Natural Nitrogenous Sesquiterpenoids and Their Bioactivity: A Review.

Nitrogenous sesquiterpenoids fromnatural sourcesare rare, so unsurprisingly neither the potentially valuable bioactivity nor thebroad structural diversity of nitrogenous sesquiterpenoids has been reviewed before. This report covers the progressduring the decade from 2010 to February 2020 on the isolation, identification, and bioactivity of 391 nitrogen-containing natural sesquiterpenes from terrestrial plant, marine organisms, and microorganisms. This complete and in-depth reviewshouldbe helpful for discovering and developing new drugs of medicinal valuerelated to natural nitrogenous sesquiterpenoids.

1. Introduction

The natural products commonly termed ‘secondary metabolites’in contrast to ‘primary metabolites’, are produced byorganisms in order to provide an evolutionary benefit [1]. Natural products as a major chemical resource, have played a significantrole over the last 200 years in treating and preventing diseases, and continue to serve as important agents in modern drug discovery due to their characteristic chemical spatial orientation, which enables them tointeract with their natural and other biological targets [1,2,3,4]. Recently, half of new drugs reported were naturally occurring or constructed on the basis of some natural chemical framework [4,5,6].

Sesquiterpenoids are the largest class of natural terpenoids, with a structural diversity that includes thousands of compounds and more than 100 skeletaltypes [7]. Many of them show ‘drug-like’ chemical properties, including alkylating centerreactivity, lipophilicity, and favorable molecular geometry and electronic features, and have attractedconsiderable interest due to their pronounced biological activities [8,9]. Meanwhile, sesquiterpenoids that contain nitrogen bonds constitute a fascinating group with enormousstructural diversity [10]. Interestingly, it is notable that nitrogenous sesquiterpenoids are rare innatural sources, and there are only a few hundred such compounds that contain the element Nknown to be produced bycertain species. Functionally and biologically important to humans, have caught the attention of a number ofscientists, and extensive phytochemical and biologicalinvestigations of nitrogenous sesquiterpenoids from natural sources have been carried out by researchers at the recent ten years [10,11,12].

While the scientific community is generally aware of the rarity of the N bond in natural sequiterpenoids, and there are many reviews providing extensive coverage on sesquiterpenoids [11,12], including the naturally occurring disesquiterpenoids [1,13,14], natural products containing a nitrogen-nitrogen bond [15] or nitrogen-sulfur bond [16], neither the potentially valuable bioactivity nor the broad structural diversity of nitrogenous sesquiterpenoids has been systematically reviewed during the past ten years.

In this review, nitrogenous sesquiterpenoids from biological sources, including plants, microorganisms, and marine resources, will be considered. In order to be as comprehensive and clear as possible, the natural nitrogenous sesquiterpenoids have been segregated by structural class and compounds covered in the past decade included where appropriate. This report provides a systematic review of the isolation, structural characterization and biological activities of these compounds since 2010, if known.

2. Species Containing Nitrogenous Sesquite Rpenoids and Their Bioactivities

2.1. Dihydroagarofuran Sesquiterpenoids

Nitrogen-containing dihydroagarofuran sesquiterpenoids feature several ester groups on a highly oxygenated tricyclic scaffold, and their polyesterified macrolide sesquiterpenoid pyridine alkaloids possess a characteristic macrocyclic dilactone skeleton consisting of a dicarboxy licacid moiety, 2-(carboxyalkyl)nicotinic acid, and a polyoxygenated dihydro-β-agarofuran sesquiterpenoid (Figure 1 and Table 1). The hydroxyl groups of the latter are usually esterified by various organicacids including acetic, benzoic, furanoic, nicotinic, and cinnamicacids. The 2-(carboxyalkyl)nicotinic acid moiety originates from evoninic acid, wilfordic acid, hydroxywilfordic acid, ortheir congeners. The number, position, and configuration of these substituents create a largenovel chemical diversity and exhibit abroadrange of biological activities.

Figure 1

Twelve types (A–L) of dihydroagarofuran sesquiterpenoid skeletons.

Table 1

Reported structures ofdihydroagarofuran sesquiterpenoids 1–144.

