An overview on natural farnesyltransferase inhibitors for efficient cancer therapy

Xiaohan Dai; Yingni Sun; Ting Zhang; Yongfei Ming; Gao Hongwei

doi:10.1080/14756366.2020.1732366

. 2020 Apr 20;35(1):1027–1044. doi: 10.1080/14756366.2020.1732366

An overview on natural farnesyltransferase inhibitors for efficient cancer therapy

Xiaohan Dai ^1,^#, Yingni Sun ¹, Ting Zhang ¹, Yongfei Ming ^1,^#, Gao Hongwei ^1,^✉

PMCID: PMC7191900 PMID: 32308053

Abstract

As one of the world’s five terminally ills, tumours can cause important genetic dysfunction. However, some current medicines for tumours usually have strong toxic side effects and are prone to drug resistance. Studies have found that farnesyltransferase inhibitors (FTIs) extracted from natural materials have a good inhibiting ability on tumours with fewer side effects. This article describes several FTIs extracted from natural materials and clarifies the current research progress, which provides a new choice for the treatment of tumours.

Executive summary

Farnesyltransferase (FTase)

When Ras gene is activated, it becomes an oncogene with oncogenic activity. Ras protein plays a crucial role in cancer cells. FTase is the first step to activate Ras protein.
FTIs not only have anti-tumour effects, but also makes great contribution to the treatment of plasmodium falciparum, parasitic diseases and progeria.
There are still some problems with FTIs, but natural products FTIs are worthy of further research as a new class of low-toxic, safe and effective anticancer drugs. Summarised natural product-derived FTase inhibitors
This review summarised several FTIs extracted from natural materials and clarifies their anti-tumour activity (IC₅₀ value) and structure, providing a reference for further research on tumour therapy.

Keywords: Tumour, FTIs, Ras protein, natural materials, inhibitors

1. Introduction

Tumour refers to the local mass formed by abnormal proliferation of local tissue under the action of various tumorigenic factors. It is one of the world’s five terminally ill diseases including motor neuron disease, AIDS, leukaemia, and rheumatoid arthritis. Cancer cells have unique properties of invasion and metastasis. Tumours disrupt cell junctions and cell signalling, leading to important gene dysfunction¹. At present, the main methods for treating tumours are still traditional treatments such as surgical treatment, chemotherapy, and radiation therapy, which usually have strong toxic side effects and are prone to drug resistance. With the development of related disciplines such as molecular biology, research on anti-tumour drugs has also shifted to new anti-tumour drugs targeting multiple links in the mechanism of tumour development. These drugs, for example, targeting cell signalling molecules: including protein tyrosine kinase inhibitors, farnesyltransferase inhibitors (FTIs), mitogen-activated protein kinase (MAPK) signalling pathway inhibitors, cell cycle regulators, etc., are localised to target cell-specific bio-macromolecules, thereby inhibiting the growth and metastasis of tumour cells, rather than killing cells directly. Among them, FTIs are one of the hotspots in recent years, which have attracted the attention of many famous research institutions at home and abroad.

2. Brief introduction to Ras protein and FTIs

The Ras protein mainly regulates the differentiation and proliferation of cells, and is called the “molecular switch” in the transmission of cellular signalling networks. Ras protein is a low molecular weight protein that is distributed inside the cell membrane and has the function of binding to guanine nucleotides, which plays an significant role in cell growth, proliferation, development, differentiation, and cancer cell production². However, if Ras protein is always in an activated state, it will have a continuous stimulating effect on the growth and proliferation of cells, which makes the cells in a state of continuous proliferation or even canceration. Therefore, Ras protein has a very close relationship with tumour generation and development.

As a precursor protein of cytoplasm, Ras protein needs some modifications including prenylation, proteolysis, carboxymethylation, and palmification to exert all biological activities⁹. The prenylation of the Ras protein requires three enzymes in turn: farnesyltransferase (FTase), geranylgeranyl transferase I (GGTaseI), and geranylgeranyl transferase II (GGTaseII). Farnesyltran is the first step in post-translational modification of Ras. Therefore, the search for suitable FTIs is an important research direction to inhibit Ras protein and thus inhibit the occurrence of cancer.

FTIs not only have anti-tumour effects, but also have a great contribution to the treatments of Plasmodium falciparum and parasitic diseases. In recent years, the study of FTIs has a certain breakthrough in the treatment of premature aging and antiviral field¹⁶^,¹⁷. According to the structural analysis and catalytic mechanism of FTase, FTIs can be divided into four types¹⁸: (1) CAAX (C is cysteine, A is an aliphatic amino acid, and X is serine or methionine) tetrapeptides and their analogues; (2) farnesyl phosphonate (FPP) mimetic; (3) double substrate mimetic; (4) natural product. Natural products have been reported as a major source of lead compounds, and a variety of natural products that could inhibit the activity of FTase have been reported¹⁹. This article describes several FTIs extracted from natural materials and clarifies the current research progress (Tables 1–4).

Table 1.

Anticancer active ingredients of natural materials.

