomes or roots can be used as medicine to some extent; (3) BF has no significant effect on the yield and quality of 13 AMPs (i.e., Angelica sylvestris, Cicuta virosa, Ferula ferulaeoides, Ferula fukanensis, Ferula lehmannii, Ferula olivacea, Ferula sinkiangensis, Ferula teterrima, Levisticum officinale, Libanotis buchtormensis, Libanotis lancifolia, Libanotis spodotrichoma, and Pimpinella candolleana), and their rhizomes or roots can be used as medicine (Figure 6).
For example, for class (1) after BF, there was a 8.3- and 16.1-fold reduction of dry weight and quality marker ferulic acid content in Angelica sinensis [301] and a 1.5- and 1.5-fold reduction of dry weight and quality marker isoimperatorin content in Angelica dahurica [302]. For class (2), there was a 1.34-fold reduction of saikosaponinsands, while no significant change of dry weight in Bupleurum chinense was seen [303,304]; and a 2.0- and 1.7-fold reduction of dry weigh and polysaccharide content in Changium smyrnioides [305]. For class (3), there was no reduction of the yield and quality of the 13 AMPs at the harvest stages [19].

9. Approaches to Control BF

Generally, most Apiaceae plants are “low-temperature and long-day” perennial herbs; in other words, the plants must experience vernalization (i.e., an extended period of cool weather at 0 to 10 °C) and long days (>12 h daylight) to induce BF. Examples include Angelica sinensis [325], Daucus carota [326], and Coriandrum sativum [327].
Table 4 shows the approaches to inhibit BF of 24 AMPs. For example, the bolting rate of Angelica sinensis can be significantly decreased by planting the green stem cultivar (Mingui 2) instead of the purple stem cultivar (Mingui 1) [328], selecting smaller seedlings (i.e., root-shoulder diameter <0.55 cm) instead of larger seedlings [329,330], storing the seedlings at freezing temperature (i.e., <0 °C) during the overwinter stage [325], shading the plants under sunshade (i.e., >40%) during growth stage [331], and providing the plants with good growth conditions (e.g., plant intensity, nutrient and water balance) [332]. The bolting rate of Angelica dahurica can be significantly decreased through planting pure breeds [333], selecting immature seeds for seeding [308], increasing potassic fertilizer while decreasing nitrogen and phosphorus fertilizers [334], and planting using standard techniques [335]. The bolting rate of Saposhnikovia divaricata can also be significantly decreased by controlling the sunshade [336], sowing date [337], and planting density [338], and preventing excessive growth [336].
To inhibit the occurrence of BF in AMPs, several measures can be used, including breeding new cultivars, controlling the seedling age and size to delay the transition from vegetative growth to flowering, storing seedlings at freezing temperatures to avoid vernalization, growing the plants under sunshade to avoid long-day photoperiodism, and planting with standard techniques to reduce pests and diseases (Figure 7).

10. The Mechanism of BF Inducing the Rhizome Lignification

Extensive experiments have demonstrated that BF induces the lignification of fleshy rhizomes and enhances the degradation of metabolites [11,13,328]. Studies on anatomical structures reveal that the ratio of secondary phloem to secondary xylem respectively changes from 2:1 to 1:10 and 2/5–1/2 to 1/2–3/4 for the rhizomes of Angelica sinensis and Angelica dahurica before and after BF; meanwhile, the number of secretory cells producing essential oils significantly decreased [368,369]. Studies have found that the Early Bolting In Short Day (EBS) acts as a negative transcriptional regulator, preventing premature flowering of Arabidopsis thaliana, and co-enrichment of a subset of EBS-associated genes with H3K4me3, H3K27me3, and Polycomb repressor complex 2 has been observed [370]; a potential genetic resource for radish late-bolting breeding with introgression of the RsVRN1In-536 insertion allele into the early-bolting genotype could contribute to delayed bolting time of Raphanus sativus [371]; and peroxidases (PRXs) involved in lignin monomer biosynthesis were found to be down-regulated in Peucedanum praeruptorum at the bolting stage [372].
As is known, lignin biosynthesis belongs to the general phenylpropanoid pathway, which starts from phenylalanine and is catalyzed by a series of enzymes [13,373]. Specifically, phenylalanine is catalyzed to form p-Coumaroyl CoA sequentially through the three enzymes phenylalanine ammonia lyase (PAL), cinnamate 4-hydroxylase (C4H), and 4-coumarate-CoA ligase (4CL). Lignin biosynthesis is synthesized via three sub-pathways, including the following: (1) lignins are catalyzed to from p-Coumaroyl CoA sequentially through the three enzymes cinnamoyl-CoA reductases (CCR), cinnamyl alcohol dehydrogenases (CAD), and laccases (LACs), and then coniferyl aldehyde is catalyzed to from p-Coumaroyl CoA sequentially through the four enzymes hydroxycinnamoyl shikimate/quinate transferase (HCT), p-coumarate 3-hydroxylase (C3H), caffeoyl-CoA 3-O-methyltransferase (CCOMT), and CCR; (2) lignins are catalyzed to from coniferyl aldehyde sequentially through the two enzymes CAD and LAC; (3) lignins are catalyzed to from coniferyl aldehyde sequentially through the three enzymes ferulate 5-hydroxylase (F5H), caffeic acid 3-O-methyltransferase (COMT), and LACs (Figure 8).
Although lignin biosynthesis has been depicted, studies on the mechanism of BF inducing rhizome lignification are still limited. To date, the mechanism of BF affecting Angelica sinensis has been revealed, with the expression level of genes (e.g., PAL1, 4CLs, HCT, CAD1, and LACs) significantly upregulated at the stem-node forming and elongating stage compared with the stem-node pre-differentiation stage, leading to the reduction of accumulation of secondary metabolites (i.e., ferulic acid and flavonoids) [13].

11. Conclusions and Future Aspects

In this review, we summarized the history of AMPs as TCMs, the classification of AMPs species, their traditional use, modern pharmacological use, and phytochemistry; the effect of BF on yield and quality, approaches to control BF, and the mechanisms of BF, inducing rhizome lignification. Although ca. 228 AMPs, 79 traditional uses, 62 modern uses, and 5 main kinds of metabolites have been recorded, the potential properties remain to be exploited. Although BF significantly reduces the yield and quality of AMPs, effective measures to inhibit BF have not been applied in the field, and the mechanisms of BF have not been systemically revealed for most AMPs. Thus, in order to effectively control the BF of AMPs to improve their quality and yield, on the one hand, standard cultivation techniques of AMPs should be applied; on the other hand, new cultivars should be developed by modern biotechnology such as the CRISPR/Cas9 system.

Author Contributions

M.L. (Meiling Li) collected and analyzed the references, drew the chemical structures, and wrote the manuscript; M.L. (Min Li) checked the classification and traditional use of Apiaceae medicinal plants; L.W. checked the language and modern pharmacological use; M.L. (Mengfei Li): conceptualization, methodology, supervision, writing—review and editing; J.W.: conceptualization and project administration. All authors have read and agreed to the published version of the manuscript.

Funding

This research was funded by the National Natural Science Foundation of China (32160083), earmarked funding for CARS (CARS-21), and Gansu Education Science and Technology Innovation Project (2022CXZXS-022).

Institutional Review Board Statement

Not applicable.

Informed Consent Statement

Not applicable.

Data Availability Statement

Not applicable.

Conflicts of Interest

The authors declare no conflict of interest.

