William Chi Keung Mak
School of Life Science, University of Technology Sydney, Ultimo, Australia.
DOI: 10.4236/jbm.2021.912011   PDF    HTML   XML   170 Downloads   1,075 Views   Citations

Abstract

Prunella vulgaris (PV) is a herb which grows widely around the world. It is used in traditional medicine in different continents worldwide. This article reviewed the research studies in the last three decades about the use of this herb in the treatment of cancer. Specifically, this study concentrates on the scientific in-vitro methods used, as the in-vitro methods were the most preferred methods used in the past. Cell viability/apoptosis, migration, anti-oxidative activities, and the underlying molecular mechanisms were the features which most of the research focused. The aim of this article was to summarize on what molecular mechanisms, which these previous research found responsible for the anti-tumoral effect of PV. The assays to investigate the aforementioned items were organized and displayed, including the proteomic methods which study the underlying molecular mechanisms. By categorizing and organizing these methods, the directions and emphases taken by the research efforts were revealed.

Keywords

Chinese Herbal Medicine, Prunella vulgaris, Xia Ku Cao, In Vitro Methods, Molecular Mechanisms, Functional Assays

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1. Introduction

Prunellavulgaris (PV) is a plant which is widely grown around the world. It was used traditionally for medicinal treatment in Eastern Europe, the Indian Sub-continent, North America, and China for many generations. In common, this herb was used as a remedy for reducing fever, wound healing, and sore throat [1].

A preliminary literature review was done with the database, Pubmed, alone to gather initial information. This collected a total of 206 articles. Among these 206 articles, the research on PV can be divided into three broad areas: pharmacological, phytochemical and agricultural areas, apart from some general review papers; for examples, [2] [3] and [4].

In the area of pharmacological research, one interesting topic is to investigate the anti-tumoral effect of PV. This anti-tumoral effect of PV was what the current review focused on. Among the previous research projects, they used different methodologies; namely, in vivo, in vitro and in silico methods. They probed the antitumoral efficacy of the herb. To achieve our aims, we concentrated on the in vitro methods. This enabled the molecular mechanisms behind the anti-tumoral effect of PV to be revealed. Research on the anti-tumoral effect of PV was reviewed before: In an article by Huang et al. [5], the review just included the In vitro methods as a section in their discussions. Another newer review paper by Wang et al. [6] did a review that summarizes the chemical constituents, pharmacological effects and clinical applications of the herb. An even more recent article by Gan et al. [7] did a network search to summarize the bioactive ingredients of the herb. It explored the molecular mechanisms of how PV works, which followed the same approach described in the current article; however, it just concentrated on using the herb to treat Hashimoto’s thyroiditis.

By concentrating on those articles which used the appropriate in vitro methods, a collective review of the responsible molecular mechanisms can be summarized.

2. Methods

To undertake systematically the review, we adhered to the following steps: We defined the limits of the investigation by spelling out what articles were included in this review, outlined the aims of this review. Then, we explained the methodologies to carry out the literature review to select the articles to be analysed.

2.1. Limits of This Investigation

To set the limits of this investigation, the first limit, of course, is to limit the attention only on the pharmacological effects of PV.

A survey of the literature shows that PV is effective to treat a wide variety of diseases. It is difficult to take a deep investigation at every one of the diseases investigated. This investigation concentrated on the anti-tumoral effect; in particular, on the survey of research methods used. Especially, the attention was on those research projects which used in-vitro methods based on molecular biology. The in-vitro methods were chosen as the most popular research methods used (Figure 1).

2.1.1. Aims of This Investigation

Over the past 30 years when the research started working on PV, this survey witnessed a gradual development of technology which the various methods are based on. In earlier years, research projects mainly used colorimetric assays, such as the MTT assay, to characterize the change in the functioning of cells

upon application of the herbal treatment; for example, impact on cell viability, an issue which many investigations probed. In recent years, the choice shifts to proteomic assays, which clarify the molecular mechanisms more clearly.

A major aim of this article was to determine the main molecular mechanisms which the previous research projects focused their efforts on and was responsible for the anti-tumoral effect of PV. Also, what types of assays were chosen to explore these molecular effects.

Then, a secondary aim was to look at the functional tests used to study issues such as cell viability, proliferation, migration, morphological changes of cancer cells upon herbal treatment. These include methods such as the colorimetric assays, and observational methods using microscope or flow cytometry. The functional changes include morphological changes, migration or propagation. Colorimetric assays were the most popular choices.

2.1.2. Approach of the Literature Review

To comprehend a general idea of the scope of studies done on PV in the past, a preliminary literature search was done using a very general term “Prunellavulgaris” as the keyword, and the reputable database, Pubmed, was used.

A more detailed literature search was done recently using three databases: Pubmed, Medline and Embase. They were chosen because of their popularity within the research community. This enabled the inclusion of as many relevant articles as possible without omission.

Nearly all the articles found were included except those articles which used the in-vivo methodology only. Studies which reported clinical studies, single case report, ethnobotanical survey and in silico analysis were also excluded. A PRISMA flowchart for articles investigating the anti-tumoral effect is included in Figure 2. It is worth to mention that about 40 more articles were discovered in the final search as compared with the initial search done about a year ago. This reflected the enthusiastic research interests on this herb.

3. Results

The result section is organized into two parts: One pertaining to the first aim, which is to look at what molecular mechanisms were found responsible for the efficacy of PV, another part pertaining to what functional assays were used by previous researchers. At the end of this article in the Appendix section, we include a summarizing descriptive table of all the articles included in the review.

To investigate the anti-tumoral effects of PV, different phenomena were observed experimentally. As discussed above, we concentrated on those articles which used the in-vitro methods. Figure 3 summarizes the different phenomena observed.

Apoptosis/cell viability was the most popular phenomenon investigated; also, observing the effects on changes in the genomic/proteomic expressions of the treated cells were also frequently taken, comprising 76% and 54% of all the articles surveyed. The differential genomic/proteomic expressions indicate the molecular mechanisms behind the effects of the herb. This is the main aim of this review.

3.1. Results Pertaining to the Major Aim: A Look at the Molecular Mechanisms Responsible for the Antitumoral Activity of the Herb

As the technology advances throughout these 3 decades, more and more studies were done using the genomic and proteomic approaches. The use of these approaches reveals the molecular mechanisms more clearly behind the anti-tumoral effects of the herb. The main theme of this review is to summarize on the molecular mechanisms.

Figure 4 shows the different techniques in genomic and proteomic methodologies. These techniques measure the cellular products such as intracellular proteins, enzymes, and intercellular signaling cytokines. By monitoring the changes in these entities resulting from the treatment of the herb will elicit the genomic expression pathways involved and thus expose the underlying molecular mechanisms.