No	Name	R1	R2	R3	R4	R5	R6	R7	R8	R9	Type	Ref
1	Mekongensine	OAc	OBz	βOAc	βOAc	OAc	OH	βOAc	OAc	H	A	[17]
2	7-epi-Mekongensine	OAc	OBz	αOAc	βOAc	OAc	OH	βOAc	OAc	H	A	[17]
3	1-O-Benzoyl-1-deacetylmekongensine	OBz	OBz	βOAc	βOAc	OAc	OH	βOAc	OAc	H	A	[17]
4	9′-Deacetoxymekongensine	OAc	OBz	βOAc	βOAc	OAc	OH	βOAc	H	H	A	[17]
5	1-O-Benzoyl-1-deacetyl-9′-deacetoxymekongensine	OBz	OBz	βOAc	βOAc	OAc	OH	βOAc	H	H	A	[17]
6	7-epi-Euojaponine A	OBz	OH	αOAc	βOAc	OAc	OH	βOAc	H	CH3	B	[17]
7	2-O-Benzoyl-2-deacetylmayteine	OBz	OAc	βOAc	βOAc	OAc	OH	βOBz	H	CH3	B	[17,24]
8	7-epi-5-O-Benzoyl-5-deacetylperitassine A	OAc	OBz	αOAc	βOAc	OAc	OH	βOAc	H	CH3	C	[17]
9	7-epi-Euonymine	OAc	OAc	αOAc	βOAc	OAc	OH	βOAc	H	CH3	B	[17]
10	Mayteine	OBz	OAc	βOAc	βOAc	OAc	OH	βOAc	H	CH3	B	[17]
11	7-epi-Mayteine	OBz	OAc	αOAc	βOAc	OAc	OH	βOAc	H	CH3	B	[17]
12	Euonymine	OAc	OAc	βOAc	βOAc	OAc	OH	βOAc	H	CH3	B	[17,18,21,26]
13	9′-O-Acetyl-7-deacetoxy-7-oxowilfortrine	OAc	OAc	O	βOAc	OAc	OH	βOFu	OAc	H	A	[18,26]
14	9′-O-Acetylwilfortrine	OAc	OAc	βOAc	βOAc	OAc	OH	βOFu	OAc	H	A	[18]
15	9′-O-Furanoylwilfordine	OAc	OAc	βOAc	βOAc	OAc	OH	βOBz	OFu	H	A	[18]
16	7-O-Benzoyl-5,7-dideacetylwilformine	OAc	OH	βOBz	βOAc	OAc	OH	βOAc	H	H	A	[18]
17	Wilfortrine	OAc	OAc	βOAc	βOAc	OAc	OH	βOFu	OH	H	A	[18,21,26]
18	Wilforgine	OAc	OAc	βOAc	βOAc	OAc	OH	βOFu	H	H	A	[18,23,26]
19	Wilfordine	OAc	OAc	βOAc	βOAc	OAc	OH	βOBz	OH	H	A	[18,26]
20	Wilforine	OAc	OAc	βOAc	βOAc	OAc	OH	βOBz	H	H	A	[18,26]
21	Wilformine	OAc	OAc	βOAc	βOAc	OAc	OH	βOAc	H	H	A	[18]
22	Wilforidine	OAc	OAc	βOAc	βOAc	OAc	OH	βOH	OH	H	A	[18]
23	Cangorinine E-1	OAc	OBz	βOAc	βOAc	OAc	OH	βOAc	H	CH3	B	[18]
24	Ebenifoline E-II	OBz	OBz	βOAc	βOAc	OAc	OH	βOAc	H	CH3	B	[18]
25	Neoeuonymine	OAc	OH	βOAc	βOAc	OAc	OH	βOAc	H	CH3	B	[18,24,26]
26	Peritassine A	OAc	OAc	βOAc	βOAc	OAc	OH	βOAc	H	CH3	C	[18,21,31]
27	Wilfornine G	OAc	OAc	βONic	βOAc	OAc	OH	βOAc	H	CH3	C	[18]
28	Regelidine	OBz	ONic	H	αOBz	H	OH	H	H	H	D	[18,24,28]
29	9-O-trans-Cinnamoyl-9-debenzoylregelidine	OBz	ONic	H	αOtCin	H	OH	H	H	H	D	[18]
30	1β-Acetoxy-8α,9β-dibenzoyloxy-13-nicotinoyloxy-β-dihydroagarofuran	OAc	H	αOBz	βOBz	ONic	H	H	H	H	D	[19]
31	1β,2β-Diacetoxy-9α-benzoyloxy-13-nicotinoyloxy-β-dihydroagarofuran	OAc	H	H	αOBz	ONic	H	βOAc	H	H	D	[19]
32	Hypoglaunine E	OAc	OH	βOAc	βOAc	OFu	OH	βOAc	OH	CH3	C	[20,21,31]
33	Hypoglaunine F	OAc	OH	βOAc	βOAc	OAc	OH	βOFu	OH	CH3	C	[20,31]
34	Triptersinine A	OtCin	OH	O	βONic	OAc	OH	H	H	H	D	[21]
35	Triptersinine B	OcCin	OH	O	βONic	OAc	OH	H	H	H	D	[21]
36	Triptersinine C	βOtCin	OH	βOAc	βONic	OAc	OH	H	H	H	D	[21]
37	Triptersinine D	OcCin	OH	βOAc	βONic	OAc	OH	H	H	H	D	[21]
38	Triptersinine E	OcCin	OAc	βOAc	βONic	OAc	OH	H	H	H	D	[21]
39	Triptersinine F	OAc	ONic	βOAc	βOFu	OAc	OH	H	H	H	D	[21]
40	Triptersinine G	OAc	OAc	βONic	βOFu	OAc	OH	H	H	H	D	[21]
41	Triptersinine H	OFu	OAc	βONic	βOFu	OAc	OH	H	H	H	D	[21]
42	Triptersinine L	OAc	ONic	βOAc	αOTig	OAc	OH	H	H	H	D	[21]
43	Wilfordinine A	OAc	OAc	βOAc	βOAc	OAc	OH	βOH	H	CH3	C	[21,31]
44	Hypoglaunine A	OAc	OAc	βOAc	βOAc	OFu	OH	βOAc	OH	CH3	C	[21,31]
45	Wilfordinine E	OAc	OAc	βOAc	βOAc	OAc	OH	βOAc	H	H	F	[21]
46	Euonine	OAc	OAc	βOAc	βOAc	OAc	OH	βOAc	H	H	A	[21,31]
47	Evonine	OAc	OAc	O	αOAc	OAc	OH	αOAc	H	CH3	G	[22]
48	Neoevonine	OAc	OH	O	αOAc	OAc	OH	αOAc	H	CH3	G	[22]
49	1β,2β,5α,8β,11-Pentaacetoxy-4α-hydroxy-3α-(2-methylbutanoyl)-15-nicotinoyl-7-oxo-dihydroagarofuran	OAc	OAc	O	αOAc	OAc	OH	αOAc	OMeBu	ONic	E	[22]
50	Triptersinine M	OtCin	OAc	βOAc	βONic	OAc	OH	H	H	H	D	[23]
51	Triptersinine N	ONic	OFu	βOAc	βOFu	OAc	OH	H	H	H	D	[23]
52	Triptersinine O	OFu	OFu	βOAc	βONic	OAc	OH	H	H	H	D	[23]
53	Triptersinine P	OTig	OAc	βONic	βONic	OAc	OH	H	H	H	D	[23]
54	Triptersinine Q	OFu	OAc	βONic	βOTig	OAc	OH	H	H	H	D	[23]
55	Triptersinine R	OAc	OAc	βONic	αOFu	OAc	OH	H	H	H	D	[23]
56	Triptersinine S	OAc	OFu	βOAc	βONic	OAc	OH	H	H	H	D	[23]
57	Triptersinine T	OAc	OH	βOAc	βONic	OAc	H	H	H	H	D	[23]
58	Tripterygiumine A	OAc	OAc	-	βOAc	-	OH	βOBz	H	CH3	H	[24]
59	Tripterygiumine B	OAc	OAc	βOBz	βOAc	OAc	OH	βOAc	H	CH3	B	[24]
60	Tripterygiumine C	OAc	OBz	βOAc	βOAc	OAc	OH	βOBz	H	CH3	B	[24]
61	Tripterygiumine D	OH	OBz	βOH	βOH	OH	OH	βOH	H	CH3	B	[24]
62	Tripterygiumine E	OAc	OH	βOAc	βOAc	OAc	OH	βOFu	H	CH3	B	[24]
63	Tripterygiumine F	OAc	OFu	βOAc	βOAc	OAc	OH	βOBz	H	CH3	B	[24]
64	Tripterygiumine G	OAc	OBz	βOAc	βOAc	OAc	OH	βOFu	H	CH3	B	[24]
65	Tripterygiumine H	OH	OAc	βOH	βOH	OH	OH	βOH	H	CH3	B	[24]
66	Tripterygiumine I	OAc	OH	βOAc	βOAc	OAc	OH	βOBz	H	CH3	B	[24]
67	Tripterygiumine J	OAc	OH	βOH	βOAc	OAc	OH	βOAc	H	CH3	B	[24]
68	Tripterygiumine K	OAc	OH	βOAc	βOAc	OBz	OH	βOH	H	CH3	B	[24]
69	Tripterygiumine L	ONic	OH	βOAc	βOAc	OAc	OH	βOAc	H	CH3	B	[24]
70	Hyponine D	OAc	OBz	βOAc	βOAc	OAc	OH	βONic	H	CH3	B	[24]
71	Hexadesacetyleuomynine	OH	OH	βOH	βOH	OH	OH	βOH	H	CH3	B	[24]
72	Euojaponine A	OBz	OH	βOAc	βOAc	OAc	OH	βOAc	H	CH3	B	[24]
73	Hyponine C	OAc	OAc	βOAc	βOAc	OBz	OH	βOAc	H	CH3	B	[24]
74	7-Acetyloxy-O11-benzoyl-O2,11- deacetyl-7- deoxoevonine	OAc	OAc	βOAc	βOAc	OBz	OH	βOH	H	CH3	B	[24]
75	4-Hydroxy-7-epi-chuchuhuanine E-V	OAc	OAc	βOAc	βOAc	OAc	OH	βOH	H	CH3	B	[24,26]
76	Wilfornine F	OAc	OBz	βOAc	βOAc	OAc	OH	βOH	H	CH3	B	[24]
77	Tripterygiumine M	OAc	OH	O	βOAc	OAc	OH	βOBz	H	H	A	[24]
78	Tripterygiumine N	OAc	OH	O	βOAc	OAc	OH	βOBz	OFu	H	A	[24]
79	Tripterygiumine O	OAc	OH	βOAc	βOAc	OAc	OH	βOFu	OBz	H	A	[24]
80	Tripterygiumine P	OH	OAc	βOH	βOH	OH	OH	βOH	OBz	H	A	[24]
81	Tripterygiumine Q	OH	OAc	βOH	βOH	OH	OH	βOH	OFu	H	A	[24]
82	Triptonine B	OAc	OAc	βOAc	βOAc	OAc	OH	βOFu	OFu	H	A	[24]
83	1-Desacetylwilforgine	OH	OAc	βOAc	βOAc	OAc	OH	βOFu	H	H	A	[24]
84	Alatamine	OAc	OAc	O	βOAc	OAc	OH	βOBz	OH	H	A	[24]
85	Alatusinine	OAc	OAc	βOAc	βOAc	OAc	OH	βOAc	OH	H	A	[24]
86	Wilforzine	OAc	OH	βOAc	βOAc	OAc	OH	βOBz	H	H	A	[24]
87	Wilforjine	OAc	OAc	βOAc	βOAc	OAc	OH	βOH	H	H	A	[24,26]
88	Tripterygiumine R	ONic	OH	H	αOBz	H	OH	H	H	H	D	[24]
89	1β,5α,11-Triacetoxy-7β-benzoyl-4α-hydroxy-8β- nicotinoyl-dihydroagarofuran	OAc	OAc	βOBz	αONic	OAc	OH	H	H	H	D	[24]
90	Wilforcidine	OBz	ONic	H	αOtCin	H	OH	H	H	H	D	[24]
91	5α-Benzoyl-4α-hydroxy-1β,8α-dinicotinoyl-dihydroagarofuran	ONic	OBz	H	αONic	H	OH	H	H	H	D	[24]
92	1α,2α,6β,8β,9α,15-Hexacetoxy-4β-hydroxy-3β,13-[2′-(3-carboxybutyl)]nicotinic acid-dicarbolactone-β-di hydroagarofuran	OAc	OAc	βOAc	αOAc	OAc	OH	αOAc	H	H	I	[25]
93	1α,2α,9α,15-Tetracetoxy-4β,6β-dihydroxy-8-oxo,3β,13-[4′-(3-carboxybutyl)]nicotinicacid-dicarbolactone- β-dihydroagarofuran	OAc	OH	O	βOAc	OAc	OH	αOAc	H	H	J	[25]
94	1α,2α,9α,15-Tetracetoxy-4β,6β,8β-trihydroxy-3β,13-[4′-(3-carboxybutyl)]nicotinic acid-dicarbolactone- β-dihydroagarofuran	OAc	OH	βOH	βOAc	OAc	OH	αOAc	H	H	J	[25]
95	1α,2α,8β,9α,15-Pentacetoxy-4β,6β-dihydroxy-3β,13-[4′-(3-carboxybutyl)]nicotinic acid-dicarbolactone-β- dihydroagarofuran	OAc	OH	βOAc	βOAc	OAc	OH	αOAc	H	H	J	[25]
96	Tripterygiumine S	OAc	OAc	O	βOAc	OAc	OH	βOH	OFu	H	A	[26]
97	Tripterygiumine T	OAc	OH	O	βOAc	OAc	OH	βOH	OH	H	A	[26]
98	Tripterygiumine U	OAc	OAc	O	βOAc	OAc	OH	βOH	H	H	A	[26]
99	Tripterygiumine V	OAc	OAc	βOAc	βOAc	OAc	OH	βOH	OBz	H	A	[26]
100	Tripterygiumine W	OFu	OBz	βOAc	βOAc	OAc	OH	βOH	H	CH3	B	[26]
101	Wilfornine A	OAc	OAc	βOAc	βOAc	OAc	OH	βOAc	OBz	H	A	[26]
102	Wilfornine D	OAc	OAc	βOAc	βOAc	OAc	OH	βOAc	OFu	H	A	[26]
103	Tripfordine A	OAc	OAc	βOAc	βOAc	OAc	OH	βOH	OH	H	A	[26]
104	2-Debenzoyl-2-nicotinoylwilforine	OAc	OAc	βOAc	βOAc	OAc	OH	βONic	H	H	A	[26]
105	(+)-(1R,2S,4S,5S,6R,7R,9S,10R)-1,2,15-Triacetoxy-9-benzoyloxy-6-nicotinoyloxydihydro-β-agarofuran	OAc	ONic	H	βOBz	OAc	OH	αOAc	H	H	E	[27]
106	Triptregeline A	ONic	OH	βOAc	αOBz	OAc	OH	αOAc	H	H	E	[28]
107	Triptregeline B	ONic	OAc	αOAc	αOBz	OAc	OH	H	H	H	E	[28]
108	Triptregeline C	ONic	OAc	αOH	αOBz	OH	OH	H	H	H	E	[28]
109	Triptregeline D	OFu	OAc	αONic	αOBz	OAc	OH	H	H	H	E	[28]
110	Triptregeline E	OFu	OH	αONic	αOBz	OAc	OH	H	H	H	E	[28]
111	Triptregeline F	OAc	OH	αONic	αOBz	OAc	OH	H	H	H	E	[28]
112	Triptregeline G	OFu	OH	αONic	αOAc	OAc	OH	H	H	H	E	[28]
113	Triptregeline H	OBz	OAc	αOH	αONic	OAc	OH	H	H	H	E	[28]
114	Triptregeline I	OFu	ONic	H	βOBz	H	OH	βOAc	H	H	E	[28]
115	Triptregeline J	OBz	ONic	H	βOBz	H	OH	H	H	H	E	[28]
116	1α, 6β, 15-Triacetoxy-8α-benzoyloxy-4β-hydroxyl -9α-(3-nicotinoyloxy)-dihydro-β-agarofuran	OAc	OAc	αOBz	αONic	OAc	OH	H	H	H	E	[28]
117	Dimacroregeline A	OH	OAc	H	αOH	-	OH	αOH	H	CH3	K	[29]
118	Dimacroregeline B	OH	OAc	OAc	αOH	-	OH	αOH	H	CH3	K	[29]
119	Triptonine A	OAc	OAc	-	αOAc	-	OH	αOAc	H	CH3	L	[29]
120	4-Deoxyalatamine	OAc	OAc	O	αOAc	OAc	H	αOAc	OH	H	I	[30]
121	1-O-Benzoyl-1-deacetyl-4-deoxyalatamine	OBz	OAc	O	αOAc	OAc	H	αOAc	OH	H	I	[30]
122	1, 2-O-Dibenzoyl-1, 2-deacetyl-4-deoxyalatamine	OBz	OAc	O	αOAc	OAc	H	αOBz	OH	H	I	[30]
123	4-Deoxyisowilfordine	OAc	OAc	βOAc	αOAc	OAc	H	αOBz	OH	H	J	[30]
124	Triptersinine U	OAc	OAc	βOAc	βOAc	OAc	OH	βOAc	αONic	ONic	D	[31]
125	Hypoglaunine B	OAc	OAc	βOAc	βOAc	OFu	OH	βOAc	OH	CH3	C	[31]
126	Triptersinine Z4	OFu	OAc	βOAc	βONic	OAc	H	H	H	H	D	[32]
127	Triptersinine Z5	OAc	OFu	βOAc	βONic	OAc	H	H	H	H	D	[32]
128	Triptersinine Z6	OFu	OFu	βOAc	βONic	OAc	H	H	H	H	D	[32]
129	Triptersinine Z7	OcCin	OAc	βOAc	βONic	OAc	H	H	H	H	D	[32]
130	Triptersinine Z8	OtCin	OAc	βOAc	βONic	OAc	H	H	H	H	D	[32]
131	Euojaponine C	OBz	OBz	βOAc	βOAc	OAc	OH	βOH	H	CH3	B	[32]
132	Triptersinine Z9	OcCin	OFu	βOAc	βONic	OAc	OH	H	H	H	D	[33]
133	Triptersinine Z10	OtCin	OFu	βOAc	βONic	OAc	OH	H	H	H	D	[33]
134	Triptersinine Z11	OtCin	OAc	βONic	βOFu	OAc	OH	H	H	H	D	[33]
135	Triptersinine Z12	OcCin	OAc	βONic	βOFu	OAc	OH	H	H	H	D	[33]
136	Triptersinine Z13	ONic	OFu	βOAc	βOTig	OAc	OH	H	H	H	D	[33]
137	Triptersinine Z14	OAc	OFu	βONic	βOTig	OAc	OH	H	H	H	D	[33]
138	Chinese bittersweet alkaloid A	OAc	OAc	βOAc	βOAc	OiBu	OH	βOH	H	CH3	B	[34]
139	Chinese bittersweet alkaloid B	OAc	OAc	βOAc	βOAc	OiBu	OH	βOAc	H	CH3	B	[34]
140	Monimin I	ONic	ONic	H	αOAc	H	H	H	H	H	E	[35]
141	Monimin II	ONic	ONic	αOH	αOBz	H	H	H	H	H	E	[35]
142	Tripteryford C	ONic	OH	βOAc	αOAc	OAc	H	αOAc	βOH	H	E	[36]
143	Tripteryford E	ONic	OAc	αOH	βOFu	OAc	OH	αOAc	βOH	H	E	[36]
144	Celaspaculin G	OAc	OBz	βOAc	αONic	H	OH	H	H	H	E	[37]