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Molecules 28 04384 g001 550
Figure 1. Apiaceae medicinal plants (AMPs).
Figure 1. Apiaceae medicinal plants (AMPs).
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Figure 2. Traditional use of the 228 AMPs.
Figure 2. Traditional use of the 228 AMPs.
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Figure 3. Modern pharmacological uses of the 228 AMPs.
Figure 3. Modern pharmacological uses of the 228 AMPs.
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Figure 4. Core structures of five different bioactive compounds identified from the 228 AMPs.
Figure 4. Core structures of five different bioactive compounds identified from the 228 AMPs.
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Figure 5. Structures of the 18 quality markers from the 22 AMPs in the “Pharmacopoeia of the People’s Republic of China” (2020) [18].
Figure 5. Structures of the 18 quality markers from the 22 AMPs in the “Pharmacopoeia of the People’s Republic of China” (2020) [18].
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Figure 6. Cluster of the 38 rhizomatous AMPs affected by bolting and flowering (BF). The red color indicates that BF significantly affects the yield and quality; the yellow color indicates that BF affects the yield, though the rhizomes or roots can be used as medicine to some extent; and the green color indicates that BF has no significant effect on the yield and quality. a: Angelica, b: Ferula, c: Libanotis, d: Ligusticum, e: Heracleum, f: Notopterygium, g: Bupleurum, h: Changium, i: Peucedanum, j: Saposhnikovia, k: Glehnia, l: Cicuta, m: Daucus, n: Levisticum, o: Anthriscus, p: Chuanminshen, and q: Pimpinella.
Figure 6. Cluster of the 38 rhizomatous AMPs affected by bolting and flowering (BF). The red color indicates that BF significantly affects the yield and quality; the yellow color indicates that BF affects the yield, though the rhizomes or roots can be used as medicine to some extent; and the green color indicates that BF has no significant effect on the yield and quality. a: Angelica, b: Ferula, c: Libanotis, d: Ligusticum, e: Heracleum, f: Notopterygium, g: Bupleurum, h: Changium, i: Peucedanum, j: Saposhnikovia, k: Glehnia, l: Cicuta, m: Daucus, n: Levisticum, o: Anthriscus, p: Chuanminshen, and q: Pimpinella.
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Figure 7. Approaches to control the BF of AMPs.
Figure 7. Approaches to control the BF of AMPs.
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Figure 8. Schematic representation of biosynthetic pathways of lignins. Abbreviations: PAL, phenylalanine ammonia lyase; C4H, cinnamate 4-hydroxylase; 4CL, 4-coumarate-CoA ligase; HCT, hydroxycinnamoyl shikimate/quinate transferase; C3H, p-coumarate 3-hydroxylase; CCOMT, caffeoyl-CoA 3-O-methyltransferase; CCR, cinnamoyl-CoA reductases; CADs, cinnamyl alcohol dehydrogenases; LACs, laccases; F5H, ferulate 5-hydroxylase; COMT, caffeic acid 3-O-methyltransferase. The green color indicates the common phenylpropanoid pathway of phenylpropanoids, and the red color indicates the lignin biosynthetic sub-pathway. The ①, ② and ③ means different sub-pathways of lignin biosynthesis.
Figure 8. Schematic representation of biosynthetic pathways of lignins. Abbreviations: PAL, phenylalanine ammonia lyase; C4H, cinnamate 4-hydroxylase; 4CL, 4-coumarate-CoA ligase; HCT, hydroxycinnamoyl shikimate/quinate transferase; C3H, p-coumarate 3-hydroxylase; CCOMT, caffeoyl-CoA 3-O-methyltransferase; CCR, cinnamoyl-CoA reductases; CADs, cinnamyl alcohol dehydrogenases; LACs, laccases; F5H, ferulate 5-hydroxylase; COMT, caffeic acid 3-O-methyltransferase. The green color indicates the common phenylpropanoid pathway of phenylpropanoids, and the red color indicates the lignin biosynthetic sub-pathway. The ①, ② and ③ means different sub-pathways of lignin biosynthesis.
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Table
Table 1. The classification, traditional use, modern pharmacological use, and main metabolites of the 228 AMPs.
Table 1. The classification, traditional use, modern pharmacological use, and main metabolites of the 228 AMPs.
No.Plant SpeciesLocal Name in ChineseParts of Plant UsedTraditional UseModern Pharmacological UseMain MetabolitesReferences
1Aegopodium alpestre Ledeb.XiaoyeqinStems and leavesDispelling wind, relieving pain, and treating influenzaTreatment of rheumatic diseases, obesity, and hypotensiveApiole, undecane, and limonene[19,20,21]
2Ammi majus L.DaamiqinFruitsTreatment of vitiligo\Furanocoumarins[16]
3Anethum graveolens L.ShiluoFruits, leaves, or whole plantTreatment of bladder inflammation, liver diseases, and insomniaAntibacterial, antifungal, antioxidantAlkaloid, terpenoids, and flavonoids[22]
4Angelica acutiloba (Siebold & Zucc.) Kitag.Dongdanggui or ribendangguiRootsTreatment of menoxenia and anemiaHemogenic, analgesic, and sedative activitiesFerulic acid, ligustilide, and angelicide[23]
5Angelica amurensis Schischk.Heishuidanggui or chaoxiandangguiRoots\\α-pinene, limonene, and sabinene[1,24]
6Angelica anomala Avé-Lall.Xiayedanggui or yixingdangguiRootsDispelling wind, eliminating dampness, and relieving painAntioxidant, anti-inflammatory, and antitumorIsoimperatorin, umbelliferone, and adenosine[16,25,26,27]
7Angelica apaensis R. H. Shan & C. C. YuanFaluohai or abadangguiRootsRelieving pain, relieving cough and asthmaBacteriostat, anti-inflammatoryOxypeucedanin, isoimperatorin, and oxypeucedanin hydrate[19,28]
8** Angelica biserrata (R. H. Shan & C. C. Yuan) C. C. Yuan & R. H. ShanDuhuo or maodangguiRootsDispelling wind, eliminating dampness, and relieving painAntitumor, anti-inflammatory, and antioxidantCoumarins osthole, columbianadin, and volatile oils[29]
9Angelica cartilaginomarginata var. Foliosa C. C. Yuan & R. H. ShanShangaobenRoots\\\[17]
10** Angelica dahurica (Fisch. Ex Hoffm.) Benth. & Hook. F. Ex Franch. & Sav.BaizhiRootsTreatment of acne, erythema, and headacheAnti-inflammatory, anti-mutagenic, and antitumorScopoletin and psoralen[18,30,31,32,33]
11** Angelica dahurica cv. HangbaizhiHangbaizhiRootsTreatment of headache, toothache, abscess, and furunculosisEstrogenic, cytotoxic, and anti-inflammatoryIsoimperatorin, imperatorin, and phellopterin[18,34,35]
12Angelica dahurica var. Formosana (H. Boissieu) YenTaiwanduhuoRoots\Anti-staphylococcaFalcarindiol[33,34]
13** Angelica decursiva (Miq.) Franch. & Sav.ZihuaqianhuRootsA remedy for thick phlegm, asthma, and upper respiratory tract infectionsAntioxidant and anti-inflammatory potentialDecursin, decursidin, and nodakenetin[36]
14Angelica gigas NakaiChaoxiandangguiRootsTreatment of dysmenorrhea, amenorrhea, and menopauseAnti-platelet effectsDecursin and decursinol angelate[37,38]
15Angelica laxifoliata DielsShuyedangguiRootsDispelling wind and relieving painTreatment of wind-damp pain, lumbus, and kneesAngelicin, β-sitosterol, and laxifolin[16,26,39]
16Angelica megaphylla DielsDayedangguiRootsUsed as Angelica sinensisUsed as A. SinensisFerulic acid, ligustilide, and angelol[40,41]
17Angelica morii HayataFushenRoots and leavesTreatment of spleen and stomach, cold cough, and toothacheUsed for diarrhea caused by deficiency of spleen and for cough caused by weakness and chillImperatorin, isoimperatorin, and phellopterin[42,43,44]
