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Journal of Natural Medicines
Published in: Journal of Natural Medicines 4/2017

Open Access 01-10-2017 | Review

Naturally occurring Vpr inhibitors from medicinal plants of Myanmar

Authors: Nwet Nwet Win, Hla Ngwe, Ikuro Abe, Hiroyuki Morita

Published in: Journal of Natural Medicines | Issue 4/2017

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Abstract

Human immunodeficiency virus type-1 (HIV-1) is a lentiviral family member that encodes the retroviral Gag, Pol, and Env proteins, along with six additional accessory proteins, Tat, Rev, Vpu, Vif, Nef, and Vpr. The currently approved anti-HIV drugs target the Pol and Env encoded proteins. However, these drugs are only effective in reducing viral replication. Furthermore, the drugs’ toxicities and the emergence of drug-resistant strains have become serious worldwide problems. Resistance eventually arises to all of the approved anti-HIV drugs, including the newly approved drugs that target HIV integrase (IN). Drug resistance likely emerges because of spontaneous mutations that occur during viral replication. Therefore, new drugs that effectively block other viral components must be developed to reduce the rate of resistance and suppress viral replication with little or no long-term toxicity. The accessory proteins may expand treatment options. Viral protein R (Vpr) is one of the promising drug targets among the HIV accessory proteins. However, the search for inhibitors continues in anti-HIV drug discovery. In this review, we summarize the naturally occurring compounds discovered from two Myanmar medicinal plants as well as their structure-activity relationships. A total of 49 secondary metabolites were isolated from Kaempferia pulchra rhizomes and Picrasama javanica bark, and the types of compounds were identified as isopimarane diterpenoids and picrasane quassinoids, respectively. Among the isolates, 7 diterpenoids and 15 quassinoids were found to be Vpr inhibitors lacking detectable toxicity, and their potencies varied according to their respective functionalities.
Literature
1.
UNAIDS (2106), Global AIDS update 2016: 1 16
2.
FDA approves maraviroc tablets (2007) AIDS patient care STDs 21:702
3.
FDA notification (2007) Accelerated approval for raltegravir tablets. AIDS Alert 22:143–144
4.
Richter SN, Frasson I, Palù G (2009) Strategies for inhibiting function of HIV-1 accessory proteins: a necessary route to AIDS therapy? Curr Med Chem 16:267–286CrossRef
5.
Berrey MM, Schacker T, Collier AC, Shea T, Brodie SJ, Mayers D, Coombs R, Krieger J, Chun TW, Fauci A, Self SG, Corey L (2001) Treatment of primary human immunodeficiency virus type 1 infection with potent antiretroviral therapy reduces frequency of rapid progression to AIDS. J Infect Dis 183:1466–1475CrossRef
6.
Kumarasamy N, Venkatesh KK, Cecelia AJ, Devaleenal B, Lai AR, Saghayam S, Balakrishnan P, Yepthomi T, Poongulali S, Flanigan TP, Solomon S, Mayer KH (2008) Spectrum of adverse events after generic HAART in southern Indian HIV-infected patients. AIDS Patient Care STDS 22:337–344CrossRef
7.
Tristem M, Marshall C, Karpas A, Hill F (1992) Evolution of the primate lentiviruses: evidence from vpx and vpr. EMBO J 11:3405–3412CrossRef
8.
Popov S, Rexach M, Zybarth G, Reiling N, Lee MA, Ratner L, Lane CM, Moore MS, Blobel G, Bukrinsky M (1998) Viral protein R regulates nuclear import of the HIV-1 pre-integration complex. EMBO J 17:909–917CrossRef
9.
Agostini I, Navarro JM, Rey F, Bouhamdan M, Spire B, Vigne R, Sire J (1996) The human immunodeficiency virus type 1 Vpr transactivator: cooperation with promoter-bound activator domains and binding to TFIIB. J Mol Biol 261:599–606CrossRef
10.
Forget J, Yao XJ, Mercier J, Cohen EA (1998) Human immunodeficiency virus type 1 Vpr protein transactivation function: mechanism and identification of domains involved. J Mol Biol 284:915–923CrossRef
11.
Jowett JB, Planelles V, Poon B, Shah NP, Chen ML, Chen IS (1995) The human immunodeficiency virus type 1 Vpr gene arrests infected T cells in the G2+ M phase of the cell cycle. J Virol 69:6304–6313PubMedPubMedCentral