Dihydroagarofuran sesquiterpenoids were considered the most widespread and characteristic metabolites of the plants of the Celastraceae. Compounds 1–12 were isolated from the roots of Maytenus mekongensis [17]. Compounds 1–5 having wilfordic acid moieties, either with or without a 9′-OAc group, exhibited comparable antiplasmodial activities, with IC50 values of 3.1 × 10−3, 3.9 × 10−3, 3.5 × 10−3, 3.1 × 10−3 and 2.5 × 10−3 mM respectively, while compounds 10–12 with evoninic acid moieties showed no inhibitory activity. Compounds 12–29 were extracted from the dried roots of Tripterygium wilfordii [18]. Compound 22 displayed 22.3% inhibitory activity against HSV2 in vitro at 0.5 mg/mL, and acyclovir 66.3% inhibitory activity at 0.5 mg/mL. Compound 28 showed 31.7% inhibitory activity at 0.25 mg/mL, while acyclovir displayed 60.6% inhibitory activity at 0.25 mg/mL. Compounds 30 and 31 were obtained from the fruits of Celastrus orbiculatus Thunb [19]. Hypoglaunines E (32) and F (33) have been purified from the root barks of Tripterygium hypoglaucum and showed no cytotoxic activities against five cancer celllines [20]. Triptersinines A–H, L (compounds 34–42), peritassine A (26), wilfordinine A (43), hypoglaunine A (44), hypoglaunine E (32), wilfordinine E (45), euonine (46), wilfortrine (21), euonymine (12) were extracted from the leaves of Tripterygium wilfordii, and compounds 26, 34, 43, and 46 showed moderate inhibitory effects onnitric oxide production in LPS-induced macrophages at 5 μM [21]. Compounds 47–49 were identified from thestems of Euonymus alatus [22]. Triptersinines M–T (compounds 50–57) and wilforgine (18) have been extracted from the the leaves of Tripterygium wilfordii, and compounds 50, 51, 54, 57, and 18 showed moderate inhibitory abilities on NO production and no influence on cell viability by the MTT method, the other compounds exhibited weak effects [23]. Compounds 7, 25, 58–91 were obtained from the dried roots of Tripterygium wilfordii [24]. Tripterygiumine Q (81) exhibited immunosuppressive activity with an IC50 value of 8.67 μM, and no cytotoxicity was observed even at a dose of 100 μM. Triptonine B (82) not only exhibited immunosuppressive activity with an IC50 value of 4.95 μM, but also showed cytotoxicity with an IC50 value of 26.41 μM. Compounds 92–95 were isolated from the leaves of Maytenus spinosa [25], and the isolates displayed no anti-HIV activity. Tripterygiumines S-W (96–100), wilfornine A (101), wilfornine D (102), tripfordine A (103), 2-debenzoyl-2-nicotinoylwilforine (104) along with 12–13, 18–20, 25, 75, and 87 were purified from the roots of the Tripterygium wilfordii, and found that 13 and 96 possessed potent nitric oxide inhibitory activity with IC50 values ranging from 2.99 to 28.80 μM, without any effect on the cell viability of RAW 264.7 cells [26]. Accordingly, compounds 13 and 96, especially 13, were identified as promising candidates for further scientific investigation of their potential use as anti-inflammatory agents. Compound 105 was obtained from the whole plants of Parnassia wightiana, and showed some cytotoxic activities against NB4, MKN-45 and MCF-7 cells at 20 μM [27]. Triptregelines A-J (106–115), regelidine (28), 1α,6β,15-triacetoxy-8α-benzoyloxy-4β-hydroxyl-9α-(3-nicotinoyloxy)-dihydro-β-agarofuran (116), dimacroregeline A-B (117–118) and triptonine A (119) have been isolated from the stems of Tripterygium regelii, and 107, 108, 113 and 116 exhibited weak cytotoxic effects on taxol-resistant A549T with IC50 values ranged from 29.4 to 54.4 μM [28], 118 showed inhibitory effects on the proliferation of human rheumatoid arthritis synovial fibroblast cell (MH7A) at a concentration of 20 µM [29]. Compounds 120–123 were extracted from the stems of Maytenusoblongata [30]. 1-O-Benzoyl-1-deacetyl-4-deoxyalatamine (121) and 1,2-O-dibenzoyl-1,2-deacetyl-4-deoxyalatamine (122) exhibited strong larvicidal activity on the A. aegypti Paea strain with LD50 values of 9.4 (95% CI: 6.5–10.0) and 2.7 μM (95% CI: 1.9–2.9), respectively. Triptersinine U (124), hypoglaunine B (125) together with 26, 32, 33, 43, 44, and 46 were isolated from the roots of Tripterygium wilfordii, but all dihydroagarofuran derivatives didn’t show cytotoxicity against six human tumor celllines (HepG2, Hep3B, Bcap37, U251, MCF-7 and A549) [31]. Neuroprotective triptersinine Z4–Z14 (126–130, 132–137) and euojaponine C (131) have been obtained from the leaves of Tripterygium wilfordii [32,33], and 126, 127, 129–131 increased cell viability of the okadaic acid-treated PC12 cells from 60.4 ± 23.0% to 72.4 ± 14.1, 71.5 ± 11.5, 75.7 ± 15.6,81.2 ± 13.1, and 86.2 ± 25.5% at 10 μM, respectively [32]. At 10 μmol/L, compounds 132 and 133 showed moderate inhibitory effects on NO production in LPS-induced macrophages with inhibitory rate at 31.2 ± 3.6 and 40.9 ± 4.3 [33]. Two new sesquiterpene pyridine alkaloids, Chinese bittersweet alkaloid A (138) and Chinese bittersweet alkaloid B (139) were isolated from the rootbarks of Celastrus angulatus [34]. Monimins I (140) and II (141) have been extracted from the leaves of Monimopetalum chinense [35]. Tripteryford C (142) and tripteryford E (143) have been obtained from the leaves of Tripterygium wilfordii, and 142 exhibited the better protective activity against human neuroblastoma SH-SY5Y cell injury induced by H2O2 with 76.63% cell viability comparing with the positive control Trolox (69.84%) at 12.5 μM [36]. Celaspaculin G (144) was purified fromthe seeds of Celastrus paniculatus, and with non lifespan-extending effect on the nematode Caenorhabditis elegans [37].