18Angelica nitida H. WolffQinghaidangguiRootsNourishing the blood, regulating menstrual disorder, and relieving pain\Isoimperatorin, imperatorin, and cnidilin[45]
19Angelica polymorpha Maxim.Guaiqin or shanqincaiRootsDispelling wind and relieving painTreatment of stomachacheCoumarins, sesquiterpenoids, and alkaloids[19,46,47]
20** Angelica sinensis (Oliv.) DielsDangguiRootsNourishing the blood, regulating menstrual disorder, and relieving painCardio-cerebrovascular, anti-inflammatory, and antioxidantFerulic acid, alkylphthalides, and polysaccharides[18,48,49]
21Angelica sinensis var. Wilsonii EmeidangguiRootsUsed as Angelica sinensis, relieving painUsed as Angelica sinensisIsoimperatorin, coumarin, and oxypeucedanin[50]
22Angelica sylvestris L.LindangguiRootsRelieves rheumatism and sweating, provides detoxification\Cnidilide, sedanenolide, and ligustilide[19]
23Angelica tsinlingensis K. T. FuQinlingdangguiRoots\\\[1]
24Angelica valida DielsWuduhuo or yandangguiRoots\\\[1]
25Anthriscus nemorosa (M. Bieb.) Spreng.CiguoeshenRoots, whole plant, and leavesUsed as Peucedanum praeruptorum Used as Peucedanum praeruptorum \[51]
26Anthriscus sylvestris (L.) Hoffm.EshenRoots and leavesInvigorating spleen, replenishing qi, and expelling phlegmAntitumor, antioxidation, and antisenityPhenylpropanoids, flavonoids, and steroidal[19,52]
27Apium graveolens L.HanqinWhole plant, roots, and rhizomeDispelling wind, eliminating dampness, and detoxificationHypertension, hyperlipidemia, and dysuriaOrganic acids, apigenin, and volatile oils[19,53,54]
28Archangelica brevicaulisfDuanjinggudangguiRootsUsed as Angelica biserrata Used as Angelica biserrata Osthol, imperatorin, and archangelicin[16,55]
29Bupleurum angustissimum (Franch.) Kitag.XiayechaihuRoots\\Saikosaponins (a, c, and d), β -terpinene, and β -thujene[56]
30Bupleurum aureum Fisch.JinhuangchaihuRoots\\Saikosaponins (a, c, and d)[1,57]
31Bupleurum bicaule HelmZhuiyechaihuRootsUsed as Bupleurum scorzonerifoliumUsed as Bupleurum scorzonerifolium Saikosaponin d, prosaikogenin G, and prosaikogenin F[16,58,59]
32Bupleurum candollei Wall. Ex DC.ChuandianchaihuWhole plantDiminishing inflammation, detoxification, dispelling wind, and relieving convulsion\Saikosaponin and flavonoids[16,56]
33Bupleurum chaishoui R. H. Shan & M. L. ShehChaishouRoots and rhizomeUsed as Bupleurum chinenseUsed as Bupleurum chinenseSaikosaponins (a, c, and d)[60]
34** Bupleurum chinense DC.BeichaihuRootsTreatment of chronic hepatitis, kidney syndrome, and inflammatory diseases Anti-allergen, analgesic, and anti-inflammationSaikosaponins (a, c, and d)[18,61,62]
35Bupleurum chinense DC. F. Octoradiatum (Bunge) Shan et ShehBaihuashanchaihuRootsUsed as Bupleurum chinenseAnti-allergen, analgesic, and anti-inflammationSaikosaponins (a, c, and d)[63,64]
36Bupleurum chinense DC. F. Vanheurckii (Muell.-Arg.) Shan et Y. LiYantaichaihuRootsUsed as Bupleurum chinenseAnti-allergen, analgesic, and anti-inflammationSaikosaponins (a, c, and d)[63,64]
37Bupleurum commelynoideum var. Flaviflorum R. H. Shan & Yin LiHuanghuayazhichaihuRoots, rhizome, and whole plantAntipyretic-analgesic effect, choleretic, and hepatoprotectionTreating or relieving inflammatory bowel diseaseSaikosaponins (a, c, and d), β-pinene, and perillen[65,66]
38Bupleurum densiflorum Rupr.MihuachaihuRoots\\\[63]
39Bupleurum dielsianum H. WolffTaibaichaihuRoots\\\[63]
40Bupleurum euphorbioides NakaiDabaochaihuRoots\\Saikosaponins, perillen, and undecanal[56]
41Bupleurum exaltatum M. Bieb.XinjiangchaihuRoots\\\[64]
42Bupleurum falcatum L.SandaochaihuRoots\Treatment of colds and upper respiratory tract infectionsSaikosaponins (a, c, and d)[64,67,68]
43Bupleurum gansuense S. L. Pan et HsuGansuchaihuRoots\\\[56]
44Bupleurum hamiltonii N. P. Balakr.XiaochaihuRoots or whole plantAntipyretic-analgesic effect, treatment of chill and fever alternationTreatment of stomach pain, dysuria, and coughKaerophyllin, isokaerophyllin, and ethyl caffeic acid[69]
45Bupleurum hamiltonii var. Hamiltonii/Bupleurum tenueXiaochaihuRoots or whole plantUsed as Bupleurum hamiltonii N. P. Balakr.Used as Bupleurum hamiltonii N. P. Balakr.\[70]
46Bupleurum hamiltonii var. Humile (Franch.) R. H. Shan & M. L. ShehAixiaochaihuRoots\\\[64]
47Bupleurum huizei S. L. Pan sp. Nov.HuizechaihuRoots\\\[64]
48Bupleurum kaoi T. S. Liu, C. Y. Chao & T. I. ChuangTaiwanchaihu or gaoshichaihuRoots\Treatment of influenza and feverSaikosaponin a, c[64]
49Bupleurum komarovianum Lincz.ChangbaichaihuRootsUsed as Bupleurum chinenseUsed as Bupleurum chinenseSaikosaponins (a, c, and d) and volatile oils (1-caprylene, limonene, and thymol)[71,72]
50Bupleurum krylovianum Schischk. Ex KrylovAertaichaihuRoots\\Saikosaponins (a, c, and d)[56,57]
51Bupleurum kunmingense Yin Li & S. L. PanJiuyechaihuRoots\ImmunomodulatorySaikosaponins (a, c, and d), cyclohexanone, and 2- methyldodecane[56]
52Bupleurum longicaule var. Amplexicaule C. Y. WuBaojingchaihuRoots\\Saikosaponins (a, c, and d)[64]
53Bupleurum longicaule var. Franchetii H. BoissieuKongxinchaihuRoots or whole plant\\Saikosaponins (a, c, and d), cyclohexanone, and myrcene[56]
54Bupleurum longicaule var. Giraldii H. WolffQinlingchaihuRoots\\Saikosaponins (a, c, and d), narcissin, and rutin[56]
55Bupleurum longiradiatum Turcz.DayechaihuRootsTreatment of gout and inflammatory illnessAnti-inflammatory and/or antimicrobialThymol, butylidene phthalide, and 5-indolol[73]
56Bupleurum luxiense Yin Li & S. L. PanLuxichaihuRoots\\Saikosaponins (a, c, and d), n-heptaldehyde, and octanal[56]
57Bupleurum malconense R. H. Shan & Yin LiMaweichaihuWhole plantHepatoprotection and antipyretic effectAcute toxicitySaikosaponins (a, c, and d), rutin, and quercetin[74,75,76]
58Bupleurum marginatum var. MarginatumZichaihu or zhuyefangfengWhole plantHepatoprotection and antipyretic effectAnti-allergen, analgesic, and anti-inflammatorySaikosaponins (a, c, and d), rutin, and quercetin[74,75,77]
59Bupleurum marginatum var. Stenophyllum (H. Wolff) R. H. Shan & Yin LiZhaizhuyechaihuWhole plant\\Saikosaponins (a, c, and d), chikusaikoside I, II, and 2- methylcyclopentanone[56]
60Bupleurum marginatum Wall. Ex DC.ZhuyechaihuWhole plant and rootsHepatoprotection and antipyretic effectAnti-allergen, analgesic, and anti-inflammatorySaikosaponins (a, c, and d), rutin, and quercetin[74,75,77]
61Bupleurum microcephalum DielsMaweichaihuWhole plant and rootsHepatoprotection and antipyretic effectAnti-allergen, analgesic, and anti-inflammatorySaikosaponins (a, c, and d), rutin, and quercetin[74,75]
62Bupleurum petiolulatum var. tenerum R. H. Shan & Yin LiXijingyoubingchaihuWhole plantAntipyretic-analgesic effectAnti-inflammatory\[63,78]
63Bupleurum polyclonum Yin Li & S. L. PanDuozhichaihuRoots\AnticancerSaikosaponins (a, c, and d), 4′-O-saikosaponin-a, and fenchane[56]
64Bupleurum rockii H. WolffLijiangchaihuRoots\\Saikosaponins (a, c, and d), thymol, and β-guaiene[56]
65Bupleurum scorzonerifolium f. LongiradiatumChangsanhongchaihuRootsUsed as Bupleurum chinenseUsed as Bupleurum chinense\[19]
66Bupleurum scorzonerifolium f. PauciflorumShaohuahongchaihuRootsUsed as Bupleurum chinenseUsed as Bupleurum chinense\[19]
67** Bupleurum scorzonerifolium Willd.Hongchaihu or zhuyechaihuRootsAntipyresis, relief of liver issues and menstrual disordersUsed as Bupleurum chinenseRutin, quercetin, and kaempferol[18,19]
68Bupleurum sibiricum var. Jeholense (Nakai) Y. C. Chu ex R. H. Shan & Yin LiWulingchaihuRoots\\\[1]