To elicit what molecular mechanisms which the researchers in the last 3 decades most popularly investigated, several approaches can be taken. In this article, we choose to discuss in terms of the entities, such as proteins, genes, or RNAs being studied to expose the underlying pathways and mechanisms; an approach which we think is the most clarifying (Figure 5), as follows:

1) Bcl-2/Bax [8] [9]

From Figure 5, it is obvious that the most frequently investigated regulating proteins were the apoptosis regulating Bcl-2 (B-cell lymphoma 2) family, which includes pro-apoptotic members (such as Bax) and anti-apoptotic members (such as Bcl-2). They are involved in the intrinsic pathway of mitochondria-related apoptotic activation mechanism. They have significant role in the lymphoma growth cell cycle, and thus given the most attention. Related proteins in the apoptotic process such as Apaf-1, caspases, and cytochrome c were also tested in other articles.

From Figure 6, the most frequent techniques used were immunocytochemical methods, such as ELISA, followed by Western blotting.

In all the articles surveyed, when the Bcl2/Bax expressions were investigated, they did show that PV was effective to decrease the expression of Bcl2 and increase that of Bax. However, even when experiments were done quantitatively, numerical data were not given in the articles. The closest to this is, for example, to give a p-value (P < 0.05) to show that the differential Bcl2/Bax expressions were statistically significant [10].

Another example which reported the effects of the extracts of endophytic fungus from PV to inhibit gastric cancer. The study reported that a dosage of 100 mg/kg/day (this study used an in-vivo mice model) treating tumor tissue caused a decrease of Bcl2 and an increase of Bax levels [11].

There was an article [12] which described the use of PV to treat B lymphoma cell line Raji cells and T lymphoma cell line Jurkat cells. It showed that,with the same dosage, the degrees of decrease in the Bcl-2 expression level and the increase in Bax protein expression in Raji cells were more significant than that in Jurkat cells (P < 0.05).

In an article which investigated Bcl-2 [13], the signal transduction pathway was further investigated to trace back to the PI3K/AKT signaling pathway. Using Western blotting, it was shown that PV extract inhibited the expression of p-PI3K and p-AKT but did not affect the expression of PI3K and AKT, and thus, explored the role of the PV extract application as anti-tumoral.

2) Caspase-3,9 [14] [15]

Caspases are a family of proteases which act as enzymes for programmed cell death, in which targeted proteins are attacked and cleaved. So, they play a key role in inducing cell death in abnormally growing cancer cells. Some of them are involved in the activation of inflammatory responses. Caspases are classified into different types, in which caspase-3 acts as executioner, and caspase-9 as initiator of apoptosis. The process of cell death through the action of caspases is complex, which consistsof complex chain reactions involving multiple proteins, enzymes and cytokines.

For the investigations on the caspases, the methods chosen were about the same as those for Bcl-2. One additional method used was the fluorometric/colorimetric assays [16]. Similarly, the research projects did not depend on a single method. For example, in a project which studied the effect of PV on gastric adenocarcinoma SGC-7901 cells [17], the alternations in the gene expression levels were studied using a cDNA microarray, real-time qPCR and immunohistochemical methods.

In all these previous studies, the caspases-3, 9 and 12 were followed. The expression levels of caspases were significantly increased by the treatment of PV. In these studies, usually more than one protein was examined. These somehow indicated more clearly which pathways were involved in the apoptosis process. For example, Yang et al. [18], reported that, other than an increase in the caspase-3, and -9 levels, hyperoside in PV increased the phosphorylation of p38 MAPK and JNK, disrupted the mitochondrial membrane potential, increased the release of cytochrome c from the mitochondria into the cytosol. These revealed the whole apoptotic pathway through the mitochondrion. Another article [19] also revealed this mitochondrion-mediated apoptotic pathway by following the expressions of multiple proteins.

Another article quantified that a dosage of PV of 30 µg/mL was enough to up-regulate the expression of caspase-3 [20]. In this previous article, the authors, Zhang and Wang, explored the synergistic effects of PV when used together with anti-tumoral drugs paclitaxel and adriamycin. They showed that PV enhanced the effects of these drugs.

3) NF-κB [21] [22]

The nuclear factor NF-κB is a protein which acts on controlling the transcription of DNA, and the production of cytokines, and thus, is involved in the immune responses of cells to various kinds of external stimuli. So, NF-κB is a key component to regulate inflammatory responses to infection. Its abnormal function or expression is thus implicated in cancer development and other inflammatory diseases. The characterization for its differential expression is used to study the anti-tumoral effects of drugs. Known inducers of NK-κB activation such as the interleukin, TNF-α, and its inhibitors, IκBs, were also included in some studies in the articles found.

While immunocytochemical methods and Western blotting were the main methods chosen to investigate protein expressions relating to NF-κB, additional methods were used to study NF-κB. The effect of the application of the herb on NF-κB expression can be deduced by the successive pretreatment of NF-κB activation inhibitor, IκB, and then, observing the effect on the downstream MMP-9 expression. Also, NF-κB binding activity to DNA can be examined by electrophoretic mobility shift assay [23].

NF-κB situates upstream of the expressions of cytokines related to inflammation, and of proteins related to metastasis and epithelialmesenchymal transition. The studies on these issues concentrated on the investigations on MMP-9 [24] [25] [26], vimentin, N-cadherin, β-catenin [27]. In these studies, the levels of expressions of these proteins will show the molecular signaling pathways which involve NF-κB.

4) MAPK, ERK, and JNK [28] [29]

On the left of the graph in Figure 5, the enzymes MAPK (mitogen activated protein kinases), ERK (extracellular signal-regulated kinases), and JNK (c-Jun N-terminal kinases) are shown. Indeed, these enzymes belong to the same family, but were given different names because of historic reasons. These enzymes are related to the Ras-Raf-MEK-ERK genomic pathway, which responds to intercellular or exterior stimulating signals such as cytokines, UV radiation, osmotic stress, and heat stress. The responses include the regulation of cell functions from proliferation, differentiation, cell cycle progression, division events such as mitosis and meiosis, to cell survival and apoptosis. Disruption in these signaling pathways, such as the malfunction of the proteins in the pathways, can cause cancers.

The articles which reported investigations on these kinases had been described in the paragraphs above looking into those proteins. This means that signaling transduction pathways relating to these kinases were identified by following multiple proteins: mitochondrial cytochrome c, caspase-3,9 [18], MMP-9, NF-κB [24] [26].

Comparing the differential expressions of these enzymes upon the application of herbal treatment showed the genomic pathways which were involved in the anti-tumoral action.