Compound no.	Classifications	Source	Components	FTI IC₅₀	References
1	Quinones	Tectona grandis L.	Tecomaquinone I	0.065 µM	Cadelis et al.³
2			Derivative	1.1 µM	Cadelis et al.³
3			Derivative	9.98 µM	Cadelis et al.³
4		Tectona grandis L.	Tectol	2.09 µM	Cadelis et al.³
5			Derivative	4.4 µM	Cadelis et al.³
6			Derivative	1.8 µM	Cadelis et al.³
7		Adocia sp. sponge	Halenaquinone	0.93 µM	Wang et al.⁴
8			Derivative	0.44 µM	Wang et al.⁴
9			Derivative	0.057 µM	Wang et al.⁴
10			Derivative	0.031 µM	Wang et al.⁴
11		Sponges	Xestosaprol C methylacetal	4.34 µM	Cao et al.⁵
12			orhalquinone	0.40 µM	Cao et al.⁵
13			3-Ketoadociaquinone A	4.19 µM	Cao et al.⁵
14			3-Ketoadociaquinone B	9.27 µM	Cao et al.⁵
15		A. camphorata	Antroquinonol	2.986 µM	Ho et al.⁶
16		Streptomyces sp.	UCF 116A	1.2 μM	Hara et al.⁷
17			UCF 116B	0.6 μM	Hara et al.⁷
18			UCF 116C	100 μM	Hara et al.⁷
19		Dichrostachys cinerea	Dichrostachines A	10 µM	Long et al.⁸
20			Dichrostachines B	40 µM	Long et al.⁸
21			Dichrostachines C	5.7 µM	Long et al.⁸
22			Dichrostachines D	86 µM	Long et al.⁸
23			Dichrostachines E	40 µM	Long et al.⁸
24			Dichrostachines G	17 µM	Long et al.⁸
25			Dichrostachines H	1.8 µM	Long et al.⁸
26			Dichrostachines L	3.2 µM	Long et al.⁸
27			Dichrostachines M	3 µM	Long et al.⁸
28			Dichrostachines O	25 µM	Long et al.⁸
29			Dichrostachines P	7 µM	Long et al.⁸
30			Dichrostachines R	37 µM	Long et al.⁸

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Table 2.

Anticancer active ingredients of natural materials.

Compound no.	Classifications	Source	Components	FTI IC₅₀	References
31	Terpenoids	Aplidium conicum	Thiaplidiaquinones A	0.78 µM	Harper et al.¹⁰
32			Thiaplidiaquinones B	1.22 µM	Harper et al.¹⁰
33			Derivative	0.14 µM	Harper et al.¹⁰
34			Derivative	0.054 µM	Harper et al.¹⁰
35			Derivative	17.3 µM	Cadelis et al.¹¹
36			Derivative	14.7 µM	Cadelis et al.¹¹
37			Derivative	22 µM	Cadelis et al.¹¹
38			Derivative	3.1 µM	Cadelis et al.¹¹
39			Derivative	0.17 µM	Cadelis et al.¹¹
40			Derivative	1.5 µM	Cadelis et al.¹¹
41			Derivative	0.45 µM	Cadelis et al.¹¹
42			Derivative	4.7 µM	Cadelis et al.¹¹
43			Derivative	7.3 µM	Cadelis et al.¹¹
44			Derivative	7.3 µM	Cadelis et al.¹¹
45			Derivative	5.8 µM	Cadelis et al.¹¹
46			Derivative	5.8 µM	Cadelis et al.¹¹
47			Derivative	1.7 µM	Cadelis et al.¹¹
48			Derivative	22.3 µM	Cadelis et al.¹¹
49			Derivative	22.3 µM	Cadelis et al.¹¹
50			Derivative	1.0 µM	Cadelis et al.¹¹
51		Penicillium sp. FO-3929	Andrastin A	24.9 μM	Omura et al.¹²
52			Andrastin B	47.1 μM	Omura et al.¹²
53			Andrastin C	13.3 μM	Omura et al.¹²
54		Stachybotrys kampalensis	Kampanol A	7 µM	Singh et al.¹³
55			Kampanol B	13 µM	Singh et al.¹³
56			Kampanol C	560 µM	Singh et al.¹³
57			Derivative	460 µM	Singh et al.¹³
58		Plant essential oils	d-Limonene	5000 µM	Gelb et al.¹⁴
59		Plant essential oils	d-Carvone	5700 µM	Hardcastle et al.¹⁵
60		Plant essential oils	Perillyl alcohol	1000 µM	Gelb et al.¹⁴

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Table 3.

Anticancer active ingredients of natural materials.

Compound no.	Classifications	Source	Components	FTI IC₅₀	References
61	Lactones	Xanthium strumarium L.	8-epi-xanthatin	64 µM	Kim et al.²⁰
62			8-epi-xanthatin epoxide	58 µM	Kim et al.²⁰
63		Unidentified fungus	CP-225917	6 µM	Moorthy et al.²¹
64			CP-263114	20 µM	Moorthy et al.²¹
65		Artemisia sylvatica	Arteminolide	0.36 µM	Lee et al.²²
66			Artanomaloide	22 µM	Lee et al.²³
67			8-Acetylarteminolide	1.8 µM	Lee et al.²³
68			Arteminone	85 µM	Lee et al.²³
69			Arteminone	82 µM	Lee et al.²³
70			Dehydromatricarin	300 µM	Lee et al.²³
71		Artemisia argyi	Arteminolide B	0.76 µM	Lee et al.²⁴
72			Arteminolide C	0.95 µM	Lee et al.²⁴
73			Arteminolide D	1.1 µM	Lee et al.²⁴
74			Artanomaloide A	105 µM	Lee et al.²⁴
75			Artanomaloide C	150 µM	Lee et al.²⁴
76	Polycarboxylic acids	Chaetomella acutiseta	Chaetomellic acids A	0.055 µM	Gibbs et al.²⁵
77			Chaetomellic acids B	0.185 µM	Gibbs et al.²⁵
78			Vinyl acid A	2 µM	Singh et al.²⁶
79			Vinyl acid B	100 µM	Singh et al.²⁶
80			Trans acid A	100 µM	Singh et al.²⁶
81			Trans acid B	100 µM	Singh et al.²⁶
82			Chaetomellic acid C	0.5 µM	Singh et al.²⁶
83			Vinyl acid C	4 µM	Singh et al.²⁶
84			Trans acid C	5 µM	Singh et al.²⁶
85			Chaetomellic acid D	0.25 µM	Singh et al.²⁶
86			Chaetomellic acid E	0.27 µM	Singh et al.²⁶
87		Amaumarcus niger	Zaragozic acid A	0.25 µM	Dufresne et al.²⁷
88			Zaragozic acid B	1 µM	Dufresne et al.²⁷
89			Zaragozic acid C	0.15 µM	Dufresne et al.²⁷
90			Zaragozic acid D	0.1 µM	Dufresne et al.²⁷
91			Zaragozic acid D₂	0.1 µM	Dufresne et al.²⁷
92		Mollisia sp.	Zaragozic acid D₃	0.6 µM	Tanimoto et al.²⁸
93			Zaragozic acid D₃ 8-methylester	3.7 µM	Tanimoto et al.²⁸
94		Actinoplanes sp.	Actinoplanic acid A	0.23 µM	Singh et al.²⁹
95			Actinoplanic acid B	0.05 µM	Singh et al.³⁰

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Table 4.