69Bupleurum sibiricum VestXinganchaihuRootsUsed as Bupleurum chinenseUsed as Bupleurum chinenseSaikosaponin a, rutin, and quercetin[16,79,80]
70Bupleurum sichuanense S. L. Pan et Hsu.SichuanchaihuRoots\\Saikosaponins (a, c, and d)[56]
71Bupleurum smithii H. WolffHeichaihuRootsAntipyretic-analgesic effectAnti-inflammatory, immunomodulatory, and anti-hepatic injurySaponins, volatile oils, and lignans[81]
72Bupleurum smithii var. Parvifolium R. H. Shan & Yin LiXiaoyeheichaihuRootsRelief of liver issues and activation of yang energyAnti-inflammatory, immunomodulatory, and antitumorFalcarinol, saponins, and flavonoids[82]
73Bupleurum thianschanicum FreynTianshanchaihuRoots\\Saikosaponins (a, c, and d)[57]
74Bupleurum triradiatum Adams ex Hoffm.SanfuchaihuRoots\\\[1]
75Bupleurum wenchuanense R. H. Shan & Yin LiWenchuanchaihuRootsUsed as BupleurumUsed as BupleurumQuercetin-3-O-α-L-rhamnoside, quercetin, and rutin[16,75]
76Bupleurum yinchowense R. H. Shan & Yin LiYinzhouchaihu or hongchaihuRootsAntipyresis, relief of liver issues, and activation of yang energyUsed as BupleurumSaikosaponins (a, c, and d)[16,65,83,84]
77Carum buriaticum Turcz.TiangelvziRoots and fruits\\\[5]
78Carum carvi L.ZanghuixiangRoots, fruits, and leavesDispelling wind, eliminating dampness, invigorating the stomach, and treating heart diseaseAnti-bacterial, antioxidant, and antitumorCarvone, limonene, and dihydrocarvone[19,85,86]
79* Centella asiatica (L.) Urb.JixuecaoWhole plantClearing heat, promoting diuresis, and treating toxicityAnti-bacterial, anti-depressive, and neuroprotectiveAsiaticoside, madecassoside, and elemene[18,87]
80** Changium smyrnioides H. WolffMingdangshenRootsStrengthening with tonics, moistening lungs, clearing phlegm, and calming the liverImmunomodulatory, relieving fatigue, and enhancing adaptabilityCetylic acid, succinic acid, and imperatorin[18,88]
81Chuanminshen violaceum M. L. Sheh & R. H. ShanChuanmingshenRootsMoistening the lungs, clearning phlegm, harmonizing the stomach, and stimulating liquidsAntioxidant, enhancing immunity, and antimutationPolysaccharides, coumarins, and flavonoids[89,90,91]
82Cicuta virosa L.DuqinRoots and rhizomeExpelling phlegm and detoxificationTreatment of osteomyelitis, gout, and rheumatismP-cymene, cicutoxine, and L-limonene[17,92]
83* Cnidium monnieri (L.) Spreng.ShechuangFruitsDispelling wind, relieving convulsion, treating impotenceAntibacterial, antiviral, and antimutagenesisOsthole, limonene, and cnidimoside A[18,93]
84Cnidium officinaleDongchuanxiongRootsUsed as Cnidium monnieriUsed as Cnidium monnieri\[1]
85Conioselinum acuminatum (Franch.) LavrovaShuigaobenRoots\\Sabinene, α-pinene, and aromadendrene[11]
86Conioselinum anthriscoidesFuxiongFuxiongRoots\\β-bergamotene[11]
87Conioselinum tenuisectum (H. Boissieu) Pimenov & KljuykovXiliegaobenRoots\\\[94]
88Conioselinum vaginatum (Spreng.) Thell.Xinjianggaoben or qiaoshanxiongRootsDispelling wind, eliminating dampness, and relieving painTreatment of common cold due to wind-cold and gastro spasmDiligustilide, daucosterol, and palmitic acid[19,95]
89Conium maculatum L.DushenWhole plantRelieving pain and relieving muscular spasmTreatment of cancerConiine, N-methyl-coniine, conhydrine 2-(1-hydroxypropyl)-piperidine[16,96,97]
90Coriandrum sativum L.HusuiWhole plant, fruits, and stemsInvigorating the stomach and promoting eruptionAntibacterial, antifungal, and antioxidantPetroselinic acid, linoleic acid, and oleic acid[19,98]
91Cryptotaenia japonica Hassk.SanyeqinWhole plantTreatment of weakness, urinary closure, and swellingAntioxidant, protection of liver, and anticancerFriedelin, stigmasterol, and apigenin[19,99,100]
92Cuminum cyminum L.ZiranqinFruitsTreatment of indigestion and stomach/abdominal painAntibacterial, antioxidant, and radical-scavenging propertiesα-pinene, 1,8-cineole, and linalool[19,101]
93Cyclorhiza peucedanifolia (Franch.) ConstanceNanzhuyehuangenqinFruitsEnriching the blood, activating the blood, and regulating menstrual disorder\\[102]
94Daucus carota L.CarrotFruitsTreatment of ascariasis, enterobiasis, and tapeworm diseaseInsecticidal, anti-bacterial, and anticancerα-pinene, isophorone oxide, and and quercetrin[18,103]
95Daucus carotavar. CarotaWild carrotFruitsTreatment of ascariasis, enterobiasis, and tapeworm diseaseInsecticidal, anti-bacterial, and anticancerα-pinene, β-bisabolene, and luteolin[18,103]
96Daucus carota var. Sativus Hoffm.Wild carrotRoots and basal leavesStrengthening spleen, treatment of dyspepsia and chronic dysenteryEnhancing immunity, anticancer and anti-agingCarotene, (1R)-α-pinene, and β-carotene[19,104]
97Eriocycla albescens (Franch.) H. WolffDianqianghuoRoots\\\[1]
98Eryngium foetidum L.CiqinWhole plantDiuresis, treatment of dropsy and snakebiteBacteriostat, diminishing of inflammation, and promotion of detumescenceLanolin alcohol, carotene, and n-nonyl aldehyde[19,105]
99Ferula bungeana Kitag.YingaweiWhole plant and seedsHeat clearing and detoxifying, relieving pain and expelling phlegm, and arresting coughingTreatment of cold, bronchopneumonia, and pulmonary tuberculosisAnisole, d-fenchone, and limonen[19,106]
100Ferula caspica M. Bieb.LihaiaweiRoots and resinEliminating stagnated food, relieving dyspepsia, insecticideTreatment of toxicityUmbelliprenin, farnesyl alcohol, and umbelliferone[107]
101Ferula conocaula KorovinYuanzhuijingaweiResin, roots, and rhizomeEliminating stagnated food, insecticide, treatment of abdominal massAnticancer and treatment of influenzaUmbelliprenin, fezelol, and feterin [107]
102Ferula feruloides (Steud.) KorovinXiangaweiRoots and resinTreatment of chilliness, and heart and abdominal painInsecticidal, bacteriostat, and antitumorα-pinene, farnesene and toluene[108,109]
103** Ferula fukanensis K. M. ShenFukangaweiResinEliminating stagnated food, relieving dyspepsia, insecticideTreatment of stomach disease, rheumatism, and joint painFerulic acid, guaiol, and ethyl-p-hydroxybenzoate[18,19,110,111,112]
104Ferula jaeschkeana VatkeZhongyaaweiResin of overground partEliminating stagnated food, insecticide, treatment of tumors, wounds, and peptic ulcersAntifertilityJaeschkeanadiol, α-pinene, and β-pinene[107]
105Ferula krylovii KorovinTuoliaweiResin Eliminating stagnated food, insecticide\Fekrynol, ferukrin and fekrynol acetate[107]
106Ferula lehmannii Boiss.DaguoaweiResinDetoxification, deodorization, and insecticideTreatment of gastropathy, rheumatism, and arthralgiaLehmannolone, sinkianone, and lehmannolone A[16,113]
107Ferula moschata (Reinsch) Koso-Pol.ShexiangaweiRootsSedative, treatment of spasmolysis and hysteriaSuppresses the replication of human immunodeficiency virus in H9 lymphocytes and suppresses the production of cytokineFezelol, fesumtuorin A, and fesumtuorin B[107]
108Ferula olivacea (Diels) H. Wolff ex Hand.-Mazz.LanlvaweiResinWind-heat dispersing, expelling phlegm, and arresting cough\\[16]
109** Ferula sinkiangensis K. M. ShenXinjiangaweiResinEliminating stagnated food, detoxification, insecticideAntioxidant, antitumor, and antiviralFerulic acid, fekrynol, and lehmannolone[16,18,114,115]
110Ferula songarica Pall. Ex Schult.ZhungaeaweiResin and whole plantEliminating stagnated food, insecticide\2,4-dihydroxylacetophenone, 3,3′, 4,4′-biphenyltetracarboxylic acid, and Δ3-carene[116]