12.
Stewart SA, Poon B, Song JY, Chen IS (2000) Human immunodeficiency virus type 1 Vpr induces apoptosis through caspase activation. J Virol 74:3105–3111CrossRef
13.
Kogan M, Rappaport J (2011) HIV-1 accessory protein Vpr: relevance in the pathogenesis of HIV and potential for therapeutic intervention. Retrovirology 8:1–25CrossRef
14.
Watanabe N, Nishihara Y, Yamaguchi T, Koito A, Miyoshi H, Kakeya H, Osada H (2006) Fumagillin suppresses HIV-1 infection of macrophages through the inhibition of Vpr activity. FEBS Lett 580:2598–2602CrossRef
15.
Kamata M, Wu RP, An DS, Saxe JP, Damoiseaux R, Phelps ME, Huang J, Chen IS (2006) Cell-based chemical genetic screen identifies damnacanthal as an inhibitor of HIV-1 Vpr induced cell death. Biochem Biophys Res Commun 348:1101–1106CrossRef
16.
Shimura M, Zhou Y, Asada Y, Yoshikawa T, Hatake K, Takaku F, Ishizaka Y (1999) Inhibition of Vpr-induced cell cycle abnormality by quercetin: a novel strategy for searching compounds targeting Vpr. Biochem Biophys Res Commun 261:308–316CrossRef
17.
Ong EB, Watanabe N, Saito A, Futamura Y, Abd El Galil KH, Koito A, Najimudin N, Osada H (2011) Vipirinin, a coumarin-based HIV-1 Vpr inhibitor, interacts with a hydrophobic region of Vpr. J Biol Chem 286:14049–14056CrossRef
18.
Win NN, Ito T, Aimaiti S, Imagawa H, Ngwe H, Abe I, Morita H (2015) Kaempulchraols A–H, diterpenoids from the rhizomes of Kaempferia pulchra collected in Myanmar. J Nat Prod 78:1113–1118CrossRef
19.
Win NN, Ito T, Aimaiti S, Kodama T, Imagawa H, Ngwe H, Asakawa Y, Abe I, Morita H (2015) Kaempulchraols I–O: new isopimarane diterpenoids from Kaempferia pulchra rhizomes collected in Myanmar and their antiproliferative activity. Tetrahedron 71:4707–4713CrossRef
20.
Win NN, Ito T, Aimaiti S, Kodama T, Tanaka M, Ngwe H, Asakawa Y, Abe I, Morita H (2015) Kaempulchraols P–T, diterpenoids from Kaempferia pulchra rhizomes collected in Myanmar. J Nat Prod 78:2306–2309CrossRef
21.
Win NN, Ito T, Matsui T, Aimaiti S, Kodama T, Ngwe H, Okamoto Y, Tanaka M, Asakawa Y, Abe I, Morita H (2016) Isopimarane diterpenoids from Kaempferia pulchra rhizomes collected in Myanmar and their Vpr inhibitory activity. Bioorg Med Chem Lett 26:1789–1793CrossRef
22.
Win NN, Ito T, Ismail Kodama T, Win YY, Tanaka M, Ngwe H, Asakawa Y, Abe I, Morita H (2015) Picrajavanicins A–G, quassinoids from Picrasma javanica collected in Myanmar. J Nat Prod 78:3024–3030CrossRef
23.
Win NN, Ito T, Ismail Kodama T, Win YY, Tanaka M, Okamoto Y, Imagawa H, Ngwe H, Asakawa Y, Abe I, Morita H (2016) Picrajavanicins H–M, new quassinoids from Picrasma javanica collected in Myanmar and their antiproliferative activities. Tetrahedron 72:746–752CrossRef
24.
Win NN, Ito T, Win YY, Ngwe H, Kodama T, Abe I, Morita H (2016) Quassinoids: viral protein R inhibitors from Picrasma javanica bark collected in Myanmar for HIV infection. Bioorg Med Chem Lett 26:4620–4624CrossRef
25.
Department of Traditional Medicine (1990) The traditional medicine formulations used in Myanmar traditional medicine. Ministry of Health, Myanmar
26.
Tuchinda P, Udchachon J, Reutrakul V, Santisuk T, Skelton BW, White AH, Taylor WC (1994) Pimarane diterpenes from Kaempferia pulchra. Phytochemistry 36:731–734CrossRef
27.
Prasad S, Yadav VR, Sundaram C, Reuter S, Hema PS, Nair MS, Chaturvedi MM, Aggarwal BB (2010) Crotepoxide chemosensitizes tumor cells through inhibition of expression of proliferation, invasion, and angiogenic proteins linked to proinflammatory pathway. J Biol Chem 285:26987–26997CrossRef
28.
Prawat U, Tuntiwachwuttikul P, Taylor WC, Engelhardt LM, Skelton BW, White AH (1993) Diterpenes from a Kaempferia species. Phytochemistry 32:991–997CrossRef
29.
Koike K, Yokoh M, Furukawa M, Ishii S, Ohmoto T (1995) Picrasane quassinoids from Picrasma javanica. Phytochemistry 40:233–238CrossRef
30.
Koike K, Ohmoto T, Uchida A, Oonishi I (1994) Javacarboline, a new β-carboline alkaloid from the stem of Picrasma javanica in Java. Heterocycles 38:1413–1420CrossRef
31.