Anticancer active ingredients of natural materials.

Compound no.	Classifications	Source	Components	FTI IC50	References
96	Phenolics	Streptomyces sp.	Pepticinnamin E	42 µM	Hinterding et al.³⁴
97			Derivative	67 µM	Thutewohl et al.³⁵
98		Fusidium griseum	fusidienol	2.7 µM	Singh et al.³⁶
99		Phoma sp.	fusidienol A	1.8 µM	Singh et al.³⁷
100		Phoma sp.	Barceloneic acid A	40 μM	Jayasuriya³⁸
101		Preussia isomera and Harmonema dematioides	Preussomerin G	1.2 µM	Singh et al.³⁹
102			Preussomerin H	12 µM	Singh et al.³⁹
103			Preussomerin I	17 µM	Singh et al.³⁹
104			Preussomerin D	1.2 µM	Singh et al.³⁹
105			Deoxypreussomerin A	10 µM	Singh et al.³⁹
106			Deoxypreussomerin B	12 µM	Singh et al.³⁹
107		Aspergillus, Trichoderma, and Penicillium	Gliotoxin	1.1 µM	Van der Pyl et al.⁴⁰
108		Cylidrocarpon lucidum	Cylindrol A	2.2 µM	Singh et al.⁴¹
109		Paecilomyces sp. FO-3684	Kurasoin A	59 µM	Uchida et al.⁴²

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3. Natural products FTIs

3.1. Quinones

Quinones are a class of chemical constituents with a quinoid structure, which are mainly classified into four types: benzoquinone, naphthoquinone, phenanthrenequinone, and anthraquinone. This article summarises the inhibition of FTase by natural products and their derivatives isolated from Tectona grandis L., sponges, A. camphorata, Streptomyces sp., and Dichrostachys cinerea, with IC₅₀ values ranging from 0.031 μM to 100 μM. It is found that phenanthraquinone compounds extracted from Adocia sp. Sponge have a better inhibitory effect on FTase, especially compounds 9 and 10, for their similarity FPP. There are many types and a large number of anthraquinones, including compounds 1 to 6, 11 to 14 (Figures 1 and 2).

Figure 1. — Chemical structures of quinones extracts from (a) *Tectona grandis* L. and their derivatives (**1–6**); (b) sponges and their derivatives (**7–14**).

Figure 2. — Chemical structures of quinones extracts from (a) *A. camphorata* (15); (b) *Streptomyces* sp. (**16–18**); (c) *Dichrostachys cinerea* (**19–30**).

3.1.1. Tectona grandis L

Tectona grandis L. belongs to the Lamiaceae family, which is native to Myanmar, Thailand, India, Indonesia, Laos, etc. Currently, it is widely introduced into Yunnan, Guangdong, Guangxi, Fujian, and Taiwan³¹. It plays an important role in pharmacological effects such as antibacterial, anti-arthritic, anti-oxidant, and wound healing³²^,³³ (Table 4).

Tecomaquinone I was originally extracted from Tectona grandis L. by Romanis⁴³. It is not only inhibited human and T. brucei FTase (IC₅₀ = 0.065 and 0.112 μM), but also exhibited moderate activity inhibition against Plasmodium falciparum (IC₅₀ = 3.44 ± 0.20 μM). Cadelis et al.³ synthesised and analysed a series of derivatives of tecomaquinone I. They found that derivative 2 showed good inhibitory activity against human and T. brucei FTase (IC₅₀ = 1.1 and 2.7 μM), but the inhibitory activity of derivative 3 with the longer side chain added at the same position was significantly reduced.

Sandermann and Dietrichs⁴⁴ found a new natural product from Tectona grandis L., tectol (4). Tectol showed moderate inhibition against FTase (IC₅₀ = 2.09 μM)³. Cadelis et al.³ synthesised and analysed the derivatives of tectol. They found, as opposed to tecomaquinone I, the derivative with longer side chain (6) has stronger inhibitory activity (IC₅₀ = 1.8 μM). They believed that tecomaquinone I can be used as a novel scaffold to develop more effective FTIs³.

3.1.2. Sponge

Sponge belongs to Porifera and is distributed in the ocean, lakes and streams. Terpenoids and terpenoids extracted from sponges play an important role in combating malaria, anti-inflammatory, antibacterial, antiviral⁴⁵.

Schmitz and Bloor⁴⁶ isolated halenaquinone (7) from Adocia sp. sponge, synthesised the corresponding derivatives on the basis of them, and detected that these inhibitors have certain cytotoxicity. Cao et al.⁵ isolated many halenaquinone-type polyketides from marine sponges of the genus Xestospongia by bioassay directed fractionation techniques. Wang et al.⁴ synthesised some derivatives of halenaquinone, evaluated a series of biological targets including FTase, and determined that halenaquinone and derivative 8, 9, and 10 have FTase, phospholipase A2 and Plasmodium falciparum inhibition. Among them, compound 10 has the strongest inhibitory effect on FTase (IC₅₀ = 0.031 μM).