5) MMP-2,9 [30] [31]

When metastasis was the issue studied, cell surface proteins were used as the target of investigation. The most frequently studied proteins were the MMPs (matrix metalloproteinases) and the other related cell surface proteins. MMPs are proteases responsible for the degradation of all kinds of extracellular matrix proteins so that epithelial-to-mesenchymal transition can proceed; cancer cells can then be set free and move to other part of the body. Other cell surface proteins, such as TIMPs, cadherins, catenins, vimentin, were also targets of investigation in metastasis of cancer cells.

The articles which investigated metastasis through the study on MMP-9 were described in [24] [25] and [26]. There was another article on metastasis which studied MMP-2 [32].

These studies showed that the application of the herbal treatment effectively reduced the abnormal expressions of the MMPs.

6) Growth Factors: bFGF, VEGF, and IL-8 [33] [34] [35]

Growth factors are cell signaling proteins, cytokines or hormones which carry signals among cells. They usually function by activating cell surface receptors to initiate a wide variety of cellular processes, including cellular growth, proliferation, tissue remodeling. FGF1 and FGF2 (fibroblast growth factors 1 and 2) have an important function to stimulate endothelial cell organization to form tube-like structure, and thus they involve in angiogenesis, an important process in cancer cell development. It was shown that FGF2 (aka bFGF) promoted human carcinoma-associated fibroblast (CAF) proliferation and migration, protected CAFs from apoptosis and reduced cells in G₀ phase in cell cycle [36]. VEGF (vascular endothelial growth factor) is another important angiogenic factor.

The articles which studied the growth factors mainly looked at the anti-angiogenic effect of the PV herb [11] [37] [38]. By competitively binding of the sulfated polysaccharide extracted from PV to the cell binding domain of bFGF, it was shown that PV significantly inhibited the proliferation, and down-regulated migration, increased apoptosis of cancer cells [39], while another article showed that PV had anti-tumoral effect by inhibiting bFGF expressions [36]. An anti-tumoral formula which includes PV was shown to suppress the expression of EGFR [40]. The polysaccharide in PV could inhibit bFGF expression, and thus exerted anti-tumoral effect [36].

There were also articles which followed the suppressive effect of PV chemical constituents, and the most frequent choice, rosmarinic acid, on the expression level of the angiogenic growth factor IL-8 [38] [41].

3.2. Results Pertaining to the Secondary Aim: A Look at the Functional Tests

3.2.1. Using Colorimetric Methods to Check Cell Viability

To fulfil the secondary aim, we started by discussing the functional assays using colorimetric methods. In earlier days, for example in the tests for cell viability, colorimetric methods were the preferred methods, with the use of the tetrazolium salt MTT being the most popular.

As shown in Figure 3, most of the articles which investigated the anti-tumoral effects of PV, frequently examined cell functions (phenomenon) which were apoptosis/cell viability, proliferation, and migration.

To examine cell viability, two large groups of assays followed the cell metabolic activity and the cell membrane permeability respectively. To observe these, often some dyes are used. Assays can be further classified as fluorometric assays or colorimetric assays, depending on whether the observed light is due to emission or reflection.

Other than monitoring the cell viability, the use of optical observation is often applied to examine other functional changes (Figure 3) due to herbal applications.

1) Cell metabolic activity assays

One commonly used group of assays which examine cell metabolism is based on the tetrazolium dyes. The most popular assay is the MTT assay, which monitors the NADPH-NADP redox metabolic reactions of living cells when they are alive. In the process, the yellow MTT dye is reduced to its purple counterpart formazan [42] [43]. Other closely related tetrazolium dyes include MTS, XTT and WSTs. These are colorimetric assays shown in Figure 7. Most of the assays shown there depend on optical observation. However, they are often used in conjunction with other techniques; for example, Annexin V FITC/PI is often used together with flow cytometry.

2) Cell membrane permeability assays

When cells are failing, the cell membrane becomes more permeable. So, measuring the leakage of the cell membrane is a way to measure cell viability. For example, LDH leakage assay is one of these [44], which measures the leakage of a common enzyme, lactate dehydrogenase, across the cell membrane. The middle six bars in Figure 7 pertain to this group of assays which monitor the cell membrane permeability. They are all dye based. Dependent on the permeability of these dyes across the cell membrane, they can be used to measure the cell viability.

Annexin V FITC (Fluorescein Isothiocyanate)/PI (Propidium iodide) was the second most popular assay used in the articles which measure cell viability. It is a combined use of the DNA staining dye, propidium iodide, with annexin V, which is fluorescently labeled by FITC and binds to phosphatidylserine, a marker of apoptosis on cell surface, to measure cell apoptosis and necrosis [45]. This assay is often used together with flow cytometry to monitor early-stage apoptosis and cell cycle.

3.2.2. Other Functional Assays

Other than the colorimetric assays discussed above, it is worthwhile to describe some assays which do not use colorimetric methods, but observe some phenomena, like the cell proliferation, migration, morphological changes, or colony formation, directly under a microscope. The assays in this group are shown in Figure 8.

3.2.3. Assays Which Observe the Anti-Oxidative Activity

As the status of the presence of ROS in the tumor environment relates closely with the development, proliferation and growth of cancer cells, researchers frequently probed the anti-oxidative activity of the herb. See Figure 9.

In Figure 9, the six bars on the left pertain to assays which use reagents that mix chemicals together to behave as oxidizing agents or radical traps. They then measure the reducing power of the samples under test for their anti-oxidative capabilities. SOD refers to superoxide dismutase, an enzyme which cells uses to catalyze dismutation of superoxide radicals. Thus, its measurement indicates the oxidative stress. Malondialdehyde is a naturally occurring marker of oxidative stress, and glutathione is a naturally occurring antioxidant in cells. So, their measurements give the anti-oxidative state also.

4. Discussion

4.1. Variations Which Make Standardization Difficult

All the articles surveyed showed that PV was effective and possessed anti-tumoral effect in a dosage dependent manner, except four. Three of them [46] [47] [48] showed certain main constituents in PV only had marginal cytotoxicity towards certain cancer cell lines. One article [49], however, showed that PV was ineffective for neuroendocrine tumor. Also, many studies singled out single compounds such as the oleanolic acid, rosmarinic acid and polysaccharides in PV to test its cytotoxic effect and showed that they are effective.

However, it is difficult to summarize their findings collectively. There are five-folded reasons for this:

1) Different materials were tested

Different materials were tested in different studies: the PV spica, the PV root, specific compounds which are the constituents found in PV, or the combination of several herbs, including PV as one of them in a herbal formula. In Figure 10, the first and the second groups, “PV spica” and “PV extract” are indeed the same, as active compounds need to be extracted from the plant before they can be analyzed. However, some articles did not mention whether they started off with the spica part of the plant, or they bought the extracts from outside sources. Thus, they are separated into two groups in this Figure 10. However, combining them, they account for nearly one half of the articles surveyed.