111Ferula teterrima Kar. & Kir.ChouaweiResinEliminating stagnated food, insecticideTreatment of malaria and dysenteryFeterin, badrakemin, and badrakemin acetate[116]
112* Foeniculum vulgare Mill.XiaohuixiangFruits, roots, stems, leaves, and whole plantDispelling wind, relieving pain, and harmonizing the stomachBacteriostat, anti-inflammatory, and insecticideTrans-anethole, estragole, and anisaldehyde[18,19,117,118]
113** Glehnia littoralis F. Schmidt ex Miq.BeishashenRootsHeat clearing and detoxifying, diminishing inflammation, expelling phlegm, and arresting coughAnti-inflammatory, bacteriostat, and antitumorPhenyllactic acid, catechol, and quercetin[18,119]
114Hansenia oviformis (R. H. Shan) Pimenov & KljuykovLuanyeqianghuoRhizome, roots, and leavesTreatment of rheumatic arthralgia, cold due to wind-cold, and headache\\[16,102]
115Heracleum barmanicum KurzYinduduhuoRootsTreatment of cold abdominalgia\\[16]
116Heracleum candicans Wall. Ex DC.BaiyunhuaRootsDispelling wind, eliminating dampness, and relieving painTreatment of cold headacheBergapten, heraclenin, and imperatorin[19,120]
117Heracleum dissectifolium K. T. FuDuolieduhuoRootsDispelling wind, eliminating dampness, and relieving pain\\[16]
118Heracleum fargesii H. BoissieuChengkouduhuoRoots\\\[17]
119Heracleum franchetii M. HiroeJianyeduhuoRoots and rhizome\\\[121,122]
120Heracleum hemsleyanumNiuweiduhuoRoots and rhizomeDispelling wind, eliminating dampness, and relieving painAntioxidant, anti-inflammatory, and antitumorβ-pinene, α-pinene, and (1S)-6,6-dimethyl-2-methylene-bicyclo [3.1.1] heptane[26,27,123,124]
121Heracleum hemsleyanum DielsBeiduhuo or dahuoRoots and rhizomeDispelling wind, eliminating dampness, and relieving painAntioxidant, anti-inflammatory, and antitumorOsthole, columbianadin, and columbianetin[26,27]
122Heracleum henryi H. WolffNanguaqiRootsClearing and activating the channels and collaterals, relieving pain and scattered stasis\Turgeniifolin B, turgeniifolin C, and bergapten[125]
123Heracleum millefolium var. MillefoliumQianyeduhuo or zangdangguiRoots and rhizomeDetumescence, treating masses, and treating leprosy\\[102,121,122]
124Heracleum moellendorffii HanceDuanmaoduhuoRoots and rhizomeClearing and activating the channels and collaterals, relieving pain and scattered stasisBacteriostatβ-pinene, α-pinene, and pentadecane [123,125,126,127]
125Heracleum oreocharis H. WolffShandiduhuoRoots\\\[122]
126Heracleum rapula Franch.BaiyunhuaRootsClearing and activating the channels and collaterals, relieving pain and scattered stasisBacteriostat, treatment of asthma, and chronic bronchitisOstholce, marmesin, and imperatorin[19,125,128]
127Heracleum scabridum Franch.Dianbaizhi or caoduhuoRoots, rhizome, and fruitsTreatment of common cold due to wind-cold, headache, cough, and asthma\Heraclenol, oxypeucedanin-hydrate, and byakangelicin[129,130,131]
128Heracleum souliei H. BoissieuXiaoduhuoRoots\\Bergapten[120,122]
129Heracleum stenopterum DielsXiachiduhuoRootsTreatment of cold and rheumatism\Bergapten, isopimpinellin, and sphondin[16,132]
130Heracleum tiliifolium H. WolffDuanyeduhuoRootsDispelling wind, eliminating dampness, and relieving pain\\[16]
131Heracleum vicinum H. BoissieuPingjieduhuoRootsUsed as Notopterygium incisum\\[121,122]
132Heracleum wenchuanense F. T. Pu & X. J. HeWenchuanduhuoRoots\\\[122]
133Heracleum wolongense F. T. Pu & X. J. HeWolongduhuoRoots\\\[1,122]
134Heracleum yungningense Hand.-Mazz.NiuweiduhuoRoots and rhizomeTreatment of waist and knee pain, limb spasm, and leucoderma\Pimpinellin, angelicin, and isobergapten[26,133]
135Hydrocotyle himalaica P. K. Mukh.BinghuatianhusuiWhole plantHeat clearing, detoxifying, and eliminating dampness\Asiaticoside, madecassoside, and quercetin[134,135]
136Hydrocotyle hookeri subsp. Chinensis (Dunn ex R. H. Shan & S. L. Liou) M. F. Watson & M. L. ShehTongqiancaoWhole plantRelieving pain, diuresis, and removing dampnessAntiviral, antitumor, and anti-bacterialFlavonoids, triterpenes, and volatile oils[16,129,135]
137Hydrocotyle nepalensis Hook.HongmaticaoWhole plantClearing heat and promoting diuresis, dissolving stasis, and hemostasis and detoxificationAntiviral, antitumor, and anti-bacterialFlavonoids, triterpenes, and volatile oils[16,135]
138Hydrocotyle sibthorpioides Lam.XiaojinqiancaoWhole plantHeat clearing, diuresis, and detumescenceAnti-ulcer, antilipemic, and antiviralQuercetin, isorhamnetin, and asiaticoside[135,136]
139Hydrocotyle sibthorpioides var. batrachium (Hance) Hand.-Mazz. Ex R. H. ShanTianhusui or potongqianWhole plantHeat clearing and detoxifying, eliminating dampness, and diuresisAnti-ulcer, spasmolysis, and anti-inflammatoryBenzene propane nitrile, phytol, and caryophyllene oxide[16,137,138]
140Hydrocotyle wilfordii Maxim.YutengcaoWhole plantAs Hydrocotyle nepalensis Hook.As Hydrocotyle nepalensis Hook.Asiaticoside, madecassoside, and quercetin[134,135]
141Hymenidium chloroleucum (Diels) Pimenov & KljuykovXizangdiangaobenRoots or whole plantRegulating flow of qi, invigorating the stomach, and activating bloodAnti-inflammatory, analgesia, and nutritious functionNobiletin, falcarindiol, and isoliquiritingenin[19,139,140]
142Hymenidium davidii (Franch.) Pimenov & KljuykovSongpanlengziqinRoots\\\[141]
143Hymenidium delavayi (Franch.) Pimenov & KljuykovLijianggaobenRoots\\\[1,6]
144Hymenidium lindleyanum (Klotzsch) Pimenov & KljuykovTianshanlengziqinRootsTreatment of hypertension, coronary heart disease, and altitude stress\Bergapten, isoimperatorin, and oxypeucedanin[142]
145Kitagawia formosana (Hayata) PimenovTaiwanqianhuRoots\\\[1]
146Kitagawia macilenta (Franch.) PimenovXilieqianhuRootsExpelling phlegm\\[143]
147Kitagawia terebinthacea (Fisch. Ex Trevir.) PimenovShifangfengRootsClearing heat and dispelling wind, calming the adverse-rising energy, and expelling phlegmTreatment of cold and cough, bronchitis, and cough during pregnancyIsoepoxybuterixin[19]
148Levisticum officinale W. D. J. KochOudangguiRootsDiuresis, invigorating the stomach, and expelling phlegmInhibition of rhythmic uterine contractions, Scavenging oxygen free radicals, and anti-lipid peroxidationLigustilide, α-phellandrene, and β-phellandrene[19,144]
149Libanotis buchtormensis (Fisch.) DC.YanfengRootsTreating wind chill, dispelling wind dampness, and relieving painBacteriostat, treatment of common cold due to wind-cold, generalized pain, and coughFalcarinone, isoimperatorin, and xanthotoxin[19,145]
150Libanotis iliensis (Lipsky) KorovinXiyefangfengRootsExpel wind-cold pathogens, thermolysis, and relieving painTreatment of common cold due to wind-cold and rheumatic arthritisArchangelin and iliensin[19]
151Libanotis lancifolia K. T. FuYanfengRootsDivergent wind chill, dispelling wind-damp, and relieving painBacteriostat, treatment of common cold due to wind-cold, generalized pain, and coughFalcarinone, isoimperatorin, and xanthotoxin[19,145]
152Libanotis laticalycina R. H. Shan & M. L. ShehShuifangfengRootsDispelling wind, antispasmodic, and relieving painAnalgesic, sedative, and anti-inflammatoryOctanal, hexanal, and 2-pentylfuran[16,146,147]
153Libanotis seseloides (Fisch. & C. A. Mey. Ex Turcz.) Turcz.XiangqinRootsEliminating dampness, activating spleen, and promote blood circulationTreatment of obstruction, dysentery, and soresEdultin[19]
154Libanotis sibirica (L.) C. A. Mey.BeixiangqinRoots\\\[1]