Cao et al.⁵^,⁴⁷^,⁴⁸ further isolated the sponges and found two compounds that inhibited FTase, xestosaprol C methylacetal (11), and orhalquinone (12). Compound 11 possess significant inhibitory activity against human FTase in µM range (IC₅₀ = 4.34 µM). Compound 12 showed inhibitory activity against human and yeast FTase (IC₅₀ = 0.40 μM), with a stronger inhibitory effect than xestosaprol C methylacetal. At the same time, Orhalquinone is a moderate growth inhibitor of P. falciparum⁴⁸. Besides, Cao et al.⁵ also found that 3-ketoadociaquinone A (13) and 3-ketoadociaquinone B (14) have inhibitory effects on FTase (IC₅₀ = 4.19 and 9.27 µM) and GGTase (IC₅₀ = 1.08 and 3.89 µM).

3.1.3. Antrodia camphorata

Antrodia camphorata belongs to Taiwanofungus and grows on the inner wall of the decaying heartwood of Taiwan’s Cinnamomum kanehirae, with the effect of lowering cholesterol, anti-cancer, anti-Alzheimer’s disease^49–51.

Wu et al.⁵² extracted antroquinonol (15), a novel compound with anti-inflammatory activities, from the mycelium of Antrodia camphorata⁵³^,⁵⁴. Ho et al.⁶ measured the inhibitory effect of Antroquinonol on various of tumours such as human lung cancer, liver cancer, and leukaemia. Antroquinonol plays a major role in interrupting the function of Ras and Ras-related GTP-binding proteins by inhibiting the activity of FTase and GGTase in cancer cells, ultimately resulting in cell death. At present, antroquinonol is in the phase 2 clinical trials in patients with non-small cell lung cancer⁶^,⁵⁵^,⁵⁶.

3.1.4. Streptomyces sp

Streptomyces sp. belongs to Actinomyces and is widely found in soil. It exhibits a wide range of anti-microbial, anti-parasitic, and anti-oxidant activities and it is an important species for the study of antibiotics⁵⁷^,⁵⁸.

Hara et al.⁷ isolated UCF 116 compounds from Streptomyces sp. Among these compounds, UCF 116A (16) and UCF 116B (17) have a strong inhibitory effect against bovine brain FTase (IC₅₀ = 1.2 and 0.6 μM), whereas UCF 116C (18) has a weaker inhibitory effect (100 μM)⁵⁹. Compounds 16 and 17 selectively inhibit rabbit reticulocyte lysate FTase (IC₅₀ = 4 μM) and have a weak inhibitory effect on GTase⁶⁰^,⁶¹. The kinetic analysis indicated that UCF 116B is competitive inhibitor of Ras protein, and UCF 116 compounds are all Ras-competitive and non-CAAX mimetic type inhibitors of FTase. It is further concluded that the substituent at the terminal amide linkage of the three compounds, the cyclohexenecarboxylalanine moiety of the compound 17 and the modification of the substituents at the C-11 site all have a non-negligible inhibitory activity against the FTase. More effective FTIs can be found based on these findings.

3.1.5. Dichrostachys cinerea

Dichrostachys cinerea belongs to Leguminosae and is native to Africa and India. The trunk can be used for myogenic, analgesic, hemostasis, dysentery, diarrhoea, etc. The bark can be used to treat intestinal parasites, syphilis, and leprosy⁶²^,⁶³.

Long et al.⁸ extracted a novel compound from Dichrostachys cinerea, which was named dichrostachine A (19). To fully study compound 19, they extracted other secondary metabolites from the roots, stems, and barks of Dichrostachys cinerea, a total of 18 compounds (dichrostachine A-R), all of which belong to the meroterpene derivatives. After determining their structures and synthesising the corresponding derivatives, using sch-66336 as the reference compound, they determined that dichrostachine A(19), B(20), C(21), D(22), E(23), G(24), H(25), L(26), M(27), O(28), P(29), and R(30) have the activity of inhibiting Ftase⁶⁴. Compound 25 has the highest inhibitory activity (IC₅₀ = 1.8 μM). The second is compound 27 (IC₅₀ = 3 μM), while compound 27 has high cytotoxicity.

3.2. Terpenoids

Terpenes take isoprene unit as the basic structural unit, and are mainly classified into monoterpenes, sesquiterpenes, and diterpenes. This article summarises the inhibition of FTase by natural products and their derivatives isolated from Aplidium conicum, Penicillium sp., Stachybotrys kampalensis, and plant essential oils. Most of the natural products and their derivatives extracted from Aplidium conicum have strong FTase inhibitory activity, and the activity varies with the side chain, whereas some monoterpenoids extracted from plant essential oils are weak. Derivatives with side chains of farnesyl group generally have good inhibitory activity. Triterpenoids 51–57 are all derived from mildew, and their activities vary greatly with the groups. Some of the monoterpenoids extracted from plant essential oils contain the least amount of isoprene unit and possess the weakest activity. Although terpenes take isoprene unit as the basic structural unit, they are mostly closed-loop structures, and only groups with chain isoprene groups or similar structures can help to inhibit FTase (Figures 3 and 4).

Figure 3. — Chemical structures of terpenoids extracts from *Aplidium conicum* and their derivatives (**31–42**).

Figure 4. — Chemical structures of terpenoids extracts from (a) *Aplidium conicum* and their derivatives (**43–50**); (b) *Penicillium* sp. (**51–53**); (c) *Stachybotrys kampalensis* and their derivatives (**54–57**); (d) plant essential oils (**58–60**).

3.2.1. Aplidium conicum

Aplidium conicum belongs to Ascidiacea, which is widely distributed in the ocean and has good medical value and edible value. Its extracts can promote apoptosis⁶⁵^,⁶⁶.