2.2. Drimane and Friedo-Drimane Sesquiterpenoids

Nitrobenzoyl drimane sesquiterpenoids are rare in natural sources, Aspergillus fungi species being the only known sources.6β,9α-Dihydroxy-14-p-nitrobenzoylcinnamolide (145) and insulicolide A (146), insulicolide B (147), 14-O-acetylinsulicolide A (148), insulicolide C (149) and 9-deoxyinsulicolide A (150) (Figure 2) were isolated from extracts of the culture of marine-derived fungus Aspergillus ochraceus Jcma1F17 [38,39]. All of them displayed significant cytotoxicity against 10 human cancer celllines (H1975, U937, K562, BGC-823, Molt-4, MCF-7, A549, Hela, HL60, and Huh-7), with IC50 values ranging from 1.95 mM to 6.35 mM, and 145 also exhibited moderate inhibitory activity against two viruses, H3N2 and EV71, with IC50 values of 17.0 and 9.4 mM, respectively [38]. Compound 146 showed the strongest activities, with IC50 values of 1.5, 1.5, and 0.89 μM, against ACHN, OSRC-2, and 786-O cells, respectively [39]. 148 indicated potent inhibitory activities atlowμM levels, comparable to the positive control, sorafenib, adrug (Nexavar) approved for the treatment of primary kidneycancer (advanced renal cell carcinoma) [39]. Additionally, 145 and 148 exhibited stronger cytotoxicity to 786-O cells (IC50 4.3 and 2.3 μM, respectively) than to OS-RC-2 (IC50 8.2 and 5.3 μM, respectively) and ACHN (IC50 11 and 4.1 μM, respectively) [39]. Purpuride (151), berkedrimane B (152), minioluteumides A–D (153, 154, 156 and 157), purpuride B (155) (Figure 2) featuring with lactones conjugated a N-acetyl-L-valine, and such drimane sesquiterpenoid are rare in nature, which were extracted from the marine fungus, Talaromyces minioluteus (Penicillium minioluteum) [40]. Compounds 152, 153 and 157 exhibited cytotoxic activity with IC50 values of 193.3, 50.6 and 57.0 µM against HepG2 cancer cell line, respectively [40]. A new sesquiterpene lactonepurpuride D (158), berkedrimane A (159), along with 151, 152, 155, 157 (Figure 2) were prepared from a culture of marine-sourced fungus Penicillum ZZ1283 in the medium of potato dextrose broth was found to have antimicrobial activities with MIC values of 4–14 μg/mL against MRSA [41]. Saccharoquinoline (160) (Figure 2) composing of a drimane-type sesquiterpene unit in combination with anapparent 6,7,8-trihydroxyquinoline-2-carboxylic acidwithcytotoxicity against the HCT-116 cancer cell line by inducing G1 arrest, and was obtained from the fermentation broth of the marine-derived bacterium Saccharomonospora sp. CNQ-490 [42].

Figure 2

The structures of compounds 145–160.

Marine sponges are a rich source ofbioactive secondary metabolites, the majority of which are sesquiterpene quinones/hydroquinones, most of which possess either adrimane or a rearranged 4,9-friedodrimane terpenoid skeleton, which contains a C15 sesquiterpene moiety incorporating a C6 benzoquinone or hydroquinone group framework. Drimane sesquiterpene quinones represent a large group of biologically active marine natural products. Six nitrogenous drimane sesquiterpenoid aminoquinones (Figure 3 and Table 2), named 18-aminoarenarone (161), 19-aminoarenarone (162), 18-methylaminoarenarone (163), 19-methylaminoarenarone (164), along with two dimeric popolohuanone F (165), popolohuanone A (166) isolated from the Australian marine sponge Dysidea sp., and 165 and 166 showed DPPH radical scavenging activitywith IC50 values of 35.0 and 35.0 µM, respectively [43]. A new sesquiterpene benzoxazole, nakijinol B (167), its acetylated derivative, nakijinol B diacetate (170), and two newsesquiterpene quinones, smenospongines B (168) and C (169) (Figure 3 and Table 2), were extracted from the methanol extract of the marine sponge Dactylospongia elegans, and were found to have cytotoxic activities in the range of 1.8–46 µM against a panel of human tumor cell lines (SF-268, H460, MCF-7, and HT-29) and a normal mammalian cell line (CHO-K1) [44]. Investigation of the marine sponge Dysideaavara, three bioactive sesquiterpenoid Quinones afforded, (−)-3′-methylaminoavarone (171), (−)-4′-methylaminoavarone (172) and (−)-N-methylmelemeleone-A (173) (Figure 3 and Table 2) with their moderate protein kinase inhibition, cytotoxicity, inhibition of NFkB-activity and insecticidal activity [45]. Two sesquiterpene aminoquinines (Figure 3 and Table 2), smenospongine (174) and glycinylilimaquinone (175), were isolated from the Fijian marine sponge Hippospongia sp., and displayed lethality at LD50 = 188 and <500 ppmagainstbrineshrimp, respectively [46]. Bioactivity-guided isolation yielded fivenew sesquiterpene aminoquinones 5-epi-Nakijiquinone S-N (176–180), two new sesquiterpene benzoxazoles 5-epi-Nakijinol C–D (181 and 182) (Figure 3 and Table 2) isolated from the sponge Dactylospongia metachromia [47]. Compounds 176–180 showed potent cytotoxicity againstthe mouse lymphoma cell line L5178Y with IC50 values ranging from 1.1 to 3.7 μM [47]. When tested in vitro for their inhibitory potential against 16 different protein kinases, compounds 180 and 181 exhibited the strongest inhibitory activity against ALK, FAK, IGF1-R, SRC, VEGF-R2, Aurora-B, MET wt, and NEK6 kinases (IC50 0.97–8.62 μM) [47]. Dysidaminones A-M (183–195) (Figure 3 and Table 2), thirteen new sesquiterpene aminoquinones, along with six known ones (196–201), were isolated from the South China Sea sponge Dysidea fragilis [48]. Compounds 185, 187, 190, and 192, 196, and 198 showed cytotoxicity against mouse B16F10 melanoma and human NCI-H929 myeloma, HepG2 hepatoma, and SK-OV-3 ovarian cancer cell lines [48]. Inaddition, these six cytotoxic compounds also exhibited NF-kB inhibitory activity with IC50 values of 0.05–0.27 mM [48]. Four nitrogenous 4,9-friedodrimane-type sesquiterpenoids (202–205) (Figure 3 and Table 2) were acquired using the oxidative potential of Verongula rigida on bioactive metabolites from two Smenospongia sponges, and the mixture of 204 and 205 suppressed β-cateninresponse transcription (CRT) via degrading β-catenin and exhibited cytotoxic activity on colon cancer cells [49]. Compounds 206–214, together with 174 (Figure 3 and Table 2) have been obtained from the Marine Sponge Spongiapertusa Esper, and 174, 213, 214 exhibited activities against the human cancer cell lines U937, HeLa, and HepG2, with most potent cytotoxicities to U937 cells with IC50 values of1.5, 2.8, and 0.6μM, respectively [50]. Four sesquiterpene hydroquinones, dactylospongins A–D (215–218), as wellas five sesquiterpene quinones, melemeleones B–E (219–222) and dysidaminone N (223) (Figure 3 and Table 2) were isolated from the marine sponge Dactylospongia sp., anti-inflammatory evaluation showed that 215–218, and 223 exhibtited potent inhibitory effects on the production of inflammatory cytokines (IL-6, IL-1β, IL-8, and PEG2) in LPS-induced THP-1 cells with IC50 values of 5.1–9.2 μM [51]. A new sesquiterpenoid aminoquinone nakijiquinone V (224), along with smenospongine (174) (Figure 3 and Table 2) were extracted from an Indonesian marine Dactylospongia elegans sponge [52]. Eleven new nitrogenous meroterpenoids, cinerols A–K (225–235) (Figure 3 and Table 2), were isolated from the marine sponge Dysideacinerea, 225 and 226 feature a rare 5H-pyrrolo[1,2a]-benzimidazole moiety, while cinerols 227–231 were examples of rare meroterpene benzoxazoles [53]. Six sesquiterpene quinones/hydroquinones (236–240, 210) (Figure 3 and Table 2) were acquired from the marine sponge Dactylospongia elegans [54]. Compounds 238–240 showed activities against the human cancer cell lines DU145, SW1990, Huh7, and PANC-1 with IC50 values ranging from 2.33 to 37.85 μM [54]. Three cytotoxic sesquiterpenoid quinones (241–243) (Figure 3 and Table 2) were purified from South ChinaSea sponge Dysidea sp., and displayed various potent cytotoxic activities with IC50 values ranging from 0.93 to 4.61 μM [55]. Two unique nitrogenous sesquiterpene quinone meroterpenoids, dysidinoid B (244) and dysicigyhone A (245) (Figure 3 and Table 2) were characterized from the marine sponge Dysideaseptosa, and 244) exhibited signifcant anti-inflammatory effect by inhibiting TNF-α and IL-6 generation with IC50 values of 9.15 μM and17.62 μM, respectively [56]. Two nitrogenous merosesquiterpene, 5-epi-nakijiquinone L (246) and 5-epi-smenospongiarine (247) (Figure 3 and Table 2) were isolated from the sponge Verongula cf. rigida with weak 5α-reductase inhibitory activity [57].