Yoshikawa M, Harada E, Aoki S, Yamahara J, Murakami N, Shibuya H, Kitagawa I (1993) Indonesian medicinal plants. VI. On the chemical constituents of the bark of Picrasma javanica BL. (Simaroubaceae) from Flores Island. Absolute stereostructures of picrajavanins A and B. Chem Pharm Bull 41:2101–2105CrossRef
32.
Koike K, Ohmoto T (1992) New quassinoid glucosides, javanicinosides I, J, K, and L, from Picrasma javanica. J Nat Prod 55:482–486CrossRef
33.
Ishii K, Koike K, Ohmoto T (1991) Javanicinosides D–H, quassinoid glucosides from Picrasma javanica. Phytochemistry 30:4099–4103CrossRef
34.
Koike K, Ishii K, Mitsunaga K, Ohmoto T (1991) New quassinoids from Picrasma javanica. Structures of javanicins U, V, W, X and Y. Chem Pharm Bull 39:2021–2023CrossRef
35.
Koike K, Ishii K, Mitsunaga K, Ohmoto T (1991) New des-4-methylpicrasane quassinoids from Picrasma javanica. J Nat Prod 54:837–843CrossRef
36.
Koike K, Ishii K, Mitsunaga K, Ohmoto T (1991) Javanicins N, P and Q, new quassinoids from Picrasma javanica. Chem Pharm Bull 39:939–941CrossRef
37.
Koike K, Ishii K, Mitsunaga K, Ohmoto T (1991) Constituents from Picrasma javanica. Part 6. Quassinoids from Picrasma javanica. Phytochemistry 30:933–936CrossRef
38.
Koike K, Ohmoto T (1990) Constituents from Picrasma javanica. Part 4. Quassinoids from Picrasma javanica. Phytochemistry 29:2617–2621CrossRef
39.
Koike K, Ishii K, Ohmoto T (1990) Quassinoids from Picrasma javanica. Tennen Yuki Kagobutsu Toronkai Koen Yoshishu 32:175–182
40.
Koike K, Mitsunaga K, Ohmoto T (1990) New quassinoids from Indonesian Picrasma javanica. Structures of javanicins E, F, G and M. Chem Pharm Bull 38:2746–2749CrossRef
41.
Arbain D, Byrne LT, Sargent MV, Skelton BW, White AH (1990) The alkaloids of Picrasma javanica: further studies. Aust J Chem 43:433–437CrossRef
42.
Ohmoto T, Koike K, Mitsunaga K, Fukuda H, Kagei K (1989) Studies on the constituents of Indonesian Picrasma javanica. III. Structures of new quassinoids, javanicins A, C and D. Chem Pharm Bull 37:2991–2994CrossRef
43.
Ohmoto T, Koike K, Mitsunaga K, Fukuda H, Kagei K, Kawai T, Sato T (1989) Studies on the constituents of Indonesian Picrasma javanica. II. Structure of a new quassinoid glucoside, javanicinoside A. Chem Pharm Bull 37:993–995CrossRef
44.
Ohmoto T, Koike K, Kagei K (1987) Alkaloids from Picrasma javanica growing in Indonesia. Shoyakugaku Zasshi 41:338–340
45.
Arbain D, Sargent MV (1987) The alkaloids of Picrasma javanica. Aust J Chem 40:1527–1536CrossRef
46.
Johns SR, Lamberton JA, Sioumis AA (1970) 4-Methoxy-1-vinyl-β-carboline, a new alkaloid from Picrasma javanica (Simaroubaceae). Aust J Chem 23:629–630CrossRef
47.
Chang CI, Tseng MH, Kuo YH (2005) Five new diterpenoids from the bark of Taiwania cryptomerioides. Chem Pharm Bull 53:286–289CrossRef
48.
Xia X, Zhang J, Zhang Y, Wei F, Liu X, Jia A, Liu C, Li W, She Z, Lin Y (2012) Pimarane diterpenes from the fungus Epicoccum sp. HS-1 associated with Apostichopus japonicas. Bioorg Med Chem Lett 22:3017–3019CrossRef
49.
Thongnest S, Mahidol C, Sutthivaiyakit S, Ruchirawat S (2005) Oxygenated pimarane diterpenes from Kaempferia marginata. J Nat Prod 68:1632–1636CrossRef
50.
Nagashima F, Murakami M, Takaoka S, Asakawa Y (2003) ent-Isopimarane-type diterpenoids from the New Zealand liverwort Trichocolea mollissima. Phytochemistry 64:1319–1325CrossRef
51.
Touchè EMG, Lopez EG, Reyes AP, Sánchez H, Honecker F, Achenbach H (1997) Parryin, a diterpene with a tricyclic 6-7-5-ring system from Salvia parryi. Phytochemistry 45:387–390CrossRef
52.
Jiao WH, Gao H, Zhao F, He F, Zhou GX, Yao XS (2011) A new neolignan and a new sesterterpenoid from the stems of Picrasma quassioides Bennet. Chem Biodivers 8:1163–1169CrossRef
Metadata
Title
Naturally occurring Vpr inhibitors from medicinal plants of Myanmar
Authors
Nwet Nwet Win
Hla Ngwe
Ikuro Abe
Hiroyuki Morita
Publication date
01-10-2017
Publisher
Springer Singapore
Published in
Journal of Natural Medicines / Issue 4/2017
Print ISSN: 1340-3443
Electronic ISSN: 1861-0293
DOI
https://doi.org/10.1007/s11418-017-1104-7

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