Aiello et al.⁶⁷ extracted two marine meroterpenoids, thiaplidiaquinones A (31) and thiaplidiaquinones B (32), which could induce the apoptosis of Jurkat cells, from the ascidian Aplidium conicum. Compound 31 (IC₅₀ = 0.78 and 0.74 μM) and Compound 32 (IC₅₀ = 1.22 and 3.04 μM) have inhibitory effects against both human and T. brucei FTase. Harper et al.¹⁰ obtained the corresponding dioxothiazine isomers (33) and (34). Compounds 31, 33, and 34 were identified to be potent inhibitors of human and T. brucei FTase, and the IC50 values are in the range of nM. Compounds 33 and 34 have moderate inhibitory activity against Plasmodium falciparum, and compound 33 also has moderate antiproliferative activity against melanocyte cell lines. To further investigate the structure–activity relationship of thiaplidiaquinones (31–34), Cadelis et al. synthesised a series of derivatives (35–50), among which 17 derivatives have inhibitory activity against FTase. The test results show that the derivatives with the farnesyl side chain (39–42) have stronger FTase inhibitory activity than the derivatives with the isoprene side chain (35–38)¹¹.

Grayfer et al.⁶⁸ found that the modification of the prenylated side chain of the natural product can regulate biological activity. For example, an increase in the number of prenyl units on the side chain of mallotojaponin B may enhance anti-malarial and FTase inhibitory activity. Whereas studies on tecomaquinone I indicated that this increase leads to a decrease in FTase activity. After synthesis and determination of derivatives of compounds 31 and 32, it was found that this series of compounds have strong or weak inhibitory effects on FTase, and most of the compounds also have moderate antimalarial activity.

3.2.2. Penicillium sp

Penicillium sp. belongs to Trichocomaceae and grows on decaying fruits, vegetables, meat, and various moist organic substances. Its metabolites show excellent antibacterial and anti-inflammatory activities, moreover, good killing effect on larvae such as Culex quinquefasciatus⁶⁹^,⁷⁰.

Shiomi et al.⁷¹ extracted andrastin A (51), andrastin B (52), and andrastin C (53) from Penicillium sp. FO-3929. These three compounds have inhibitory effects on FTase in a dose-dependent manner (IC₅₀ = 24.9, 47.1, and 13.3 μM)¹².

3.2.3. Stachybotrys kampalensis

Stachybotrys kampalensis belongs to chartrum, which is commonly found in soil and can use plants to produce cellulose⁷². Stachybotrys can help the treatment of cancer⁷³.

Singh et al.¹³ isolated kampanol A-C (54–56) from Stachybotrys kampalensis and synthesised a derivative of 56. Compounds 54, 55 are found to have inhibitory activity against human recombinant FPTase by biological activity assay (IC₅₀ = 7 and 13 μM). Nevertheless, 56 and its derivative (57) have weak inhibitory activities (IC₅₀ = 560 and 460 μM). Besides, none of the four compounds have inhibitory activity against GGTase.

3.2.4. Plant essential oils

Plant essential oils are extracted from a variety of plants. Major of them are monoterpenoids. These compounds have antibacterial and insecticidal effects⁷⁴. Several monoterpenoids described here have a certain inhibitory effect on FTase.

Crowell et al.⁷⁵ extracted the monoterpenoid d-limonene (58), one of the end products of the metabolism of mevalonate in plant cells, which is widely found in orange peel and some plant essential oils. Compound 58 is one of the few natural anti-tumour products known to have both chemopreventive and chemotherapeutic effects. Besides, d-limonene is also a very effective chemotherapeutic agent, which can cause 80% complete regression of rat breast cancer induced by chemical factors^76–78. Currently, d-limonene has entered phase I clinical studies in the UK⁷⁹.

Crowell et al.⁸⁰ demonstrated that d-carvone (59), which is a d-limonene analogue, can inhibit cell growth. Hardcastle et al.¹⁵ suggested that compound 59 may be a metabolite of limonene in vivo, a potential FTI (IC₅₀ = 5700 µM).

Perillyl alcohol (60), similar to d-limonene, is a monoterpenoid derived from the essential oils of cherries and other plants. It also has the effect of inhibiting cell growth and weak FTase and GGTase inhibition (IC₅₀ = 1000 and 700 µM)¹⁴^,⁸¹.

3.3. Lactones

Lactone refers to the organic matter produced by dehydration of both carboxyl group and hydroxyl group in the same molecule, which is mainly classified according to the size of the ring. We summarise the inhibition of FTase by natural products and their derivatives isolated from Xanthium strumarium L., unidentified fungus, and Artemisia. In such compounds, the IC₅₀ value of the natural product as a function of side chain groups varies widely. When the groups are the same, the activity of the compounds which are isomers will also vary greatly. For example, the compounds 71, 72 and the compounds 74, 75 are positional isomers, but their activities differ by more than 100-fold (Figure 5).

Figure 5. — Chemical structures of lactones extracts from (a) *Xanthium strumarium* L. (**61–62**); (b) unidentified fungus (**63–64**); (c) *Artemisia* (**65–75**).

3.3.1. Xanthium strumarium L

Xanthium strumarium L. belongs to Compositae and is widely distributed in China. It can be used as raw material for paint, soap, and linoleum. Its fruit extracts have the ability of anti-bacterial, anti-oxidation, anti-diabetes, and preventing arthritis⁸²^,⁸³.

Kim et al.²⁰ extracted two xanthanolide sesquiterpene lactones, 8-epi-xanthatin (61) and 8-epi-xanthatin epoxide (62) from the leaves of Xanthium strumarium L. The concentration of compound 61 required to obtain FTase inhibition is higher than that of compound 62 (IC₅₀ = 64 and 58 μM). The results of in-depth study of compound 61 show that compound 61 can inhibit the growth of T. brucei rhodesiense, T. cruzi, L. donovani, and P. falciparum with IC₅₀ values of 0.33, 11.3, 0.6, and 6.5 μM, respectively. However, the cytotoxicity of compound 61 reached 22.1 μM for rat myoblast cells. In other words, its side effects are great⁸⁴.

Matsuo et al.⁸⁵ separated two milder compounds from Xanthium strumarium L. leaves. Although the inhibitory activities of the two compounds were weaker than that of the compound 61, their side effects were smaller and safer⁸⁶^,⁸⁷.