155Libanotis spodotrichoma K. T. FuChangchongqiRootsTreating wind chill, dispelling wind dampness, and relieving painBacteriostat, treatment of common cold due to wind-cold, generalized pain, and coughFalcarinone, isoimperatorin, and xanthotoxin[19,145]
156Ligusticopsis brachyloba (Franch.) LeuteMaoqianhuRootsSudation, relieving pain, and dispelling windTreatment of headache, dizziness, arthralgia, and tetanusα-pinene, β-pinene, and sabinene[148,149,150]
157Ligusticopsis daucoides (Franch.) Lavrova & KljuykovYubaogaobenRoots\\\[1,94]
158Ligusticopsis likiangensis (H. Wolff) Lavrova & KljuykovMeimaigaobenRoots\\\[1,94]
159** Ligusticum chuanxiong Hort. ChuanxiongRoots, rhizome, stems, and leavesActivating blood, relieving pain, and dispelling windAnti-inflammatory, antioxidant, and antitumorAbietene, tetramethylpyrazine, and glucose[18,19,151]
160** Ligusticum jeholense Nakai et Kitag.LiaogaobenRoots and rhizomeDispelling wind, dispersing cold, and eliminating dampnessAnti-inflammatory, sedative, and anti-ulcerFerulic acid, isoferulic acid, and daucosterol[18,19,152,153]
161Ligusticum pteridophyllum Franch.JueyegaobenRootsDispelling wind, relieving pain, and eliminating dampnessTreatment of cold due to wind-cold and migraineAsaricin, β-sitosterol, and daucosterol[26,154]
162** Ligusticum sinense Oliv.BaogenRoots, rhizome, and tuberExpelling wind-cold pathogens, eliminating dampness, and relieving painAnti-inflammatory, central inhibitory, and anti-thrombotic effects3-butylphthalide, opthalonide, and neopthalonide[18,155]
163Ligusticum tenuissimum (Nakai) KitagawaGaobenRoots and rhizomeUsed as ligusticum sinense Oliv. Treatment of wind chill, wind-cold headache, and diarrheaAnalgesia and sedationFerulic acid[19,94,156]
164Meeboldia delavayi (Franch.) W. Gou & X. J. HeDianqinRootsTreatment of cold, fever, and headache\\[16]
165Nothosmyrnium japonicum var. JaponicumBaibaoqinRoots\Sedation and analgesia\[16]
166Nothosmyrnium japonicum var. Sutchuensis H. BoissieuChuanbaibaoqinRoots\Sedation and analgesia\[16]
167** Notopterygium franchetii H. De Boiss.KuanyeqianghuoRoots and rhizomeTreating wind chill, dispelling wind, and eliminating dampnessAnti-inflammatory, analgesic, and antiviralNodakenin, ferulic acid, and bergamot lactone[18,157,158]
168** Notopterygium incisum Ting ex H. T. ChangQianghuoRoots and rhizomeTreating wind chill, dispelling wind, and eliminating dampnessAnti-inflammatory, analgesic, and antiviralNodakenin, notopterol, and isoimperatorin[18,158]
169Oenanthe benghalensis Benth. & Hook.ShaohuashuiqinRoots and whole plantUsed as Oenanthe javanica (Blume) DC.Used as Oenanthe javanica (Blume) DC.\[17,159]
170Oenanthe javanica (Blume) DC.ShuiqinRoots, stems, and whole plantHeat clearing, detoxification, and removing liver-fireEnhancing immunity, antiarrhythmic, and hypoglycemicPhytic acid, γ-terpinene, and caryophyllene[19,160]
171Oenanthe linearis subsp. Rivularis (Dunn) C. Y. Wu & F. T. PuYeshuiqinRoots and whole plantUsed as Oenanthe javanica (Blume) DC.Used as Oenanthe javanica (Blume) DC.\[17]
172Osmorhiza aristata var. Laxa (Royle) Constance & R. H. ShanXianggenqinRootsTreating wind chill and sudation, and relieving pain\\[16]
173Ostericum citriodorum (Hance) C. C. Yuan & R. H. ShanGeshanxiangRoots and whole plantActivating blood, dissolving stasis, and dispelling windExpectorant, anti-inflammatory, and bacteriostatIsoapiole, panaxynol, and myristicin[19,161,162,163]
174Ostericum grosseserratum (Maxim.) Kitag.DachishanqinRootsActivating spleen, dispersing cold, invigorating spleen, and replenishing qi\Octanal, β-pinene, and myristic acid[16,164,165]
175Ostericum sieboldii (Miq.) NakaiShanqinRoots\\\[166,167,168]
176Peucedanum dielsianum Fedde ex H. WolffChuanfangfengRoots and rhizomeRelieving pain, dispelling wind, and eliminating dampness\Isoimperatorin, Phellopterin, and 9-octadecenoic acid[19,169,170]
177Peucedanum dissolutum (Diels) H. WolffYanfengRoots\\\[1]
178Peucedanum harry-smithii var. SubglabrumYingqianhuRootsUsed as Peucedanum praeruptorum; alleviating asthma, reducing phlegm, and heat eliminationTreatment of bronchitis, hypertension, and coronary heart diseasePsoralen, bergapten, and xanthotoxin[171,172,173,174]
179Peucedanum japonicum Thunb.BinhaiqianhuRootsClearing heat, relieving cough, and diuresisAntipyresis, analgesia, and anti-inflammatoryPeucedanol, umbelliferone, and β-pinene[19,175,176]
180Peucedanum ledebourielloides K. T. FuHuashanqianhuRoots\\\[1,168]
181Peucedanum longshengense R. H. Shan & M. L. ShehNanlingqianhuRoots\\\[1]
182Peucedanum mashanense R. H. Shan & M. L. ShehFangfengRootsExpelling phlegm\\[143]
183Peucedanum medicum DunnHuazhongqianhuRootsExpelling phlegm, alleviating asthma and cough, and arresting convulsionAnticoagulation, antioxidant, and antibacterial2-methoxy-4-vinylphenol, p-menthan-1-ol, and cis-α-bisabolene[19,177,178]
184Peucedanum medicum var. Gracile Dunn ex R. H. Shan & M. L. ShehYanqianhuRoots and rhizomeExpelling phlegm, alleviating asthma and cough, and arresting convulsionAnticoagulation, antioxidant, and antibacterialIsoimperatorin, phellorerin, and bergapten[19,177,179]
185Peucedanum medicum var. MedicumHuazhongqianhuRoots and rhizomeExpelling phlegm, alleviating asthma and cough, and arresting convulsionAnticoagulation, antioxidant, and antibacterial2-methoxy-4-vinylphenol, p-menthan-1-ol, and cis-α-bisabolene[19,177,178]
186** Peucedanum praeruptorum DunnQianhuRootsTreating gas, clearing heat, and reducing phlegmAnticoagulation, antioxidant, and anticancerPraeruptorin A, praeruptorin B, and scopoletin[18,180]
187Peucedanum shanianum F. L. Chen & Y. F. DengHongqianhuRootsRelieving asthma, expelling phlegm, and treating spasmolysisAnti-inflammatory, antiallergic, and anti-ulcerSinodielides A, deltoin, and (+)-pareruptorin A[181,182,183,184]
188Peucedanum turgeniifolium H. Wolff/Peucedanum pulchrumYaqianhuRoots and whole plantExpelling phlegm, antibechic, and dispersing wind-heatSmooth muscle spasmolysisTurgenifolin A, turgenifolin B, and bergapten[19,184,185]
189Peucedanum wawrae (H. Wolff) S. W. Su ex M. L. ShehTaishanqianhuRootsAntibechic and expelling phlegmAnalgesia, sedation, and anti-inflammatoryPeucedanocoumarin, d-laserpitin, and bergapten[16,168,186]
190Peucedanum wulongense R. H. Shan & M. L. ShehWulongqianhuRoots\\\[1]
191Phlojodicarpus sibiricus (Steph. Ex Spreng.) Koso-Pol.ZhangguoqinRoots\\\[1]
192Physospermopsis alepidioides (H. Wolff & Hand.-Mazz.) R. H. ShanQuanyedianxiongRoots\\\[1]
193Physospermopsis delavayi (Franch.) H. WolffDianxiongRoots\\\[1]
194Pimpinella anisum L.HuiqinFruitsWarming meridian and diuresisTreatment of paralysis, facial paralysis, and migraineAnisaldehyde, anisole, and (E)-anethole[187,188,189,190,191]
195Pimpinella candolleana Wight & Arn.XingyefangfengRoots or whole plantWarming spleen and stomach for dispelling cold, relieving pain, and dispelling windRelieving muscular spasm, antiviral, and antibacterialα-zingiberene, pregeijerene, and β-elemene[19,192,193,194]
196Pimpinella coriacea (Franch.) H. BoissieuGeyehuiqinWhole plantWarming spleen and stomach for dispelling cold, dispelling wind, and eliminating dampness, and activating blood\\[195]
197Pimpinella diversifolia DC.YiyehuiqinWhole plantExpelling phlegm, activating blood, relieving pain, and removing toxicity for detumescenceAnti-inflammatory, antitumor, and anti-tuberculosis1H-benzocycloheptene, sesquiphellandrene, and β-chamigrene[196,197,198]