Figure 3

The friedo-drimane sesquiterpenoidskeletons (I–XXI) and three dimers.

Table 2

Reported structures offriedo-drimane sesquiterpenoids.

No	Name	R1	R2	R3	R4	R5	R6	R7	Type	Ref
161	18-Aminoarenarone	H	NH2	H	αH	αCH3	βCH3	βCH3	I	[43]
162	19-Aminoarenarone	NH2	H	H	αH	αCH3	βCH3	βCH3	I	[43]
163	18-Methylaminoarenarone	H	NHCH3	H	αH	αCH3	βCH3	βCH3	I	[43]
164	19-Methylaminoarenarone	NHCH3	H	H	αH	αCH3	βCH3	βCH3	I	[43]
167	Nkijinol B	OH	OH	H	H	βCH3	βCH3	βCH3	II	[44]
168	Smenospongine B	H	NHCH2COOH	OH	αH	βCH3	βCH3	βCH3	I	[44]
169	Smenospongine C	H	NH(CH2)2COOH	OH	H	βCH3	βCH3	βCH3	II	[44]
170	Nakijinol B diacetate	OAc	OAc	H	αH	βCH3	βCH3	βCH3	I	[44]
171	(−)-3′-Methylaminoavarone	H	NHCH3	H	αH	βCH3	βCH3	βCH3	III	[45]
172	(−)-4′-Methylamino-avarone	NHCH3	H	H	αH	βCH3	βCH3	βCH3	III	[45]
173	(−)-N-Methylmelemeleone-A	H	N(CH3)(CH2)2SO3H	H	αH	βCH3	βCH3	βCH3	III	[45]
174	Smenospongine	H	NH2	OH	αH	βCH3	βCH3	βCH3	IV	[46,50,52]
175	Glycinylilimaquinone	H	NHCH2COOH	OH	αH	βCH3	βCH3	βCH3	IV	[46]
176	5-epi-Nakijiquinone S	H		OH	αH	αCH3	βCH3	βCH3	V	[47]
177	5-epi-Nakijiquinone Q	H		OH	αH	αCH3	βCH3	βCH3	V	[47]
178	5-epi-Nakijiquinone T	H		OH	αH	αCH3	βCH3	βCH3	V	[47]
179	5-epi-Nakijiquinone U	H	NH(CH2)3SCH3	OH	αH	αCH3	βCH3	βCH3	V	[47]
180	5-epi-Nakijiquinone N	H	NH(CH2)2CH(CH3)2	OH	αH	αCH3	βCH3	βCH3	V	[47]
181	5-epi-Nakijinol C	OH	OCH3	CH3	αH	αCH3	βCH3	βCH3	VI	[47]
182	5-epi-Nakijinol D	CH3	CH3	-	αH	αCH3	βCH3	βCH3	VII	[47]
183	Dysidaminone A	NHCH2CH(CH3)2	H	H	αH	βCH3	βCH3	βCH3	III	[48]
184	Dysidaminone B	NHCH2CH(CH3)CH2CH3	H	H	αH	βCH3	βCH3	βCH3	III	[48]
185	Dysidaminone C	H	N(CH3)2	H	αH	βCH3	βCH3	βCH3	III	[48]
186	Dysidaminone D	N(CH3)2	H	H	αH	βCH3	βCH3	βCH3	III	[48]
187	Dysidaminone E	H	NHCH2CH(CH3)2	H	αH	βCH3	βCH3	βCH3	III	[48]
188	Dysidaminone F	H	NHCH2CH(CH3)CH2CH3	H	αH	βCH3	βCH3	βCH3	III	[48]
189	Dysidaminone G		H	H	αH	βCH3	βCH3	βCH3	III	[48]
190	Dysidaminone H	H	NHCH3	H	αH	βCH3	βCH3	βCH3	I	[48]
191	Dysidaminone I	NHCH3	H	H	αH	βCH3	βCH3	βCH3	I	[48]
192	Dysidaminone J	H	N(CH3)2	H	αH	βCH3	βCH3	βCH3	I	[48]
193	Dysidaminone K	NHCH2CH(CH3)2	H	H	αH	βCH3	βCH3	βCH3	I	[48]
194	Dysidaminone L	NHCH2CH(CH3)CH2CH3	H	H	αH	βCH3	βCH3	βCH3	I	[48]
195	Dysidaminone M		H	H	αH	βCH3	βCH3	βCH3	I	[48]
196	18-Methylaminoavarone	H	NHCH3	H	αH	βCH3	βCH3	βCH3	III	[48]
197	19-Methylaminoavarone	NHCH3	H	H	αH	βCH3	βCH3	βCH3	III	[48]
198	18-Aminoavarone	H	NH2	H	αH	βCH3	βCH3	βCH3	III	[48]
199	19-Aminoavarone	NH2	H	H	αH	βCH3	βCH3	βCH3	III	[48]
200	18-Phenethylaminoavarone	H		H	αH	βCH3	βCH3	βCH3	III	[48]
201	Popolohuanone D		H	H	αH	βCH3	βCH3	βCH3	III	[48]
202	(-)-Nakijinol E	OH	OCH3	H	CH3	βCH3	βCH3	βCH3	II	[49]
203	(+)-5-epi-Nakijinol E	OH	OCH3	H	CH3	αCH3	βCH3	βCH3	II	[49]
204	Nakijinone A	CH3	OCH3	H	CH3	βCH3	βCH3	βCH3	VIII	[49]
205	5-epi-Nakijinone A	CH3	OCH3	H	CH3	αCH3	βCH3	βCH3	VIII	[49]
206	18-Deoxy-18-formamidodictyoceratin B	COOCH3	NHCHO	OH	βH	αCH3	αCH3	αCH3	IX	[50]
207	18-Deoxy-18-(2-hydroxyacetyl)aminodictyoceratin B	COOCH3	NHCOCH2OH	OH	βH	αCH3	αCH3	αCH3	IX	[50]
208	N-Methyl-ent-smenospongine	H	NHCH3	OH	βH	αCH3	αCH3	αCH3	I	[50]
209	N-Methyl-5-epi-smenospongine	H	NHCH3	OH	αH	αCH3	βCH3	βCH3	I	[50]
210	20-Demethoxy-20-methylaminodactyloquinone D	H	NHCH3	-	αH	βCH3	βCH3	βCH3	X	[50,54]
211	20-Demethoxy-20-methylamino-5-epidactylo-quinone D	H	NHCH3	-	αH	βCH3	βCH3	βCH3	IV	[50]
212	20-Demethoxy-20-methylaminodactyloquinone B	H	NHCH3	-	-	αCH3	βCH3	βCH3	XI	[50]
213	5-epi-Smenospongine	H	NH2	OH	αH	αCH3	βCH3	βCH3	IV	[50]
214	Smenospongiadine	H		OH	αH	βCH3	βCH3	βCH3	IV	[50]
215	Dactylospongin A	H	OH	H	βH	αCH3	αCH3	αCH3	XII	[51]
216	Dactylospongin B	H	OH	H	αH	βCH3	βCH3	βCH3	XIII	[51]
217	Dactylospongin C	NHCHO	H	H	βH	αCH3	αCH3	αCH3	XIV	[51]
218	Dactylospongin D	NHCHO	H	H	αH	βCH3	βCH3	βCH3	XV	[51]
219	ent-Melemeleone B	NHCH2CH2SO3H	H	H	βH	αCH3	αCH3	αCH3	V	[51]
220	Melemeleone C	H	NHCH2CH2SO3H	H	βH	αCH3	αCH3	αCH3	V	[51]
221	Melemeleone D	NHCH2CH2SO3H	H	H	αH	βCH3	βCH3	βCH3	IV	[51]
222	Melemeleone E	H	NHCH2CH2SO3H	-	αH	βCH3	βCH3	βCH3	XVI	[51]
223	Dysidaminone N	H		H	αH	βCH3	βCH3	βCH3	IV	[51]
224	Nakijiquinone V	H		OH	αH	βCH3	βCH3	βCH3	IV	[52]
225	Cinerol A	H	OH	-	αH	βCH3	βCH3	βCH3	XVII	[53]
226	Cinerol B	H	OH	-	αH	βCH3	βCH3	βCH3	XVIII	[53]
227	Cinerol C	H	OH	H	αH	βCH3	βCH3	βCH3	VI	[53]
228	Cinerol D	H	OH	CH3	αH	βCH3	βCH3	βCH3	VI	[53]
229	Cinerol E	H	OH	H	CH3	βCH3	βCH3	βCH3	II	[53]
230	Cinerol F	H	OH	H	αH	βCH3	βCH3	βCH3	XIX	[53]
231	Cinerol G	H	OH	CH3	αH	βCH3	βCH3	βCH3	XIX	[53]
232	Cinerol H		H	H	αH	βCH3	βCH3	βCH3	XIV	[53]
233	Cinerol I		H	H	αH	βCH3	βCH3	βCH3	XIV	[53]
234	Cinerol J	NHCHO	H	H	αH	βCH3	βCH3	βCH3	XIV	[53]
235	Cinerol K	NHCOCH2CH(CH3)2	H	H	αH	βCH3	βCH3	βCH3	XIV	[53]
236	20-Demethoxy-20-isopentylaminodactyloquinone D	H	NH(CH2)2CH(CH3)2	-	αH	βCH3	βCH3	βCH3	X	[54]
237	20-Demethoxy-20-isobutylaminodactyloquinone D	H	NHCH2CH(CH3)2	-	αH	βCH3	βCH3	βCH3	X	[54]
238	Smenospongiarine	H	NH(CH2)2CH(CH3)2	OH	βH	αCH3	αCH3	αCH3	I	[54]
239	Smenospongorine	H	NHCH2CH(CH3)2	OH	βH	αCH3	αCH3	αCH3	I	[54]
240	Smenospongimine	H	NHCH3	OH	βH	αCH3	αCH3	αCH3	I	[54]
241	(+)-19-Methylaminoavarone	NHCH3	H	H	αH	βCH3	βCH3	βCH3	V	[55]
242	(−)-20-Phenethylaminoavarone	H		H	αH	βCH3	βCH3	βCH3	V	[55]
243	(−)-20-Methylaminoavarone	H	NHCH3	H	αH	βCH3	βCH3	βCH3	V	[55]
244	Dysidinoid B	H	H	-	αH	βCH3	βCH3	βCH3	XX	[56]
245	Dysicigyhone A	H	OH	CH3	αH	βCH3	βCH3	βCH3	XXI	[56]
246	5-epi-Nakijiquinone L	H	NHCH2CH(CH3)CH2CH3	OH	αH	αCH3	βCH3	βCH3	IV	[57]
247	5-epi-Smenospongiarine	H	NH(CH2)2CH(CH3)2	OH	αH	αCH3	βCH3	βCH3	IV	[57]