3.3.2. Unidentified fungus

Dabrah et al.²¹^,⁸⁸^,⁸⁹ found two compounds CP-225917 (63) and CP-263114 (64) from unidentified fungi, which have some characteristics of Phoma sp. The structures of the two compounds were analysed by means of extensive NMR measurements, UV spectra, and FT-IR spectra⁸⁹. It was verified by experiments that both compounds inhibited FTase in the brain of mice (IC₅₀ = 6 and 20 μM).

3.3.3. Artemisia

As Compositae, Artemisia is extremely strong and widely distributed, which is distributed in temperate regions of the northern hemisphere. Artemisia has good medicinal value, can be used to treat malaria and cancer. In addition, Artemisia also has antibacterial and anti-oxidant effects⁹⁰^,⁹¹.

Lee et al.²² isolated a compound from the leaves of Artemisia sylvatica Maxim in 1998. It was determined to be arteminolide (65) by NMR, IR, HREIMS, NOESY spectrum, and mass spectral data. Compound 65 has broad biological activity and selectively inhibits FTase (IC₅₀ = 0.36 μM)^92–94.

Later, Lee et al.²³ isolated five compounds from the methanol extract of Artemisia sylvatica in 2000. After testing and comparing the spectral data with the reported spectral data⁹⁵, it was confirmed that the five compounds were artanomaloide (66), 8-acetylarteminolide (67), arteminone (68 and 69), and dehydromatricarin (70). All the five belong to sesquiterpene lactone. Among them, compounds 68 and 69 are identified as stereoisomers. The inhibitory effects of five compounds on FTase were examined by scintillation proximity assay (SPA). The results show that compound 67 selectively inhibited recombinant rat FTase (IC₅₀ = 1.8 μM) and weaker inhibitory activity against recombinant rat GGTase (IC₅₀ ≫ 100 μM). Compounds 66, 67, 68, and 69 also had some inhibitory effects on FTase (IC₅₀ = 22, 85, 82, and 300 μM). This result is important for studying the pharmacological activities of sesquiterpene lactones. Due to the special structure of 8-acetylarteminolide, Lee et al. speculated that it might be a useful lead compound for the development of anticancer drugs. Subsequent studies show that 8-acetylarteminolide does have an inhibitory effect against tumour cells⁹⁶^,⁹⁷.

Lee et al.²⁴ isolated some compounds from Artemisia argyi and obtained the corresponding chemical structure through experiments in 1998. They renamed the arteminolide (65) as arteminolide A, and the other compounds were named arteminolide B (71), arteminolide C (72), arteminolide D (73), artanomaloide A (74), and artanomaloide C (75). Among them, compounds 74, 75 are regioisomers. In vitro enzyme assays and kinetic experiments revealed that compounds 71–73 have strong inhibitory effect on recombinant human FTase with IC₅₀ values ranging from 1.7 to 1.1 μM. However, the IC₅₀ values of artanomaloides are all over 100 μM. Arteminolides and artanomaloides have almost no inhibitory activity against rat squalene synthase and recombinant rat GGTase.

3.4. Polycarboxylic acids

Polycarboxylic acids are a class of carboxylic acids containing a plurality of carboxyl groups. We summarises the inhibition of FTase by polycarboxylic acids isolated from Chaetomella sp., Amaumarcus niger, Mollisia sp., and Phoma sp. The inhibitions of these natural products are significant. After analysing the activity and structure of each compound, it was found that several polycarboxylic acid compounds in this review had groups similar to FPP and could compete with FPP to inhibit FTase, so almost all these polycarboxylic acids compounds had good inhibitory activity. The side chain groups of polycarboxylic acids have a great influence on the activity. For example, the cis-orientation of dicarboxylic acid and the CH on the alkyl side can make the inhibitory effect more significant, while the cis-diacid composed of shorter alkyl chain can make the compound lose its inhibitory activity (Figures 6 and 7).

Figure 6. — Chemical structures of polycarboxylic acids extracts from (a) *Chaetomella acutiseta* and their derivatives (**76–82**); (b) *Amaumarcus niger* and *Mollisia* sp. (**87–93**).

Figure 7. — Chemical structures of polycarboxylic acids extracts from *Actinoplanes* sp. and their derivatives (**94–95**).

3.4.1. Chaetomella sp

Chaetomella sp. belongs to Sphaeropsidaceae, which uses many plants as its host to survive and has good adaptability to various environment, thus it is distributed all over the world⁹⁸. Chaetomella sp. is an important material for the production of Taxol⁹⁹, which has a certain contribution to the treatment of cancer.

Singh et al.¹⁰⁰ extracted chaetomellic acids A (76) and B (77) from Chaetomella acutiseta and confirm that they can inhibit recombinant human FTase. Subsequently, compounds 76 and 77 were confirmed to have reversible inhibitory abilities against FTase (IC₅₀ = 55 and 185 nM), and selective inhibitory abilities against bovine brain GGTase (IC₅₀ = 92 and 54 μM)²⁵. Lingham et al.¹⁰¹ further verified that compounds 76 and 77, similar to FPP, are reversible inhibitors of FTase. Singh et al.²⁶ synthesised the isomeric diacids (78, 79, 80, 81) of chaetomellic acids A and B, together with C-12 chain compound chaetomellic acid C (82) and its isomers (83, 84). They also found chaetomellic acids D (85) and E (86) from a mycelial broth. These compounds all have strong or weak FTase inhibitory abilities, but no inhibitory activity against GGTase. The results of their work show that the cisoid orientation of the dicarboxylic acid and the alkyl chain of the appropriate length play an important role in the inhibitory activity against FTase. The trans- and vinyl-diacids reduce the inhibitory activity of the compound, and the cis-diacids consisting of a shorter alkyl chain were inactive against FTase.