198Pimpinella diversifolia var. DiversifoliaYiyehuiqinRoots or whole plantInvigorating stomach, dispersing accumulations, and antidiarrheicAnti-inflammatory, antitumor, and anti-tuberculosis1H-benzocycloheptene, sesquiphellandrene, and β-chamigrene[19,196,197,198]
199Pimpinella thellungiana H. WolffYanghongshanRoots or whole plantWarming spleen and stomach for dispelling cold, benefiting qi and nourishing blood, and coordinating yin and yangHypotensive, hypolipidemic, and modulates and improves cellular immunityProtocatechuic acid, gallic acid, and neochlorogenic acid[199,200,201,202,203]
200Pleurospermopsis bicolor (Franch.) Jing Zhou & J. WeierselengziqinWhole plantWarming spleen and stomach for dispelling cold, benefiting qi and nourishing blood, and coordinating yin and yangHypotensive, antilipemic, and modulates and improves cellular immunity, antimicrobial Chlorogenic acid, isochlorogenic acid A, and apigenin-7-O-β-D-glucuronopyranoside[199,201,202]
201Pleurospermum aromaticum W. W. Sm.fangxianglengziqinWhole plant\\\[1]
202Pleurospermum giraldii DielsTaibaidiangaobenWhole plant and seedsWarming spleen, digesting food, and treating vaginal dischargeInhibition of smooth muscle contraction and releasing intestinal smooth muscle spasmCarvone, n-triactanol, and γ-sitosterol[19,204,205,206]
203Pleurospermum rivulorum (Diels) K. T. Fu & Y. C. HoShetouqianghuoRoots or whole plantTonifying the kidney \\[1,102]
204Pternopetalum leptophyllum (Dunn) Hand.-Mazz.BaoyenangbanqinWhole plant\\\[16]
205Pternopetalum vulgare var. VulgareWupiqingRoots or whole plantTreatment of lumbago\\[19]
206Sanicula astrantiifolia H. Wolff ex KretschmerWupifeng or xiaoheiyaoWhole plantTonifying the kidney and lung, treating tuberculosis and kidney vacuity lumbar painAntioxidant, antibacterial, and bacteriostatTotal flavonoids, rutin, and polysaccharides[207,208,209]
207Sanicula caerulescens Franch.DafeijincaoWhole plantDispelling wind, treating phlegm, and promoting blood circulation for regulating menstruationExpectorant, antibechic, and anti-inflammatoryAngelicin, isoferulaldehyde, and 12-hydroxybakuchiol[19,210,211]
208Sanicula chinensis BungeShanqincaiWhole plantDetoxification, hemostasis, and treatment of throat painAntiviral\[129,212,213,214]
209Sanicula elata Buch.-Ham. Ex D. DonSanyeqiWhole plantUsed as Sanicula lamelligeraAntiviralOleanane saponins, saponins, and microelement[212,213,214,215,216,217]
210Sanicula lamelligera HanceDafeijincaoWhole plantDispelling wind, treating phlegm, and promoting blood circulation for regulating menstruationExpectorant, antibechic, and anti-inflammatoryAngelicin, isoferulaldehyde, and 12-hydroxybakuchiol[19,210,211]
211Sanicula orthacantha S. MooreHeiejiaobanRoots or whole plantHeat clearing and detoxifying, treatment of traumatic injury\\[16]
212Sanicula orthacantha var. Brevispina H. BoissieuYajiaoqiWhole plantHeat clearing and detoxifying, treatment of traumatic injury\\[16]
213** Saposhnikovia divaricata (Turcz.) Schischk.FangfengRootsDispelling wind, removing dampness to relieve pain, and arresting convulsionAnalgesia, sedation, and anti-inflammatoryPrim-o-glucosylcimifugin, 5-O-methylvisamitol glycoside, and cimifugin[18,218,219]
214Selinum cryptotaenium H. BoissieuLinagshechuangRoots\\\[1]
215Semenovia montana Kamelin & V. M. Vinogr.LieyeduhuoRoots\\\[122]
216Seseli delavayi Franch.YunfangfengRootsDispelling wind, removing dampness, and relieving pain\\[19]
217Seseli mairei var. MaireiYunfangfengRoots and rhizomeDispelling wind, removing dampness, and relieving painAntipyretic, analgesic, and anti-inflammatorySphondin, bergapten, and isopimpinellin[19,220,221,222]
218Seseli yunnanense Franch.ChuanfangfengRoots and rhizomeDispelling wind, removing dampness, and relieving painAntipyretic, analgesic, and anti-inflammatoryFalcarindiol, falcarinol, and glycerol monolinoleate[19,220,221,223]
219Seselopsis tianschanica Schischk.XiguiqinRootsTreatment of fall injury, anemia, and other diseasesTreatment of nasopharynx cancer\[16]
220Sium suave WalterCaogaobenWhole plantDispersing cold, relieving headache, and decreasing blood pressure\\[16,224]
221Spuriopimpinella arguta (Diels) X. J. He & Z. X. WangJianchidayeqinRoots and whole plant\\\[195]
222Tongoloa silaifolia (H. Boissieu) H. WolffTaibaisanqiRootsStopping bleeding, relieving pain, and activating bloodTreatment of traumatic injury, trauma bleeding, and rheumatic painSuberosin, crenulatin, and isoimperatorin[19,225,226]
223Tongoloa stewardii H. WolffGulingdongeqinRoots\\\[1]
224Torilis japonica (Houtt.) DC.HeshiFruits and rootsLumbricide ascaricide and external antiphlogistic agent\Essential oil[19]
225Torilis scabra (Thunb.) DC.HuananheshiFruits or whole plantActivating blood, insecticide, and antidiarrhealBacteriostatCyclohexene, 6,6-dimethyl-bicyclo [3.1.1] heptane-2-carboxaldehyde, and endo-borneol[19,195,227]
226Trachyspermum ammi (L.) Sprague.AyuweiFruitsDispersing cold, relieving pain, and treating indigestionAntibacterial, antimicrobial, and antifungalthymol, ρ-cymene, and β-pinene[19,188,228,229,230,231]
227Vicatia thibetica H. BoissieuXiguiRootsDispelling wind, eliminating dampness, and dispelling coldAnti-fatigue, antioxidant, and enhancing immunityUmbelliferone, bergapten, and ferulic acid[232,233,234]
228Visnaga daucoides Gaertn.AmiqinFruitsTreatment of coronary artery disease, such as coronary thrombosisTreatment of renal colic, angina pectoris, and urinary calculiKhellin, visnagin, and khellol glycoside[16,235]
Note: * means the plant reported in “Pharmacopoeia of the People’s Republic of China (2020)”, ** means the plant roots used as medicine reported in “Pharmacopoeia of the People’s Republic of China (2020)” [18].
Table
Table 2. Quality markers in the 22 AMPs recorded in the “Pharmacopoeia of the People’s Republic of China” (2020) [18].
Table 2. Quality markers in the 22 AMPs recorded in the “Pharmacopoeia of the People’s Republic of China” (2020) [18].
No./No. in
Table 1		Plant SpeciesQuality MarkersClassificationBiosynthetic Pathway
1/8Angelica biserrataOsthole (1) and columbianadin (2)CoumarinsPhenylpropanoids
2/10Angelica dahuricaImperatorin (3) and isoimperatorin (4)CoumarinsPhenylpropanoids
3/11Angelica dahurica cv. Hangbaizhi(3) and (4)CoumarinsPhenylpropanoids
4/13Angelica decursivaNodakenin (5)CoumarinsPhenylpropanoids
5/20Angelica sinensisFerulic acid (6) and ligustilide (15)Propenyl benzenes and phthalidesPhenylpropanoids and phthalides
6/34Bupleurum chinenseSaikosaponin a (11) and saikosaponin d (12)TriterpenesTerpenes
7/67Bupleurum scorzonerifolium(11) and (12)TriterpenesTerpenes
8/79Changium asiaticaAsiaticoside (13) and madecassoside (14)TriterpenesTerpenes
9/80Changium smyrnioides
10/83Changium monnieri(1)CoumarinsPhenylpropanoids
11/94Daucus carota
12/102Ferula fukanensis
13/109Ferula sinkiangensis
14/112Foeniculum vulgareTrans-anethole (7)PhenylpropenePhenylpropanoids
15/113Glehnia littoralis
16/159Ligusticum chuanxiong(6) and levistilide A (16)Phenylpropanoids and phthalidePhenylpropanoids and phthalides
17/160Ligusticum jeholense(6) PhenylpropanoidsPhenylpropanoids
18/162Ligusticum sinense(6) PhenylpropanoidsPhenylpropanoids
19/167Notopterygium franchetii(4), (5), and notopterol (8)CoumarinsPhenylpropanoids
20/168Notopterygium incisum(4), (5), and (8)CoumarinsPhenylpropanoids