Some researchers focused on just a single target chemical component in PV; for examples, rosmarinic acid [41], and oleanolic acid [50] were the most popular choices. These compounds were previously shown in prior investigations to be anti-tumoral. Some researchers researched on formulae which combined several herbs including PV; for examples, Ruanjian Sanjie decoction [51], Wei Chang An [17].

A large group of 20% of the articles shown in Figure 10 are comparison papers, which compared the efficacy of multiple herbs or multiple compounds. Two articles [52] and [53] stated that they used PV injection drug, and one article [54] stated that it used PV granules, but they did not mention the methods of preparation of these secondary products from the raw herb. Lacking the preparation method makes their experiments unrepeatable. Similarly, the selection of different materials makes it difficult to summarize systematically the pharmacological efficacy of PV.

Some projects aimed to explore the interacting and comparative effects of using PV together with anti-tumoral Western drugs; for examples, paclitaxel, Adriamycin [20] and 5-fluorouracil [17]. Then, comparison with articles which explored the effect of using PV alone is invalid. An example can be shown by the results in one investigation [20]: They compared the improvements in the inhibitory effect on tumor proliferation when PV extract was used in combination with two Western drugs: taclitaxel and adriamycin, with the effect of using the Western drugs alone. When PV extract at a dosage of 0.8 µg/mL was used with taclitaxel, the improvement on inhibiting the proliferation of lymphoma Raji cells was ten-fold better than the improvement when PV extract at a dosage of 0.08 µg/mL was used with adriamycin (Table 1).

2) Lack of a unified measure to show the results

One more hurdle to collectively summarize all their results is that they did not have a unified measure to show their findings. For in-vivo experiments, many articles quoted the animal body weight or the tumor weight [55], the spleen index or the thymus index [56], or the animal survival time [52]. For in-vitro experiments, some quoted the percentage improvement as compared with the

control; for example, Zhao et al. [17] quoted an improvement of the tumor inhibitory rate of 44.32% when compared with the control, and the apoptosis index of 9.72% when using the herb, as compared with 2.45% of the control. A more frequent used measure is the half maximal inhibitory concentration, IC₅₀. Some used the IC₅₀ for proliferation; for examples, [53] [54] [57], and some used the IC₅₀ for apoptosis; for examples, [16] [46] [54]. However, even more disturbing for comparison is that some used the unit of molar concentration, but some used weight per unit volume. Refer to Table 1, it demonstrates the closest we can get to make a direct comparison of the results from six of the previous studies. These projects chose the same unit, weight per unit volume, as the measure to report the IC₅₀.

It can be seen that the IC₅₀ results obtained in these studies varied widely. The wide difference is understandable when different forms of the PV drug were used, for example, PV injection, or using a herbal formula which consisted of more than one herb. The results would be different also if the extract of the PV root was used instead of the commonly used spica. From the results of Zhang and Wang [20] when PV extract was used in combination with different Western drugs, the IC₅₀ values might be ten-fold different. Also, for different cancer types, the IC₅₀ values were different. All these factors contribute to highlight why the IC₅₀ numbers shown in Table 1 can be a thousand-fold different.

3) Lack of information on the geographical sources of herb

Also from Figure 11, only 13% of the articles surveyed stated the geographical regions where their samples were sourced from. According to some studies [59] [60] [61], they showed that PV plants grown in different geographical regions had different profiles of chemical compositions. For example, an article [59] showed the chemical compositions of PV from 5 different producing regions in China were all different. So, the pharmacological effects of the plant from different producing regions will not be the same. The results from different studied regions cannot, indeed, be compared against each other if they do not specify the place of origin, where the plant was grown and harvested. This important information should at least be indicated, but most researchers did not care. In addition, there were articles [62] [63] which showed that the variations in water treatment and the harvest time also caused changes in the bioactive components of the plant. This raises the question of how to control the standard quality of the herb used for medical use.

4) No standard dosage

Even about half of the articles which used the raw herb, the PV spica, as the material to be tested, did not use a standard dosage. Moreover, the authors sourced their herbal samples from different sources; some from herbal dispensaries, some from their affiliated institutes, like hospitals. No standard sources made it difficult to fix a standard dosage. From Figure 11, it reveals a bigger problem that about one-third of the articles did not even mention where they obtained the herbal samples.

5) No standard extraction and preparation methods

There was not a standard extraction method. From Figure 12, different articles used different methods for extraction. The most frequently used method was by decoction, which is the traditional method of preparing herbal medicinal tea by boiling the herb with water; for example, in the project by Cho et al. [27]. The dried extract was then obtained by vacuum evaporation or lyophilization. This accounts for about one-quarter of the articles surveyed. The other frequently used solvents were ethanol [64] [65], and methanol [66]. Depending on the polarity of the solvent, the chemical components which were extracted would then be different. However, even many articles did not mention the extraction method at all; some may be because they used over-the-counter forms such as extracts, herbal injection or granules, so that the extraction methods were unknown. One more complication is that even if articles used the same solvent, the solvent were at different concentrations (for example, some used 70% ethanol and some used 95% ethanol), or at different extraction temperatures. These variations affected the profile of the chemical compositions of the extracts too.

About the extraction techniques used, other than by decoction, many of the studies used the reflux methods, like the Soxhlet method. A few used silica gel chromatography or sonification.

In summary, from the discussion above, the approaches taken in these previous studies to obtain their results varied; were piecemeal and unorganized. It is thus impossible to summarize meaningful collective answers to many questions on the anti-tumoral effects of PV, like what the most effective chemical components in PV are, what method for extraction is the best, and many other queries.

4.2. Limitations in the Pharmacological Research of Chinese Herbs

This article discussed the use of the herb, PV, for the treatment of tumor. Especially, it analyzed the in-vitro methods used in the past 3 decades. By looking in-depth into these articles, certain limitations in the pharmacological research of Chinese herbs were exposed. In traditional Chinese herbal medicine, a whole plant, or part of it; say, the root or the spica is used as the drug. In Western medicine, drugs are just a certain chemical compound found in a plant, or the combination of individual compounds. Then, it is easy to identify uniquely what material is investigated. Giving the chemical molecular formula of the compound(s) uniquely identifies the drug. In herbal medicine, it is not so straightforward. As pointed out in different articles, for example [59], a certain herb, such as PV, has different chemical components for plants grown in different geographic regions. The composition also depends on other factors such as the drought condition [67], variations in UV-B radiation [68] and altitude of producing area [69]. These variations of different factors weaken the quality of the research, as these various factors affect the morphology of the plant; then, the identity of what material is investigated becomes ambiguous. This also poses difficulty in the identification of herbs. So, many researchers just resorted to authorities, for example, by saying a certain professor verified the identity of the herb. Some researchers simply omitted the identification step of the herbs they used completely. This is far from ideal.