3.4.2. Amaumarcus niger, Mollisia sp., and Phoma sp

Amaumarcus niger is a keratinophilic fungus which is mostly distributed in the soil. Most of the extracts from Amaumarcus niger have strong activity. Mollisia sp. belongs to the Mollisiaceae and is mainly distributed in warm and humid areas. Although Mollisia sp. causes some diseases, some of its extracts can be used as new antibiotics and have contributed to the field of medicine¹⁰². Phoma sp. is an endophytic fungus widely distributed in the ocean. It has considerable application value. Its isolated products can achieve the effect of treating cancer by inducing apoptosis and autophagy of cancer cells¹⁰³. For example, terpenoids extracted from its culture medium show good antiviral activity¹⁰⁴, and its metabolites can be used to prepare herbicides¹⁰⁵.

Zaragozic acid A (87), B (88), C (89), D (90), and D₂ (91) extracted from keratinophilic fungus Amaumarcus niger belong to tricarboxylic acid. The structure was identified by 2D NMR and mass spectral experiments^106–109. The five compounds all have FTase inhibitory activity, by competing with FPP. Among them, compounds 89, 90, and 91 have the strongest activity (IC₅₀ = 150, 100, and 100 nM), whereas compound 87 and 88 have relatively weak activity (IC₅₀ = 250 and 1000 nM)²⁵^,²⁷. Tanimoto et al.¹¹⁰ extracted zaragozic acid D₃ (92) and zaragozic acid D₃ 8-methylester (93) from the fungus Mollisia sp. Both of the compounds have strong inhibitory activities on FTase and GGTase²⁸. Pedretti et al.¹¹¹ performed a detailed docking analysis of zaragozic acid extracted from Phoma sp. by molecular docking and found that zaragozic acid have strong FTase inhibitory ability by interacting with residues at two FPP binding sites.

3.4.3. Actinoplanes sp

Actinoplanes sp. belongs to Micromonosporaceae, which grows in soil, fresh water, and plant remnants. Its hyphae produce a variety of antibiotics against bacteria and tumours¹¹²^,¹¹³.

Singh et al.²⁹ originally extracted actinoplanic acid A (94) from Actinoplanes sp. and determined its structure. Compound 94 was found to compete with FPP and was also a selective inhibitor of FTase (IC₅₀ = 230 nM). Subsequently, actinoplanic acid B (95) was extracted from Actinoplanes sp., which also exerts selective and competitive inhibition of FTase and has stronger inhibitory activity (IC₅₀ = 50 nM)³⁰^,¹¹⁴. When analysing the structure, we found that compounds 94 and 95 carried more groups similar to FPP, just as Singh et al. found that they could compete with FPP to inhibit FTase, with strong inhibitory activity.

3.5. Phenolics

The phenolic compound refers to a compound having a hydroxyl group on an aromatic hydrocarbon and is classified into monohydric phenol and polyhydric phenol. This review summarises phenolic compounds isolated from several fungi with a small IC₅₀ difference and similar inhibitory abilities against FTase. After observing of the structure and activity of the compounds, it was found that compounds 96 and 97 had more complicated structures than other phenolic compounds and were less effective in inhibiting FTase (Figures 8 and 9).

Figure 8. — Chemical structures of phenolics extracts from (a) *Streptomyces* sp. (**96–97**); (b) *Fusidium griseum* (98); (c) *Phoma* sp. (**99–100**); (d) *Preussia isomera* and *Harmonema dematioides* (**101–106**).

Figure 9. — Chemical structures of phenolics extracts from (e) *Aspergillus*, *Trichoderma*, and *Penicillium* (**107**); (f) *Cylidrocarpon lucidum* (**108**); (g) *Paecilomyces* sp. (**109**).

3.5.1. Streptomyces sp

Streptomyces sp. is the highest Actinomyces and has a good adaptability to the environment. It is of great value to the development of antibiotics and cancer treatment.

Hinterding et al.¹¹⁵ isolated pepticinnamin E (96) from secondary metabolites of Streptomyces sp. It is the first Ras protein substrate competition inhibitor derived from natural products. What is more, subsequent studies show that it is a dual substrate (Ras protein and FPP) competition inhibitor (IC₅₀ = 42 μM)³⁴^,¹¹⁵^,¹¹⁶. Structurally, compound 96 mimics the two substrates of FTase, CAAX, and FPP.

Thutewohl and Waldmann³⁵ synthesised a library of compounds including 51 analogues based on the structure of compound 96 by a change in eight structural parameters. Among them, the seventh derivative (97) has an inhibitory activity similar to that of compound 96 (IC₅₀ = 67 μM).

3.5.2. Fusidium sp

Fusidium sp. belongs to Moniliaceae and has important medical value. The antibiotic fusidic acid extracted from Fusidium sp. has been used for disease treatment since 1962¹¹⁷^,¹¹⁸. Fusidic acid not only has good in vitro antibacterial effect, but also has strong anti-inflammatory effects in vivo¹¹⁹.

Singh et al.³⁶ extracted fusidienol (98) from Fusidium griseum, which inhibited bovine brain FTase and human FTase (IC₅₀ = 0.3 and 2.7 μM).

Fusidienol A (99) is an FTase inhibitor extracted from Phoma sp., which is similar in structure and function to compound 98. Compound 99 has a strong inhibitory activity on recombinant human FTase (IC₅₀ = 1.8 μM) but does not inhibit GGTase well³⁷.

3.5.3. Phuma sp

As an endophytic fungus, Phuma sp. has the effect of treating cancer and antiviral activity.

Jayasuriya et al.³⁸ extracted three natural products from Phuma sp. The structure and activity of these compounds were determined experimentally. Only barceloneic acid A (100) was found to have FTase inhibitory activity (IC₅₀ = 40 μM).

3.5.4. Preussia sp. and Harmonema dematioides

Preussia sp. is a new Chinese strain discovered in 2013 and belongs to endophytic fungi. Its isolates have strong antiplasmodial, antibacterial, and antioxidant activities¹²⁰^,¹²¹. Harmonema dematioides is also an endophytic fungus. It produces secondary metabolites that inhibit the biosynthesis of sterols and thus have a good therapeutic effect on heart disease¹²².