Drimane sesquiterpenoid-indole alkaloids rarely occur in Nature. Only eight compounds were isolated from actinomycete Streptomyces sp. Three hybrid isoprenoid drimane derivatives―indotertine A (248), drimentine F (249) and drimentine G (250) (Figure 4)—were afforded from a reed rhizosphere soil-derived actinomycete Streptomyces sp. CHQ-64 [58]. Compound 250 showed strong cytotoxicity against human cancer cells lines with IC50′s down to 1.01 μM, while 248 and 249 showed no significant activity [58]. Four new indolo-drimanesesquiterpenes, dixiamycins A (251) and B (252), oxiamycin (253), and chloroxiamycin (254), were isolated from a marine-derived actinomycete Streptomyces sp. and characterized, together with the known compound xiamycin A (255) (Figure 4) [59]. 251 and 252 are the first examples of atropisomerism of naturally occurring N−N-coupled atropo-diastereomers, with a dimeric indolo-sesquiterpene skeleton and a stereogenic N−N axis between sp3-hybridized nitrogen atoms [59]. The two dimeric compounds 251 and 252 showed better antibacterial activities than the monomers 253–255 with the IC50 values of 4–16 μg/mL against four indicator strains (Escherichia coli ATCC25922, Staphylococcus aureus ATCC 29213, Bacillus subtilis SCSIO BS01 and Bacillus thuringiensis SCSIO BT01) [59].

Figure 4

The structures of compounds 248–255.

2.3. Eudesmane Sesquiterpenoids

Eleven nitrogen-containing eudesmane sesquiterpenoids, halichonadins G–Q (256–266) (Figure 5), were isolated from a marine sponge Halichondria sp., and compounds 256 and 258 showed cytotoxicity against murine lymphoma L1210 cells (IC50 5.9 and 6.9 μg/mL)and human epidermoid carcinoma KB cells (IC50 6.7 and 3.4 μg/mL) in vitro, Halichonadin K showed cytotoxicity against human epidermoid carcinoma KB cells (IC50 10.6 μg/mL) in vitro, and halichonadin O displayed antimicrobial activity against Staphylococcus aureus (MIC 8 µg/mL), Micrococcus luteus (MIC 8 µg/mL), and Trichophyton mentagrophytes (IC50 16 µg/mL) [60,61,62]. One eudesmane-type sesquiterpene, phaeusmane I (267) (Figure 5), was isolatedfrom the rhizomes of Curcuma phaeocaulis [63]. Three new nitrogen-containing sesquiterpenoids, the cespilamides C–E (268–270, Figure 5) were purified from the Taiwanese soft coral Cespitularia taeniata, and 270 exhibited cytotoxicity against human breast adenocarcinoma (MCF-7), medulloblastoma (Daoy), and cervical epitheloid carcinoma (Hela) cancer cells with IC50 of 17.5, 22.3, and 24.7 μM, respectively [64]. Acanthine B (271), acanthine C (272), 11-isocyano-7βH-eudesm-5-ene (273), 11-isothiocyano-7βH-eudesm-5-ene (274), and 11-formamido-7βH-eudesm-5-ene (275) (Figure 5), were isolated from the Thai sponge Halichondria sp. [65]. Four new uncommon nitrogenous eudesmane-type sesquiterpenes, axiriabilines A–D (276–279), and one known related ent-stylotelline (280) (Figure 5), were isolated from the Hainan sponge Axinyssa variabilis with no cytotoxicity against several cancer cells [66]. Axiriabiline A (276) and 11-formamido-7βH-eudesm-5-ene (281) (Figure 5) were extracted from South China Sea Nudibranchs Phyllidiella sp. [67]. Spiroalanpyrroids A (282) and B (283), two sesquiterpene alkaloids with an unprecedented eudesmanolide-pyrrolizidine spiro [55] framework, were isolated together with two new sesquiterpene-amino acidadducts, helenalanprolines A (284) and B (285) (Figure 5), from the roots of Inula helenium [68]. Bioassays showed that 284 and 285 significantly inhibited nitric oxide production in lipopolysaccharide-induced RAW 264.7 macrophages with IC50 values of 15.8 and 13.5 μM, respectively [68].

Figure 5

The structures of compounds 256–285.

2.4. Cadinane Sesquiterpenoids

Two nitrogenous cadinane sesquiterpenes (3S*, 5R*, 6R*, 9R*)-3-formamido-1(10)-cadinene (286) and (−)-halichamine (287) (Figure 6) were isolated from the Thai marine sponge Halichondria sp. [69]. Compound 286 showed moderate cytotoxic activity against HeLa, MOLT-3, and HepG2 cell lines with IC50 valued of 32.1, 33.4, and 16.0 mM, respectively, while compound 287 also displayed moderate cytotoxic activity against HuCCA-1, MOLT-3, HepG2, and MDA-MB231 cell lines with IC50 valued of 20.3, 34.6, 19.9, and 22.6 mM, respectively [69]. (1R, 6S, 7S, 10S)-10-isothiocyanato-4-amorphene (288), axinisothiocyanate J (289) (Figure 6) were extracted from the marine sponge Axinyssa sp. [70]. Halichon C (290) and 4-epihalichon C (291), halichon D (292), halichonG (293), (−)-10-isocyano-4-cadinene (294), and (−)-10-isothiocyanato-4-cadinene (295) (Figure 6), were obtained from the Thai sponge Halichondria sp. [65]. Compounds 290, 291, and 294 exhibited moderate cytotoxicity (IC50 20.9, 29.0, and 9.1 μM, respectively) against the MOLT-3 cell line and compound 292 also showed moderate cytotoxicity against HepG2 and MDA-MB-231 cell lines with IC50 values of 24.3 and 19.3 μM, respectively [65]. New stereoisomers of (+)-(1S*, 4S*, 6S*, 7R*)-4-Isocyano-9-amorphene (296) and of (−)-(1S*, 6R*, 7R*, 10S*)-10-isocyano-4-amorphene (297), 4α-isocyano-9-amorphene (298), (1S*, 4S*, 6S*, 7R*)-4-thiocyanate-9-cadinene (299), (−)-10-isocyano-4-amorphene (300), (−)-10-isothiocyanato-4-cadinene (301) (Figure 6), were identified from Phyllidiella pustulosa and from Phyllidia ocellata [71]. A novel sesquiterpenoidal lactam, commipholactam A (302) (Figure 6) was isolated from Resina commiphora [72]. Biological assessment against human cancer cells showed that the IC50 values of 302 against HepG2 and A549 cells were 21.73 μM and 128.50 μM, respectively [72]. Axidaoisocyanate A (303), 10-isothiocyanato-4-cadinene (304), 10-formamido-4-cadinene (305), along with 289, 293 (Figure 6), were identified from two South China Sea Nudibranchs Phyllidiella pustulosa, Phyllidia coelestis [67].

Figure 6

The structures of compounds 286–305.

2.5. Bisabolane Sesquiterpenoids

Brasilamides E–J (306-311), bisabolane sesquiterpenoids with 3-cyclohexylfuran (306 and 307) and 3-cyclohexylfuranone (308–311) skeletons (Figure 7), were isolated from scaled-up fermentation cultures of the plant endophytic fungus Paraconiothynium brasiliense Verkley [73]. Compound 307 selectively inhibited the proliferation of the breast (MCF-7) and gastric (MGC) cancer cell lines, with IC50 values of 8.4 and 14.7 μM, respectively [73]. N,N’-bis[(6R,7S)-7-amino-7,8-dihydro-a-bisabolen-7-yl]urea (304), and (6R,7S)-7-amino-7,8-dihydro-α-bisabolene (313) (Figure 7), were purified from the marine sponge Axinyssa sp. collected atIriomote Island [70]. Compound 312 was the most potent inhibitor of PTP1B activity (IC50 = 1.9 μM) without cytotoxicity at 50 μM in two human cancer cell lines, hepatoma Huh-7 and bladder carcinoma EJ-1 cells [70]. Compound 312 also moderately enhanced the insulin-stimulated phosphorylation levels of Aktin Huh-7 cells [70]. D7,14-3-isocyanotheonellin (314) and 3-isocyanotheonellin (315), theonellin formamide (316), theonellin isothiocyanate (317), and 7-isocyano-7,8-dihydro-α-bisabolene (318) (Figure 7) were extracted from the two South China Sea nudibranchs Phyllidiella pustulosa and Phyllidia coelestis [67]. Compounds 315, 317, and 318 exhibited strong cytotoxicity against human cancercell line SNU-398 with IC50 values of 0.50, 2.15, and 0.50 μM, respectively [67]. In addition, compound 315 also displayed broad cytotoxicity against the other three cancer cell lines, including A549, HT-29, and Capan-1, with IC50 values of 8.60, 3.35, and 1.98 µM, respectively [67]. A rearranged bisabolene-type sesquiterpene, halichonic acid (319), was isolated from a marine sponge Halichondria sp., together with313 [ (Figure 7). Compound 313 was cytotoxic against HeLa cells with an IC50 value of 50 μM, whereas 314 did not show cytotoxicity even at 50 μM [74]. Five novel highly oxygenated norbisabolane sesquiterpene, namely phyllanthacidoid U (320), phyllanthacidoidA (321),phyllanthacidoid B (322), phyllanthacidoid L (323), and phyllanthacidoid S (324) (Figure 7) were isolated from the roots and stems of Phyllanthus acidus, and compounds 321–323 displayed potential anti hepatitis B virus (anti-HBV) activities [75].