If the geographical origins are not explicitly spelt out, the ambiguity weakens the quality of the research. However, sometimes this is unavoidable, as most herb suppliers mix the products they source from different growing areas. It is thus not always possible to state the geographical origin.

From the categorization of all these previous research studies, it highlights that researchers believe that PV is most effective in treating breast cancer, lymphoma, leukemia and colon cancer. However, as indicated in Table 1, by looking at the wide range of IC₅₀ values, even for the same cancer type or for the same extraction method, it is not feasible to conclude how effective the PV herb can be, what the effective dosage is, or which extraction method is the best.

For the main aim of this paper to identify what molecular mechanisms are responsible for the anti-tumoral effect of the PV herb, Bcl/Bax and caspases are the most popular proteins which most researchers concentrated their attention on. This highlights that they regarded the intrinsic pathway of mitochondria-related apoptotic activation [10] [11] [12] [13] [16] [17] [19] [50] [53] [57] [58] [65] as what the herbal treatment of PV affects most.

Other molecular pathways identified were:

· Lck-dependent Ca²⁺ signaling pathway and its downstream effectors which finally modulate IL-2 gene expression, relating to T cell activation, and thus to inflammatory response [66].

· MRK/ERK/JNK signaling pathway. This relates to the inhibition of NF-κB and MMP activity, and thus to metastasis [18] [24] [26] [27] [41] [70].

· PI3K/AKT signaling pathway [13].

However, the concentration of research efforts in just a few genomic pathways is too limiting, and points to the limitation of these conventional research methodologies. Researchers needed to target and specify the pathway which the research concentrated on. Thus, these traditional methodologies may miss many other possible pathways. This drawback should be remedied by newer technologies such as the use of the NGS sequencing technique.

5. Conclusions

This article reviewed the research efforts in the anti-tumor effect of the herb, PV, in the past 3 decades. Specifically, this article emphasized on the in-vitro methods employed. This article tried to identify the molecular mechanisms which the previous research efforts on the PV herb concentrated on and found to be responsible for the anti-tumoral effect of the herb. Then, we followed the types of assays to explore them. These chiefly pointed to proteomic assays, which are still widely used.

The main issues of cancer investigation by the previous works were cell viability/apoptosis, migration, and anti-oxidative activity. However, most research efforts concentrated on the cell viability. Different assays which investigated the different phenomena that appeared during the apoptosis process were organized and disclosed. This overview provides a good summary and understanding of the methodologies employed.

Appendix

A descriptive table summarizing the articles surveyed in this review.

Conflicts of Interest

The authors declare no conflicts of interest regarding the publication of this paper.