21/186Peucedanum praeruptorumPraeruptorin A (9) and praeruptorin B (10)CoumarinsPhenylpropanoids
22/213Saposhnikovia divaricataPrim-O-glucosylcimifugin (17) and 5-O-methylvisammioside (18)ChromonesChromones
Note: “–” indicates there are no specific quality markers recorded in the “Pharmacopoeia of the People’s Republic of China” (2020) [18].
Table
Table 3. Classification of the 38 rhizomatous AMPs affected by BF.
Table 3. Classification of the 38 rhizomatous AMPs affected by BF.
No./No. in Table 1Plant SpeciesClassesReferencesNo./No. in Table 1Plant SpeciesClassesReferences
1/4Angelica acutiloba (Siebold & Zucc.) Kitag.(1)[306]20/109* Ferula sinkiangensis K. M. Shen(3)[19]
2/8** Angelica biserrata (R. H. Shan & C. C. Yuan) C. C. Yuan & R. H. Shan(1)[307]21/111Ferula teterrima Kar. & Kir.(3)[19]
3/10** Angelica dahurica (Fisch. ex Hoffm.) Benth. & Hook. f. ex Franch. & Sav.(1)[308]22/113** Glehnia littoralis F. Schmidt ex Miq.(2)[309]
4/11** Angelica dahurica cv. Hangbaizhi(1)[308]23/121Heracleum hemsleyanum Diels(1)[307]
5/13** Angelica decursiva (Miq.) Franch. & Sav.(1)[310]24/126Heracleum rapula Franch.(1)[19]
6/14Angelica gigas Nakai(2)[311]25/148Levisticum officinale W. D. J. Koch(3)[19]
7/19Angelica polymorpha Maxim.(1)[19]26/149Libanotis buchtormensis (Fisch.) DC(3)[312]
8/20** Angelica sinensis (Oliv.) Diels(1)[313]27/150Libanotis iliensis (Lipsky) Korovin(1)[19]
9/26Anthriscus sylvestris (L.) Hoffm.(3)[314]28/151Libanotis lancifolia K. T. Fu(3)[19,312]
10/34** Bupleurum chinense DC.(2)[315]29/153Libanotis seseloides (Fisch. & C. A. Mey. ex Turcz.) Turcz.(1)[19]
11/67** Bupleurum scorzonerifolium Willd.(2)[315]30/155Libanotis spodotrichoma K. T. Fu(3)[19,312]
12/80** Changium smyrnioides H. Wolff(2)[316]31/159** Ligusticum chuanxiong Hort. (2)[317]
13/81Chuanminshen violaceum M. L. Sheh & R. H. Shan(2)[318]32/160** Ligusticum jeholense Nakai et Kitag.(2)[319]
14/82Cicuta virosa L.(3)[19]33/162** Ligusticum sinense Oliv.(2)[319]
15/96Daucus carota var. sativus Hoffm.(1)[320]34/167** Notopterygium franchetii H. de Boiss.(2)[321]
16/102Ferula feruloides (Steud.) Korovin(3)[19]35/168** Notopterygium incisum Ting ex H. T. Chang(2)[321]
17/103Ferula fukanensis K. M. Shen(3)[19]36/186** Peucedanum praeruptorum Dunn(1)[322]
18/106Ferula lehmannii Boiss.(3)[19]37/195Pimpinella candolleana Wight & Arn.(3)[19]
19/108Ferula olivacea (Diels) H. Wolff ex Hand.-Mazz.(3)[19]38/213** Saposhnikovia divaricata (Turcz.) Schischk.(1)[323,324]
Note: (1) BF significantly affects the yield and quality, and the rhizomes or roots cannot be used for clinical applications; (2) BF differently affects the yield, but the rhizomes or roots can be used as medicine to some extent; and (3) BF has no significant effect on the yield and quality, and their rhizomes or roots are used as medicine. * means the plant reported in “Pharmacopoeia of the People’s Republic of China (2020)”, ** means the plant roots used as medicine reported in “Pharmacopoeia of the People’s Republic of China (2020)” [18].
Table
Table 4. Reported approaches for inhibiting BF in 25 AMPs.
Table 4. Reported approaches for inhibiting BF in 25 AMPs.
ClassNo./No. in Table 1Plant SpeciesMeasure I
(Seeding)		Measure II
(Cultivation)		Measure III
(Abiotic)		Measure IV
(Molecular Biology)
(1)1/4Angelica acutiloba (Siebold & Zucc.) Kitag.Seedling diameter [339]Density of planted seedlings [339]Paclobutrazol concentration [339]\
(1)2/8** Angelica biserrate (R. H. Shan & C. C. Yuan) C. C. Yuan & R. H. ShanSeedling size and root length [307]\\\
(1)3/10** Angelica dahurica (Fisch. ex Hoffm.) Benth. & Hook. f. ex Franch. & Sav.Seed quality and seed maturity degree [308,333]Soil selection to avoid continuous cropping and fertile sticky soil, density of planted seedlings, and seeding time [333,335,340]Rational application of fertilizer, and appropriate N, P, and K fertilizer [308,333,341]Seven types of reproductive conversion genes, and constans-like genes [342,343]
(1)4/11** Angelica dahurica cv. HangbaizhiSeed quality and seed maturity degree [308,333]Soil selection to avoid continuous cropping and fertile sticky soil, density of planted seedlings, and seeding time [333,335,340]Rational application of fertilizer, and appropriate N, P, and K fertilizer [308,333,341]Seven types of reproductive conversion genes, and constans-like genes [342,343]
(1)5/13** Angelica decursiva (Miq.) Franch. & Sav.\\\\
(1)6/19Angelica polymorpha Maxim.\\\\
(1)7/20** Angelica sinensis (Oliv.) DielsSeed maturity degree, seeding age, seeding weight, root diameter, and excellent variety [328,330,344,345,346]Short day, storage temperature, and reasonable planting and cultivation [313,344,347]Plant growth retardant [348]Four pathways of genes for regulating early BF [349,350]
(1)8/96Daucus carota var. Sativus Hoffm.Endogenous hormone content and different cultivars [351,352]Temperature, short day, and seeding time [351,353,354,355]\Two major genes: Bol1-1 and Bol1-2 [356]
(1)9/121Heracleum hemsleyanum Diels\\\\
(1)10/126Heracleum rapula Franch.\\\\
(1)11/150Libanotis iliensis (Lipsky) Korovin\\\\
(1)12/153Libanotis seseloides (Fisch. & C. A. Mey. ex Turcz.) Turcz.\\\\
(1)13/186** Peucedanum praeruptorum Dunn\Compact planting and seeding time [357,358]\\
(1)14/213** Saposhnikovia divaricata (Turcz.) Schischk.\Density of planted seedlings [338]\Differentially expressed genes associated with BF during early flowering, flower bud differentiation, and late flowering [359]
(2)15/14Angelica gigas Nakai\\\\
(2)16/34** Bupleurum chinense DC.\Cut the flowers [315]Temperature [360]Flowering gene (BcSVP, BcPAF1, BcCO, and BcFT) [361]
(2)17/67** Bupleurum scorzonerifolium Willd.\\\\
(2)18/80Changium smyrnioides H. Wolff\Cut the flowers [316]\\
(2)19/81Chuanminshen violaceum M. L. Sheh & R. H. Shan\\\\
(2)20/113** Glehnia littoralis F. Schmidt ex Miq.\Cut the flowers [309]\\
(2)21/159** Ligusticum chuanxiong Hort.Asexual reproduction and tissue culture [317,362]Cut the bolted stem [363]\Transcriptome original data by Illumina sequencing technology [364]
(2)22/160** Ligusticum jeholense Nakai et Kitag.\Cut the flower [365,366]\\
(2)23/162** Ligusticum sinense Oliv.\Cut the flower [365,366]\\
(2)24/167** Notopterygium franchetii H. de Boiss.\Cut the flower [367]\\
(2)25/168** Notopterygium incisum Ting ex H. T. Chang\Cut the flower [321]\\
Note: ** means the plant roots used as medicine reported in “Pharmacopoeia of the People’s Republic of China (2020)” [18].
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Li, M.; Li, M.; Wang, L.; Li, M.; Wei, J. Apiaceae Medicinal Plants in China: A Review of Traditional Uses, Phytochemistry, Bolting and Flowering (BF), and BF Control Methods. Molecules 2023, 28, 4384. https://doi.org/10.3390/molecules28114384

AMA Style

Li M, Li M, Wang L, Li M, Wei J. Apiaceae Medicinal Plants in China: A Review of Traditional Uses, Phytochemistry, Bolting and Flowering (BF), and BF Control Methods. Molecules. 2023; 28(11):4384. https://doi.org/10.3390/molecules28114384

Chicago/Turabian Style

Li, Meiling, Min Li, Li Wang, Mengfei Li, and Jianhe Wei. 2023. "Apiaceae Medicinal Plants in China: A Review of Traditional Uses, Phytochemistry, Bolting and Flowering (BF), and BF Control Methods" Molecules 28, no. 11: 4384. https://doi.org/10.3390/molecules28114384

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