Figure 7

The structures of compounds 306–324.

2.6. Germacrane, Elemaneand Iresane Sesquiterpenoids

Two germacrane-type sesquiterpenoid dimers―isobisparthenolidine (325) and bisparthenolidine (326) (Figure 8) were isolated from the chloroform-soluble fraction of the methanolic extract of the bark of Magnolia kobus (Magnoliaceae) [76]. Compound 325 displayed broad cytotoxicity against four cancer cell lines, including A549, SK-OV-3, SK-MEL-2, and HCT-15, with IC50 values of 2.0, 1.9, 3.9 and 3.2 µM, respectively [76]. Noveliresane sesquiterpene alkaloids, halichonines A (327), B (328), and C (329) (Figure 8), were identified from the marine sponge Halichondria okadai Kadota, and 328 wasthen subjected to the trypan blue dye exclusion using HL60 human leukemia cells, and showed cytotoxicity (IC50 value: 0.60 µg/mL) [77]. One γ-elemene-type sesquiterpenes, 8β(H)-elema-1,3,7(11)-trien-8,12-lactam (330) (Figure 8) was obtained from the rhizomes of Curcuma phaeocaulis [63]. Three new germacrane sesquiterpenoid-typealkaloids with an unusual Δ8-7,12-lactam moiety, glechomanamides A–C (331–333) (Figure 8) were isolated from Salvia scapiformis [78]. In a tube formation assay, 332 showed the most potent antiangiogenic activity in primary screening, and its IC50 value was determined to be 40.4 μM [78]. In addition to VEGFR2, 332 decreased BMP4 expression, which regulates tube formation, and glycolysisrelated proteins, including GLUT1 and HK2, which suggests that the novel compound 332 is worthy of additional investigation for angiogenesis-associated pathological conditions [78]. Onopornoids A–D (334–337) (Figure 8), three elemanes and one germacrane, were extracted from the whole aerial parts of Onopordum alexandrinum, which possess unique structures combining a sesquiterpenoid framework with an amino acid, L-proline [79].

Figure 8

The structures of compounds 325–337.

2.7. Farnesane, Spiroaxane, Aromadendrane and Pupukeanane Sesquiterpenoids

Chemical investigation of the endophytic fungus Emericella sp. (HK-ZJ) isolated from the mangrove plant Aegiceras corniculatum led to the isolation of six farnesane sesquiterpenoids named emeriphenolicins A–F (338–343) (Figure 9) with moderate anti-influenza A viral (H1N1) activities [80]. An unusual farnesane natural product (dotofide, 344) (Figure 9), in which the terpenoid skeleton is interrupted by a guanidine moiety was obtained from the marine slug Doto pinnatifida [81]. Two spiroaxane sesquiterpenes, (−)-axisonitrile-3 (345), (+)-axamide-3 (346), and one aromadendrane sesquiterpene axamide-2 (347) (Figure 9) were isolated from the Thai marine sponge Halichondria sp., and only 345 showed strong activity to the HepG2 cell line withan IC50 value of 1.3 µM [69]. Fasciospyrinadine (348) (Figure 9), a novel farnesane sesquiterpene pyridine alkaloid was extracted froma Guangxi sponge Fasciospongia sp. [82].

Figure 9

The structures of compounds 338–354.

Apupukeanane-type sesquiterpenoid isomers, 9-thiocyanatopupukeanane isomers (349–350) (Figure 9) were isolated from the the Thai sponge Halichondria sp. [65]. A bioassay-guided phytochemical study was conducted on the semi-mangrove plant Myoporum bontioides. A. Gray, which led to the isolation of two new farnesane sesquiterpene alkaloids, myoporumines A (351) and B (352) (Figure 9), which displayed potent anti-MRSA activity with MIC value of 6.25 µg/mL [83]. Two aromadendrane sesquiterpene 1-isothiocyanatoaromadendrane (353) and 347, one spioaxane-type sesquiterpenoid axamide-3 (354), and two pupukeanane-type sesquiterpenoids (349, 350) (Figure 9), were isolated from the nudibranchs Phyllidiella pustulosa and Phyllidia coelestis [67].

2.8. Tremulane, Daucane, Brasilane, Salvialane, Aristolane, Bergamotane and Valerane Sesquiterpenoids

Huptremules A–D (compounds 355–358) (Figure 10) featuring unusual sesquiterpenoid-alkaloid hybrid structures that integrate the characteristics offungal metabolites (tremulane sesquiterpenoids) and the exogenous substrate, were isolated from a fungal endophyte of Huperzia serrata [84]. Compound 355–358 selectively inhibited acetylcholinesterase activities, with IC50 values of 0.99, 2.17, 0.11 and 0.06 μM, respectively [84]. Two daucane-type sesquiterpenoids, aculeneA (359) and B (360) (Figure 10), were identified from Aspergillus aculeatus, which were tested for antifungal activity against Candida albicans. However, all showed only weak orno activity [85]. One brasilane-type sesquiterpenoid, named diaporol L (361) (Figure 10) was isolated from Diaporthe sp., an endophytic fungus associated with the leaves of Rhizophora stylosa collected in Hainan Province, China [86]. One salvialane-type sesquiterpene halichon E (362) and one aristolane sesquiterpene epipolasin A (363) (Figure 10) were obtained from the Thai sponge Halichondria sp. [65]. Sporulaminals A (364) and B (365) (Figure 10), a pair of unusual epimericspiroaminal derivatives, bearing 6/4/5/5 tetracyclic ring system derived from bergamotane sesquiterpenoid, were isolated from a marine-derived fungus Paraconiothyrium sporulosum YK-03 [87]. Volvalerine A (366) (Figure 10), a novel N-containing valerane bisesquiterpenoid derivative with a dihydroisoxazole ring, was isolated from the roots of Valeriana officinalis var. latifolia [88]. Compound 366 was also evaluated for their enhancing activity on NGF mediated neurite outgrowth in PC12 cells. The result indicatedthat the proportion of the NGF-induced neurite-bearing cells (with NGF 5 ng/mL) was not enhanced by compound 366 at 50 μM [88].

Figure 10

The structures of compounds 355–366.

2.9. Cyclonerane, Axane, Nardosinane, Zizaane, Eremophilane, and Guaiane Sesquiterpenoids

The nitrogenous cycloneranesesquiterpenescyclonerin A (367) and B (368) along with seven new congeners―deoxycyclonerins A–D (369–372), cyclonerinal (373), and cyclonerizole (374) (Figure 11)―were isolated from the culture of a marine algicolous strain(A-YMD-9-2) of Trichoderma asperellum [89]. And, compounds (367–374) showed significant cytotoxic activityagainst harmful microalgae Chattonella marina with the IC50 value of 2.1–30 μg/mL [89]. Antartin (375) (Figure 11), a cytotoxic zizaane-type sesquiterpenoid was obtained from a Streptomyces sp. SCO736, isolated from an Antarcticmarine sediment, and showed cytotoxicity against A549, H1299, and U87 cancer cell lines by causing cell cycle arrest at the G1 phase [90]. One eremophilane sesquiterpene dendryphiellin J (376) (Figure 11) was isolated from the marine-derived fungus Cochliobolus lunatus SCSIO41401 [91]. Compound 376, a rare naturally occurring aldoxime analogue, displayed cytotoxicities against ACHN and HepG-2 cells with IC50 values of 3.1 and 5.9 μM, respectively [91]. One unusual sesquiterpenoid dimer, nardochinoid B (377) (Figure 11) was isolated from Nardostachys chinensis Batal [92]. Compound 377 is the first nitrogen-containing nornardosinane-aristolane sesquiterpene conjugate. The ED50 of compound 377 on the production of NO was 5.73, and obviously inhibited LPS-inducediNOS and COX-2 protein expression in a dose-dependent way, and increased HO-1 protein expression at the concentration of 10 μM [92].Three axane sesquiterpenoid isonitrile pictaisonitrile-1 (378), pictaisonitrile-2 (379), and cavernothiocyanate (380) (Figure 11) were extracted from hyllidiapicta collected from Bali, Indonesia [71]. Vlasoulamine A (381) (Figure 11), an unprecedented guaiane sesquiterpene lactone dimerfeaturing a fully hydrogenated pyrrolo[2,1,5-cd] indolizine core, was isolated from the roots of Vladimiria souliei [93]. Moreover, 381 exhibited neuroprotective activity whenevaluated for glutamate-induced cytotoxicity, nuclear Hoechst 33,258 staining, and measuring intracellular reactive oxygen species levels, using a rat pheochromocytoma PC12 cell-based model system [93]. Clavukoellians A–D (382-385) (Figure 11), highly rearranged nardosinane Sesquiterpenoids with antiangiogenic activity were purified from the marine soft coral Clavularia koellikeri [94]. Compound 382 has aunique skeleton with both lactone and maleimide ring systems, which is rare in natural products, and appears to be formed byoxidative cleavage of the C-7/C-8 bond of a nardosinane precursor with inhibiting the migration of the human umbilical veinendothelial cells (HUVECs) at 2.5 μM [94].