References

[1]	Markova, H., Sousek, J. and Ulrichova, J. (1997) Prunella vulgaris L.—A Rediscovered Medical Plant. Ceská a Slovenská Farmacie, 46, 58-63.
[2]	Kujawska, M., Klepacki, P. and Luczaj, L. (2017) Fischer’s Plants in Folk Beliefs and Customs: A Previously Unknown Contribution to the Ethnobotany of the Polish-Lithuanian-Belarusian Borderland. Journal of Ethnobiology and Ethnomedicine, 13, Article No. 20. https://doi.org/10.1186/s13002-017-0149-8
[3]	Amjad, M.S., Qaeem, M.F., Ahmad, I., Khan, S.U., Chaudhari, S.K., Zahid Malik, N., Shaheen, H. and Khan, A.M. (2017) Descriptive Study of Plant Resources in the Context of the Ethnomedicinal Relevance of Indigenous Flora: A Case Study from Toli Peer National Park, Azad Jammu and Kashmir, Pakistan. PLoS ONE, 12, e0171896. https://doi.org/10.1371/journal.pone.0171896
[4]	Wurtele, E.S., Chappell, J., Jones, A.D., Celiz, M.D., Ransom, N., Hur, M., Rizshsky, L., Crispin, M., Dixon, P., Liu, J., Widrlechner, M.P. and Nikolau, B.J. (2012) Medicinal Plants: A Public Resource for Metabolomics and Hypothesis Development. Metabolites, 2, 1031-1059. https://doi.org/10.3390/metabo2041031
[5]	Huang, M., Wang, Y., Xu, L. and You, M. (2015) Anti-Tumor Properties of Prunella vulgaris. Current Pharmacology Reports, 1, 401-419. https://doi.org/10.1007/s40495-015-0038-6
[6]	Wang, S.J., Wang, X.H., Dai, Y.Y., Ma, M.H., Rahman, K., Nian, H. and Zhang, H. (2019) Prunella vulgaris: A Comprehensive Review of Chemical Constituents, Pharmacological Effects and Clinical Applications. Current Pharmaceutical Design, 25, 359-369. https://doi.org/10.2174/1381612825666190313121608
[7]	Gan, X., Zhong, L., Feng, J., Li, Y., Li, S., Cai, W. and Xu, B. (2021) Network Pharmacology to Explore the Molecular Mechanisms of Prunella vulgaris for Treating Hashimoto’s Thyroiditis. Frontiers in Pharmacology, 12, Article ID: 700896. https://doi.org/10.3389/fphar.2021.700896
[8]	Brady, H.J.M. and Gil-Gomez, G. (1998) Molecules in Focus Bax. The Pro-Apoptotic Bcl-2 Family Member, Bax. The International Journal of Biochemistry and Cell Biology, 30, 647-650. https://doi.org/10.1016/S1357-2725(98)00006-5
[9]	Bagci, E.Z., Vodovotz, Y., Billiar, T.R., Ermentrout, G.B. and Bahar, I. (2006) Bistability in Apoptosis: Roles of Bax, Bcl-2, and Mitochondrial Permeability Transition Pores. Biophysical Journal, 90, 1546-1559.
[10]	Yin, D.T., Lei, M., Xu, J., Li, H., Wang, Y., Liu, Z., Ma, R., Yu, K. and Li, X. (2017) The Chinese Herb Prunella vulgaris Promotes Apoptosis in Human Well-Differentiated Thyroid Carcinoma Cells via the B-Cell Lymphoma-2/Bcl-2-Associated X Protein/Caspase-3 Signaling Pathway. Oncology Letters, 14, 1309-1314. https://doi.org/10.3892/ol.2017.6317
[11]	Tan, J., Qi, H. and Ni, J. (2015) Extracts of Endophytic Fungus xkc-s03 from Prunella vulgaris L. Spica Inhibit Gastric Cancer in Vitro and in Vivo. Oncology Letters, 9, 945-949. https://doi.org/10.3892/ol.2014.2722
[12]	Fu, X.R., Sun, Z.C. and Zhang, M.Z. (2012) Experimental Study of Extract from Prunella vulgaris Inducing B, T Lymphoma Cell Apoptosis. Journal of Chinese Medicinal Materials, 35, 433-438.
[13]	Gao, W., Liang, H., Li, Y., Liu, Y. and Xu, Y. (2019) Root Extract of Prunella vulgaris Inhibits in Vitro and in Vivo Carcinogenesis in MCF-5 Human Breast Carcinoma Cells via Suppression of Angiogenesis, Induction of Apoptosis, Cell Cycle Arrest and Modulation of PI3K/AKT Signalling Pathway. Journal of B.U.ON., 24, 549-554.
[14]	Mcllwain, D.R., Berger, T. and Mak, T.W. (2013) Caspase Functions in Cell Death and Disease. Cold Spring Harbor Perspectives in Biology, 5, Article ID: a008656. https://doi.org/10.1101/cshperspect.a008656
[15]	Shalini, S., Dorstyn, L., Dawar, S. and Kumar, S. (2015) Old, New and Emerging Functions of Caspases. Cell Death and Differentiation, 22, 526-539. https://doi.org/10.1038/cdd.2014.216
[16]	Woo, H.J., Jun, D.Y., Lee, J.Y., Woo, M.H., Yang, C.H. and Kim, Y.H. (2011) Apoptogenic Activity of 2α,3α-Dihydroxyurs-12-Ene-28-Oic Acid from Prunella vulgaris var. lilacina Is Mediated via Mitochondria-Dependent Activation of Caspase Cascade Regulated by Bcl-2 in Human Acute Leukemia Jurkat T Cells. Journal of Ethnopharmacology, 135, 626-635. https://doi.org/10.1016/j.jep.2011.03.067
[17]	Zhao, A.G., Li, T., You, S.F., Zhao, H.L., Gu, Y., Tang, L.D. and Yang, J.K. (2008) Effects of Wei Chang An on Expression of Multiple genes in Human Gastric Cancer Grafted onto Nude Mice. World Journal of Gastroenterology, 14, 693-700.
[18]	Yang, Y., Tantai, J., Sun, Y., Zhong, C. and Li, Z. (2017) Effect of Hyperoside on the Apoptosis of A549 Human Non-Small Cell Lung Cancer Cells and the Underlying Mechanism. Molecular Medicine Reports, 16, 6483-6488. https://doi.org/10.3892/mmr.2017.7453
[19]	Zheng, L., Chen, Y., Lin, W., Zhuang, Q., Chen, X., Xu, W., Liu, X., Peng, J. and Sferra, T.J. (2011) Spica Prunellae Extract Promotes Mitochondrion-Dependent Apoptosis in Human Colon Carcinoma Cell Line. African Journal of Pharmacy and Pharmacology, 5, 327-335. https://doi.org/10.5897/AJPP10.354
[20]	Zhang, M.Z. and Wang, X.Q. (2009) Effects of Extract from Prunella vulgaris Combined with Chemotherapeutic Agents on Proliferation of Lymphoma Cells. Tumor, 29, 961-964.
[21]	Gilmore, T.D. (2006) Introduction to NF-κB: Players, Pathways, Perspectives. Oncogene, 25, 6680-6684. https://doi.org/10.1038/sj.onc.1209954
[22]	Brasier, A.R. (2006) The NF-κB Regulatory Network. Cardiovascular Toxicology, 6, 111-130. https://doi.org/10.1385/CT:6:2:111
[23]	Wu, H., Gao, M., Ha, T., Kelley, J., Young, A. and Breuel, K. (2012) Prunella vulgaris Aqueous Extract Attenuates IL-1β-Induced Apoptosis and NF-κB Activation in INS-1 Cells. Experimental and Therapeutic Medicine, 3, 919-924. https://doi.org/10.3892/etm.2012.524