Zink et al.³⁹ studied the structure–activity relationships of preussomerin G (101), H (102), I (103), D (104), deoxypreussomerin A (105) and B (106) extracted from the coprophilous fungus Preussia isomera, and the endophytic fungus Harmonema dematioides^123–125 which are fungal metabolites. They have a certain inhibitory activity on FTase. Among them, compound 101 has the strongest activity, not only against FTase, but also GGTase (IC₅₀ = 1.2 and 20 μM).

3.5.5. Aspergillus, Trichoderma, and Penicillium

Aspergillus belongs to Aspergillaceae and is widely distributed in nature. Although it causes food spoilage and is extremely toxic, it has a key role in food fermentation. Aspergillus also has a positive contribution to antibacterial effects¹²⁶. Trichoderma belongs to Hypocreaceae and is mainly distributed in rot, seeds, plant residues, organic fertilisers, soil, and air. Trichoderma has good medicinal value. For example, it can be used to produce cellulase¹²⁷, producing antibiotics, and so on¹²⁸. Living on saprophytic life, Penicillium sp. can cause food to rot, but it also has certain antibacterial and anti-inflammatory effects.

Shah et al.⁴⁰^,¹²⁹ extracted gliotoxin (107) from Aspergillus, Trichoderma, and Penicillium, which is a sulphur-containing mycotoxin. Compound 107 has modest FTase inhibitory activity (IC₅₀ = 1.1 μM).

3.5.6. Cylidrocarpon lucidum

Cylidrocarpon lucidum is a fungus with excellent medicinal value. Its metabolites can form cyclosporin for treating rheumatoid arthritis¹³⁰.

Singh et al.⁴¹ extracted cylindrol A (108) from Cylidrocarpon lucidum, which is a bicyclic resorcinaldehyde cyclohexanone propionate derivative. It could inhibit bovine FTase (IC₅₀ = 2.2 μM).

3.5.7. Paecilomyces sp

Paecilomyces sp. belongs to Discellaceae, and its research is still not very thorough. It is a group of fungi that are only found in asexual or sexual stages. Its extracts have a considerable effect on antileishmanial and enhanced immunity¹³¹^,¹³².

Uchida et al.⁴² extracted kurasoin A (109) from a cultured broth of Paecilomyces sp. FO-3684, and determined the structure of this compound for the first time. It was found to have a dose-dependent inhibition against FTase (IC₅₀ = 59 μM).

4. Future perspective

So far, many compounds with FTase inhibitory activity have been discovered and synthesised. What is more, many of them are now in the clinical trials. Oral FTIs developed in recent years have high bioavailability and selective antitumor activity in vivo, and their potential effects may eventually be used to treat malignant tumours in humans. FTIs have also made significant achievements in the treatment of diseases such as premature aging and leukaemia^133–135.

It is worth noting that half of the compounds listed here with IC₅₀ values less than 1 μM are from belong to polycarboxylic acid compounds. The importance of polycarboxylic acid compounds in the inhibition of FTase activity was demonstrated. The structural similarity of these polycarboxylic acid compounds to FPP may be the main reason for their effective FTase inhibitory activity. In this review, compounds containing chain groups are similar to FPP, which can compete with FPP to inhibit FTase. However, FPP is also substrate of other enzymes, FPP-competitive inhibitors may inhibit the physiological function of them, causing some harm to the human body. As far as the current results concerned, natural products FTIs are worthy of further research as a new class of low toxicity, safe, and effective anticancer drugs. Apart from further structural modifications based on the existing structural types to enhance the selectivity and in vivo activity of FTIs, a rich library of natural compounds is also worthy of attention. In recent years, many FTIs of novel structures have been found in natural products. It is expected that FTIs will be a promising field of research for new anticancer drugs, and will provide more new options for the clinical treatment of malignant tumours.

Funding Statement

This work was financially supported by Natural Science Foundation of Shandong, China [Grant No. ZR2019MC004]. This work was also financially supported by the high-end talent team construction foundation [Grant No. 108-10000318].

Disclosure statement

No potential conflict of interest was reported by the author(s).

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PERMALINK

An overview on natural farnesyltransferase inhibitors for efficient cancer therapy

Xiaohan Dai

Yingni Sun

Ting Zhang

Yongfei Ming

Gao Hongwei

Abstract

1. Introduction

2. Brief introduction to Ras protein and FTIs

Table 1.

Table 2.

Table 3.

Table 4.

3. Natural products FTIs

3.1. Quinones

Figure 1.

Figure 2.

3.1.1. Tectona grandis L

3.1.2. Sponge

3.1.3. Antrodia camphorata

3.1.4. Streptomyces sp

3.1.5. Dichrostachys cinerea

3.2. Terpenoids

Figure 3.

Figure 4.

3.2.1. Aplidium conicum

3.2.2. Penicillium sp

3.2.3. Stachybotrys kampalensis

3.2.4. Plant essential oils

3.3. Lactones

Figure 5.

3.3.1. Xanthium strumarium L

3.3.2. Unidentified fungus

3.3.3. Artemisia

3.4. Polycarboxylic acids

Figure 6.

Figure 7.

3.4.1. Chaetomella sp

3.4.2. Amaumarcus niger, Mollisia sp., and Phoma sp

3.4.3. Actinoplanes sp

3.5. Phenolics

Figure 8.

Figure 9.

3.5.1. Streptomyces sp

3.5.2. Fusidium sp

3.5.3. Phuma sp

3.5.4. Preussia sp. and Harmonema dematioides

3.5.5. Aspergillus, Trichoderma, and Penicillium

3.5.6. Cylidrocarpon lucidum

3.5.7. Paecilomyces sp

4. Future perspective

Funding Statement

Disclosure statement

References

ACTIONS

PERMALINK

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