Figure 11

The structures of compounds 367–385.

2.10. Others

Five sesquiterpene isocyanides, isothiocyanates, thiocyanates, andformamides―halichon A (386), halichon B (387), halichon F (388), halichon H (389), and (+)-2-thiocyanatoneopupukeanane (390) (Figure 12) ― were isolated from the Thai sponge Halichondria sp. [65]. Lamellodysidine B (391) (Figure 12), a sesquiterpenes isolated from the marine sponge Lamellodysidea herbacea, collected inIndonesia [95]. Biological activities of 391 was tested in our in-house screening including cytotoxicity, antimicrobial activities, inhibitory activity of the cholesterol ester accumulation in macrophages, inhibitory activity of the RANKL-induced formation of multinuclear osteoclasts, and inhibitory activities of the ubiquitin-proteasome system (proteasome, E1,Ubc13 (E2)−Uev1A interaction, p53-Mdm2 (E3) interaction, and USP7). However, no significant activity was detected forthe compound [95].

Figure 12

The structures of compounds 386–391.

3. Occurrence

Natural nitrogenous sesquiterpenoids are mainly distributed in species of plants belonging to the Celastraceae, Saxifragaceae, Zingiberaceae, Asteraceae, Burseraceae, Phyllanthaceae, Magnoliaceae, Lamiaceae, Myoporaceae, and Valerianaceae families, marine sponges belonging to the Dysiseidae, Thorectidae, Spongiidae, and Halichodriae families, soft corals belonging to the Xeniidae and Clavulariidae families, phyllidid nudibranchs belonging to the Phyllidiidae family, marine slugs belonging to the Dotidae family), fungi belonging to the Trichocomaceae, Eurotiaceae, Parmulariaceae, Phanerochaetaceae, Diaporthaceae, and Pezizaceae families, bacteria belonging to the Pseudomonadaceae family, and actinomyces belonging to the Streptomycetaceae family (Table 3). Dihydroagarofuran sesquiterpenoids have been isolated from the roots of Maytenus mekongensis, the stems of M. oblongata, the leaves of M. spinosa, the roots and leaves of Tripterygium wilfordii, the stems of T. regelii, the root barks of T. hypoglaucum, the fruits of Celastrus orbiculatus, the seeds of C. paniculatus, the root barks of C. angulatus, the stems of Euonymus alatus, the whole plants of Parnassia wightiana, the leaves of Monimopetalum chinense. Friedo-drimane and drimane sesquiterpenes have been extracted from maring sponges of the following species: Dysidea sp., D. avara, D. fragilis, D. cinerea, D. septosa, Dactylospongia sp., D. elegans, and D. metachromia. Drimane sesquiterpenoids have been purified from the fungi Aspergillus ochraceus, A. aculeatus, Talaromyces minioluteus, and Penicillium sp. ZZ1283, the bacterium Saccharomonospora sp. CNQ-490, and the actinomycete Streptomyces sp. Eudesmane sesquiterpenoids have been identified inmarine sponges of Halichondria sp., H. okadai, Axinyssa sp., and A. variabilis, the soft coral Cespitularia taeniata, phyllidid nudibranchs of the Phyllidiella sp., P. pustulosa, and P. ocellate species and the plants Curcuma phaeocaulis and Inula helenium L. Germacranese squiterpenoids were isolated from the plants Onopordum alexandrinum, Magnolia kobus, and Salvia scapiformis. Cadinane sesquiterpenes were extracted from the plant Resina commiphora, marine sponges like Halichondria sp. and Axinyssa sp., phyllidid nudibranchs of the Phyllidiella sp. Bisabolane sesquiterpenoids have been isolated from Phyllanthus acidus (L.) skeels, Halichondria sp. Phyllidiella sp., Paraconiothynium brasiliense and P. sporulosum.

Table 3

The species containing nitrogenous sesquiterpenoids.

Classification	Family	Species	Type	Reference
Plant	Celastraceae	Maytenus mekongensis; M. spinosa; M. oblongata	Dihydroagarofuran	[17,25,30]
		Tripterygium wilfordii; T. regelii; T. hypoglaucum		[18,20,21,23,24,26,28,29,31,32,33,36]
		Celastrus orbiculatus; C. angulatus; C. paniculatus		[19,34,37]
		Euonymus alatus		[22]
		Monimopetalum chinense		[35]
	Saxifragaceae	Parnassia wightiana		[27]
	Zingiberaceae	Curcuma phaeocaulis	Eudesmane; Elemene	[63]
	Asteraceae	Inula helenium L.	Eudesmane	[68]
		Onopordum alexandrinum	Germacrane; Elemene	[79]
		Vladimiria souliei	Guaiane	[93]
	Burseraceae	Resina commiphora	Cadinane	[72]
	Phyllanthaceae	Phyllanthus acidus (L.) skeels	Bisabolane	[75]
	Magnoliaceae	Magnolia kobus	Germacrane	[76]
	Lamiaceae	Salvia scapiformis	Germacrane	[78]
	Myoporaceae	Myoporum bontioides	Farnesane	[83]
	Valerianaceae	Valeriana officinalis var. latifolia	Valerane	[88]
		Nardostachys chinensis	Nornardosinane-aristolane	[92]
Sponge	Dysiseidae	Dysidea sp.; D. avara; D. fragilis; D. cinerea; D. septosa	friedo-drimane	[43,45,48,53,55,56]
	Thorectidae	Dactylospongia sp.; D. elegans; D. metachromia		[44,47,51,52,54]
		Smenospongia aurea, S. cerebriformis, and Verongula rigida		[49]
		Verongula cf. rigida Esper		[57]
	Spongiidae	Hippospongia sp.		[46]
		Spongiapertusa Esper		[50]
	Halichodriae	Halichondria sp.; H. okadai	Eudesmane; Cadinane; Spiroaxane; Aromadendrane; Bisabolane; Pupukeanane; Salvialane; Aristolane; Iresane	[60,61,62,65,69,74,77]
		Axinyssa sp.; A. variabilis	Eudesmane; Cadinane; Bisabolene	[66,70]
	Thorectidae	Fasciospongia sp.	Farnesane	[82]
Soft coral	Xeniidae	Cespitularia taeniata	Eudesmane	[64]
	Clavulariidae	Clavularia koellikeri	Nardosinane	[94]
Phyllidid nudibranchs	Phyllidiidae	Phyllidiella sp.; P. pustulosa; P. ocellata	Eudesmane; Cadinane; Bisabolane; Farnesane, spiroaxane; aromadendrane; pupukeanane; Axane	[67,71]
Marine slug	Dotidae	Doto pinnatifida	Farnesane	[81]
Fungus	Trichocomaceae	Aspergillus ochraceus; A. aculeatus	Drimane; Daucane	[38,39,85]
		Talaromyces minioluteus	Drimane	[40]
		Emericella sp.	Farnesane	[80]
	Eurotiaceae	Penicillium sp. ZZ1283.	Drimane	[41]
	Parmulariaceae	Paraconiothynium brasiliense; P. sporulosum	Bisabolane; Bergamotane	[73,87]
	Phanerochaetaceae	Ceriporia lacerate	Tremulane	[84]
	Diaporthaceae	Diaporthe sp.	Brasilane	[86]
	Moniliaceae	Trichoderma asperellum	Cyclonerane	[89]
	Pezizaceae	Cochliobolus lunatus	Eremophilane	[91]
Bacteria	Pseudomonadaceae	Saccharomonospora sp. CNQ-490	Drimane	[42]
Actinomyces	Streptomycetaceae	Streptomyces sp.	Drimane; Zizaane	[58,59,90]

4. Conclusions

In summary, a total of 391 bioactive nitrogenous sesquiterpenoids have been isolated and characterized from plants, microorganisms, and marine organisms at the past ten years. This report systematically describes the occurrence, isolation, structures and biological activities ofthese nearly 400 natural products that contain a nitrogen-carbon/nitrogen-nitrogen/nitrogen-sulfurbond. These natural products are dispersed over severalstructural classes, isolated from many different sources (bothmarine and terrestrial) and possess a diverse array of biological activities. It can be concluded that the structure types are obviously related to the species sources, and the bioactivities of nitrogenous sesquiterpenoids are obviously related to structure types, being particularly important their cytotoxic activities. The important points arising from this review are the following: (1) There are few structural types of N-containing sesquiterpenes in plants, while the structural types of sesquiterpenes with nitrogen in marine resources and microorganisms are various and diverse. (2) Dihydroagarofuran sesquiterpenoids were considered the most widespread and characteristic metabolites of the plants of Celastraceae, which are well recognized as characteristic metabolitesand important chemotaxonomic markers or indicators of the family, exceptforsome β-dihydroagarofurans obtained from the Saxifragaceae species Parnassia wightiana. (3) Sponges and their associated microorganisms are the largest contributors of nitrogenous sesquiterpenoids. Rearranged 4,9-friedo-drimaneterpenoid skeletons represent the majority ofnitrogen-contenting sesquiterpenes isolated from marine sponges. The types of sesquiterpenoids that are the most abundant among the marine organisms, Halichondria sp. (sponge) and Phyllidiella sp. (nudibranchs), are all sesquiterpene isocyanides, isothiocyanates, thiocyanates, and formamides. (4) Nitrogenous sesquiterpenes are rich in microorganisms, such as fungus, bacteria and actinomyces and the main skeleton types are drimane, bisabolane, farnesane, tremulane sesquiterpenoids and so on. (5) Dihydroagarofuran sesquiterpenoids show significant anti-inflammatory, neuroprotective, and immunosuppressive effects, while sesquiterpenes isolated from marine organisms exhibit remarkable antitumor cytotoxic activities. Due to the rich activities and structural diversity of N-contenting sesquiterpenes, researchers have not stopped exploring and studying such compounds. We hope this review will stimulate further researchinto this interesting class of nitrogenous secondary metabolites.