[24]	Choi, J.H., Han, E.H., Hwang, Y.P., Choi, J.M., Choi, C.Y., Chung, Y.C., Seo, J.K. and Jeong, H.G. (2010) Suppression of PMA-Induced Tumor Cell Invasion and Metastasis by Aqueous Extract Isolated from Prunella vulgaris via the Inhibition of NF-κB-Dependent MMP-9 Expression. Food and Chemical Toxicology, 48, 564-571. https://doi.org/10.1016/j.fct.2009.11.033
[25]	Choi, J.H. and Jeong, H.G. (2009) The Antimetastatic Effects of Aqueous Extract Isolated from Prunella vulgaris by Modulating Expressions of MMP-9. Drug Metabolism Reviews, 2, 43.
[26]	Su, Y.C., Lin, I.H., Siao, Y.M., Liu, C.J. and Yeh, C.C. (2016) Modulation of the Tumor Metastatic Microenvironment and Multiple Signal Pathways by Prunella vulgaris in Human Hepatocellular Carcinoma. American Journal of Chinese Medicine, 44, 835-849. https://doi.org/10.1142/S0192415X16500464
[27]	Cho, I.H., Jang, E.H., Hong, D., Jung, B., Park, M.J. and Kim, J.H. (2015) Suppression of LPS-Induced Epithelial-Mesenchymal Transition by Aqueous Extracts of Prunella vulgaris through Inhibition of the NF-κB/Snail Signaling Pathway and Regulation of EMT-Related Protein Expression. Oncology Reports, 34, 2445-2450. https://doi.org/10.3892/or.2015.4218
[28]	Orton, R.J., Sturm, O.E., Vyshemirsky, V., Calder, M., Gilbert, D.R. and Kolch, W. (2005) Computational Modelling of the Receptor-Tyrosine-Kinase-Activated MAPK Pathway. The Biochemical Journal, 392, 249-261. https://doi.org/10.1042/BJ20050908
[29]	Ip, Y.T. and Davis, R.J. (1998) Signal Transduction by the c-Jun N-Terminal Kinase (JNK)—From Inflammation to Development. Current Opinion in Cell Biology, 10, 205-219. https://doi.org/10.1016/S0955-0674(98)80143-9
[30]	Verma, R.P. and Hansch, C. (2007) Matrix Metalloproteinases (MMPs): Chemical-Biological Functions and (Q)SARs. Bioorganic & Medicinal Chemistry, 15, 2223-2268. https://doi.org/10.1016/j.bmc.2007.01.011
[31]	Hessing, B., Hattori, K., Friedrich, M., Rafii, S. and Werb, Z. (2003) Angiogenesis: Vascular Remodeling of the Extracellular Matrix Involves Metalloproteinases. Current Opinion in Hematology, 10, 136-141. https://doi.org/10.1097/00062752-200303000-00007
[32]	Kim, S.H., Huang, C.Y., Tsai, C.Y., Lu, S.Y., Chiu, C.C. and Fang, K. (2012) The Aqueous Extract of Prunella vulgaris Suppresses Cell Invasion and Migration in Human Liver Cancer Cells by Attenuating Matrix Metalloproteinases. American Journal of Chinese Medicine, 40, 643-656. https://doi.org/10.1142/S0192415X12500486
[33]	Aaronson, S.A. (1991) Growth Factors and Cancer. Science, 254, 1146-1153. https://doi.org/10.1126/science.1659742
[34]	Karkkainen, M.J. and Petrova, T.V. (2000) Vascular Endothelial Growth Factor Receptors in the Regulation of Angiogenesis and Lymphangiogenesis. Oncogene, 19, 5598-5605. https://doi.org/10.1038/sj.onc.1203855
[35]	Florkiewicz, R.Z., Shibata, F., Barankiewicz, T., Baird, A., Gonzalez, A.M., Florkiewicz, E. and Shah, N. (1991) Basic Fibroblast Growth Factor Gene Expression. Annals of the New York Academy of Sciences, 638, 109-126. https://doi.org/10.1111/j.1749-6632.1991.tb49022.x
[36]	Hao, J., Ding, X.L., Yang, X. and Wu, X.Z. (2016) Prunella vulgaris Polysaccharide Inhibits Growth and Migration of Breast Carcinoma-Associated Fibroblasts by Suppressing Expression of Basic Fibroblast Growth Factor. Chinese Journal of Integrative Medicine, 26, 270-276. https://doi.org/10.1007/s11655-016-2587-x
[37]	Lin, W., Zheng, L., Zhao, J., Zhuang, Q., Hong, Z., Xu, W., Chen, Y., Sferra, T.J. and Peng, J. (2011) Anti-Angiogenic Effect of Spica prunellae Extract in Vivo and in Vitro. African Journal of Pharmacy and Pharmacology, 5, 2647-2654. https://doi.org/10.5897/AJPP11.266
[38]	Wang, Y., Cao, R., Zhu, C. and Wu, X. (2014) Effect and Mechanism of Prunella vulgaris Sulfated Polysaccharide on Angiogenesis in Hepatocellular carcinoma. Chinese Journal of Clinical Oncology, 41, 758-761.
[39]	Wu, X.Z., Zhang, S.X., Zhu, C. and Chen, D. (2011) Effects of Sulfated Polysaccharide Extracted from Prunella vulgaris on Endothelial Cells. Journal of Medicinal Plants Research, 5, 4218-4223.
[40]	Wang, Y., Yao, R., Gao, S., Wen, W., Du, Y., Szabo, E., Hu, M., Lubet, R.A. and You, M. (2013) Chemopreventive Effect of a Mixture of Chinese Herbs (Antitumor B) on Chemically Induced Oral Carcinogenesis. Molecular Carcinogenesis, 52, 49-56. https://doi.org/10.1002/mc.20877
[41]	Xu, Y., Jiang, Z., Ji, G. and Liu, J. (2010) Inhibition of Bone Metastasis from Breast Carcinoma by Rosmarinic Acid. Planta Medica, 76, 956-962. https://doi.org/10.1055/s-0029-1240893
[42]	Mossmann, T. (1983) Rapid Colorimetric Assay for Cellular Growth and Survival: Application to Proliferation and Cytotoxicity Assays. Journal of Immunological Methods, 65, 55-63. https://doi.org/10.1016/0022-1759(83)90303-4
[43]	Stockert, J.C., Horobin, R.W., Blazquex-Castro, A. and Colombo, L.L. (2018) Tetrazolium Salts and Formazan Products in Cell Biology: Viability Assessment, Fluorescence Imaging, and Labeling Perspectives. Acta Histochemica, 120, 159-167. https://doi.org/10.1016/j.acthis.2018.02.005
[44]	U.S. National Library of Medicine (2018) Lactate Dehydrogenase Test: MedlinePlus Medical Encyclopedia. MedlinePlus.
[45]	Vermes, I., Haanen, C., Steffens-Nakken, H. and Reutellingsperger, C. (1995) A Novel Assay for Apoptosis Flow cytometric Detection of Phosphatidylserine Expression on Early Apoptotic Cells Using Fluorescein Labelled Annexin V. Journal of Immunological Methods, 184, 39-51. https://doi.org/10.1016/0022-1759(95)00072-I
[46]	Lee, I.K., Kim, D.H., Lee, S.Y., Kim, K.R., Choi, S.U., Hong, J.K., Lee, J.H., Park, Y.H. and Lee, K.R. (2008) Triterpenoic Acids of Prunella vulgaris var. lilacina and Their Cytotoxic Activities in Vitro. Archives of Pharmacal Research, 31, 1578-1583. https://doi.org/10.1007/s12272-001-2154-6
[47]	Lee, K.H., Lin, Y.M., Wu, T.S., Zhang, D.C., Yamagishi, T., Hayashi, T., Hall, I.H., Chang, J.J., Wu, R.Y. and Yang, T.H. (1988) The Cytotoxic Principles of Prunella vulgaris, Psychotria serpens, and Hyptis capitata: Ursolic Acid and Related Derivatives. Planta Medica, 54, 308-311. https://doi.org/10.1055/s-2006-962441
[48]	Gu, X.J., Li, Y.B., Li, P., Qian, S.H. and Zhang, J.F. (2007) Triterpenoid Saponins from the Spikes of Prunella vulgaris. Helvetica Chimica Acta, 90, 72-78. https://doi.org/10.1002/hlca.200790023
[49]	Johnbeck, C.B., Jensen, M.M., Guan, X., Wang, W., Yi, Z., Zhou, R. and Kjaer, A. (2012) Prunella vulgaris Does Not Show Effect on CT Tumorvolume or FLT Uptake in Human Neuroendocrine Xenograft Tumors in Mice. Molecular Imaging and Biology, 14, S326.
[50]	Feng, L., Au-Yeung, W., Xu, Y.H., Wang, S.S., Zhu, Q. and Xiang, P. (2011) Oleanolic Acid from Prunella vulgaris L. Induces SPC-A-1 Cell Line Apoptosis Via Regulation of Bax, Bad and Bcl-2 Expression. Asian Pacific Journal of Cancer Prevention, 12, 403-408.
[51]	Zhao, X., Zhao, J., Hu, R., Yao, Q., Zhang, G., Shen, H., Yague, E. and Hu, Y. (2017) Ruanjian Sanjie Decoction Exhibits Antitumor Activity by Inducing Cell Apoptosis in Breast Cancer. Oncology Letters, 13, 3071-3079. https://doi.org/10.3892/ol.2017.5832
[52]	Yao, Z.H., Zhang, M.Z., Wang, L.X. and Zhao, P.R. (2006) Influence of the Extract of Prunella vulgaris L. on in Situ Apoptosis of Mouse T lymphocyte EL-4. Chinese Journal of Clinical Rehabilitation, 10, 126-128.
[53]	Zhang, K.J., Zhang, M.Z., Wang, Q.D. and Liu, W.L. (2006) The Experimental Research about the Effect of Prunella vulgaris L. on Raji Cells Growth and Expression of Apoptosis Related Protein. Journal of Chinese medicinal materials, 29, 1207-1210.
[54]	Maimon, Y., Karaush, V., Yaal-Hahoshen, N., Ben-Yosef, R., Ron, I., Vexler, A. and Lev-Ari, S. (2010) Effect of Chinese Herbal Therapy on Breast Cancer Adenocarcinoma Cell Lines. Journal of International Medical Research, 38, 2033-2039. https://doi.org/10.1177/147323001003800617
[55]	Yan, Q.Z., Zhang, K.Q., Li, Q., Xia, B.H., Fu, R.G., Wu, P., Lin, Y., Lin, L.M. and Liao, D.F. (2018) Screening of the Appropriate Proportion on Anti-Breast Cancer Activity of Prunellae spica Combined with Taraxaci herba and Its Anti-Tumor Research in Vivo. Chinese Pharmaceutical Journal, 53, 776-782.
[56]	Feng, L., Jia, X.B., Shi, F. and Chen, Y. (2010) Identification of Two Polysaccharides from Prunella vulgaris L. and Evaluation on Their Anti-Lung Adenocarcinoma Activity. Molecules, 15, 5093-5103. https://doi.org/10.3390/molecules15085093
[57]	Chen, C., Wu, G. and Zhang, M. (2009) The Effects and Mechanism of Action of Prunella vulgaris l Extract on Jurkat Human T Lymphoma Cell Proliferation. Chinese-German Journal of Clinical Oncology, 8, 426-429. https://doi.org/10.1007/s10330-009-0067-x
[58]	Zhang, L.L., Li, H.Q., Ma, R.S., Yu, F.Q., Liu, C.G., Lei, M.Y. and Yin, D.T. (2019) The Pro-Apoptotic Effect and Mechanism of Prunella vulgaris Extracts on Thyroid Cancer Cell Line B-CPAP. Journal of Xi’an Jiaotong University (Medical Sciences), 40, 486-490.
[59]	Yan, Y., Nan, H., Wang, G., Yang, W. and Xu, J. (2013) Comparative Determination of the Volatile Components of Prunella vulgaris L. from Different Geographical Origins by Headspace Solid-Phase Microextraction and Gas Chromatograph-Mass Spectrometry. Analytical Letters, 46, 2001-2016. https://doi.org/10.1080/00032719.2013.782551
[60]	Chen, Y., Guo, Q., Wang, C., Ma, C., Liu, T. and Sun, W. (2009) Genetic Variation, Correlation and Principle Component Analysis on Morphological Characteristics of Various Germplasm from Prunella vulgaris. China Journal of Chinese Materia Medica, 34, 1886-1889.
[61]	Rasool, R., Ganai, B.A., Akbar, S., Kamili, A.N. and Masood, A. (2010). Phytochemical Screening of Prunella vulgaris L.—An Important Medicinal Plant of Kashmir. Pakistan Journal of Pharmaceutical Sciences, 23, 399-402.
[62]	Chen, Y., Guo, Q., Zhu, Z. and Zhang, L. (2012) Changes in Bioactive Components Related to the Harvest Time from the Spicas of Prunella vulgaris. Pharmaceutical Biology, 50, 1118-1122. https://doi.org/10.3109/13880209.2012.658477
[63]	Guo, Q., Zhou, L., Gong, W. and Wu, X. (2010) Effect of Different Water Treatments on Quality and Yield of Spadix in Prunella vulgaris. China Journal of Chinese Materia Medica, 35, 1795-1798.
[64]	Feng, L., Jia, X., Zhu, M., Chen, Y. and Shi, F. (2010) Chemoprevention by Prunella vulgaris L. Extract of Non-Small Cell Lung Cancer via Promoting Apoptosis and Regulating the Cell Cycle. Asian Pacific Journal of Cancer Prevention, 11, 1355-1358.
[65]	Fang, Y., Zhang, L., Feng, J.Y., Lin, W., Cai, Q.Y. and Peng, J. (2017) Spica prunellae Extract Suppresses the Growth of Human Colon Carcinoma Cells by Targeting Multiple Oncogenes via Activating miR-34a. Oncology Reports, 38, 1895-1901. https://doi.org/10.3892/or.2017.5792
[66]	Ahn, S.C., Oh, W.K., Kim, B.Y., Kang, D.O., Kim, M.S., Heo, G.Y. and Ahn, J.S. (2003) Inhibitory Effects of Rosmarinic Acid on Lck SH2 Domain Binding to a Synthetic Phosphopeptide. Planta Medica, 69, 642-646. https://doi.org/10.1055/s-2003-41111
[67]	Phillips, B.B., Shaw, R.F., Holland, M.J., Fry, E.L., Bardgett, R.D., Bullock, J.M. and Osborne, J.L. (2018) Drought Reduces Floral Resources for Pollinators. Global Change Biology, 24, 3226-3235. https://doi.org/10.1111/gcb.14130
[68]	Chen, Y., Zhang, X., Guo, Q., Liu, L., Li, C., Cao, L., Qin, Q., Zhao, M. and Wang, W. (2018) Effects of UV-B Radiation on the Content of Bioactive Components and the Antioxidant Activity of Prunella vulgaris L. Spica during Development. Molecules, 23, Article No. 989. https://doi.org/10.3390/molecules23050989
[69]	Kuriya, S., Hattori, M., Nagano, Y. and Itino, T. (2015) Altitudinal Flower Size Variation Correlates with Local Pollinator Size in a Bumblebee-Pollinated Herb, Prunella vulgaris L. (Lamiaceae). Journal of Evolutionary Biology, 28, 1761-1769. https://doi.org/10.1111/jeb.12693
[70]	Xu, Y., Xu, G., Liu, L., Xu, D. and Liu, J. (2010) Anti-Invasion Effect of Rosmarinic Acid via the Extracellular Signal-Regulated Kinase and Oxidation-Reduction Pathway in Ls174-T Cells. Journal of Cellular Biochemistry, 111, 370-379. https://doi.org/10.1002/jcb.22708