487-89-8 Usage
Description
Indole-3-carboxaldehyde, also known as 1H-Indole-3-carboxaldehyde (I3C), is a natural compound found in various plants such as tomato seedlings, pea seedlings, barley, lupine, cabbage, and cotton. It is a heteroarenecarbaldehyde that is indole in which the hydrogen at position 3 has been replaced by a formyl group. Indole-3-carboxaldehyde is an off-white to beige-brown crystalline powder and represents an important building block of many natural and synthetic biologically active compounds.
Uses
Indole-3-carboxaldehyde is used as a biochemical for the preparation of analogs of the indole phytoalexin cyclobrassinin with NR1R2 group. It is also used as the starting material for the synthesis of higher order indoles, including isoindolo[2,1-a]indoles, aplysinopsins, and 4-substituted-tetrahydrobenz[cd]indoles.
Used in Pharmaceutical Industry:
Used in Material Science:
Indole-3-carboxaldehyde can undergo Schiff bases condensation to form multifunctional silica nano-vehicles and magnetic nanoparticles, which have potential applications in various fields, including drug delivery, catalysis, and sensing.
Biosynthesis
Biosynthesis of natural 1H-indole-3-carboxaldehyde was first suggested by Tang and Bonner who reported that, aldehyde[1] was produced via biotransformation of indole-3acetic acid (IAA) using crude enzyme which is prepared from etiolated pea seedlings[10]. On the other hand, brassinin oxidase (BOLm; a fungal detoxifying enzyme) mediates the conversion of the phytoalexin brassinin into 1H-indole3-carboxaldehyde with equivalent ratio[11].
Also, bacteria play an important role in the biosynthesis of it via biotransformation of L-tryptophan using Escherichia coli[12]. 1H-Indole-3-carboxaldhyde and its derivatives are not only the key intermediates for the preparation of biologically active molecules as well indole alkaloids, but also they are important precursors for the synthesis of diverse heterocyclic derivatives.
Synthesis method
Previously, 1H-indole-3-carboxaldehyde has been prepared synthetically either via direct formylation of indole using e.g., Reimer-Tiemann reaction (aq. KOH/CHCl3)[13], Grignard reaction[14], Vilsmeier Haack reaction (POCl3/DMF)[15] or formylation of the potassium salt of indole using carbon monoxide under robust conditions of heat and pressure[16]. Sommelet reaction on gramine and on indole itself oxidation of N-skatyl-N-phenyl-hydroxylamine and/or by hydrolysis of 3-(1,3-dithiolan-2-yl) indole with boron trifluoride diethyl etherate BF3.O(C2H5)2 and mercury (II) oxide HgO.
Recently, the researchers developed general and simple approaches by the use of environmentally benign reagents in order to obtain 1H-indole-3-carboxaldyhde, for an example: Unusual oxidation of graminemethiodide [1-(1H-indol-3-yl)-N, N, N-trimethylmethanaminium iodide] using sodium nitrite in N, N-dimethylformamide (DMF) produces it in 68% yield[17]. For another method: Alkaline degradation of ascorbigen leads to a mixture of L-sorbose and L-tagatose derivatives. The later ketoses underwent acetylation and open ring of pyranose using acetic anhydride in pyridine in the presence of 4-dimethylaminopyridine (DMAP) leads to a mixture, which are separated by column chromatography. Deacetylations of compounds mixture have been accompanied by the formation of end product with yield (3%)[18].
Applications for the synthesis of bioactive indole alkaloids
Indole alkaloids constitute a large class of natural products and their diverse and complex structures have been attributed to potent biological activities such as anticancer, anti-inflammatory, antimicrobial, antimalarial, antiplasmodial and protein kinase inhibition. The isolation of bioactive compounds from natural sources is difficult, costly and an extremely time-consuming process, therefore synthetic pathways are more convenient than natural separation to deliver such compounds in considerable amounts. 1H-indole-3-carboxaldehyde is an effective precursor for the synthesis of bioactive indole alkaloids utilizing 1H-indole-3-carboxaldehyde and its derivatives.
Phytoalexins
Phytoalexins are secondary metabolites formed after plants have been exposed to stressful conditions. The formed compounds constitute an important defense against pathogenic microbes[19]. The common core structure of more than 20 isolated cruciferous phytoalexins is indole possessing a side chain or a heterocycle (fused or linked) containing one or two sulfur atoms[19, 20]. More than twenty phytoalexins have been identified in the family Cruciferae, occurring in many daily used edible vegetables. Chinese cabbage (brassinin, methoxybrassinin, cyclobrassinin, and methoxybrassitin), Japanese radish (brassitin and spirobrassinin), Japanese cabbage (methoxybrassenins A and B), Japanese kohlrabi (cyclobrassinone and methoxyspirobrassinin), Japanese false flax (camalexin) and Indian mustard (brassilexin) are examples of these vegetables[19, 20].
The isolation of indole phytoalexins from cruciferous plants does not provide sufficient quantities for biological screening. Hence, synthetic methods have been elaborated to prepare sufficient quantities of indole phytoalexins including brassinin, cyclobrassinin, brassitin, cyclobrassinone, brassilexin and (S)-(–)-spirobrassinin. A key intermediate in the synthesis of indole phytoalexins is 3-aminomethylindole, which is prepared from indole-3-carboxaldehyde.
Bis(indole) Alkaloids: Rhopaladines A–D
Four bis (indole) alkaloids, rhopaladines A–D, were isolated from the Okinawan marine tunicate Rhopalaea sp. Rhopaladin B exhibited inhibitory activity against cyclindependent kinase IV and c-ErbB-2 kinase. Rhopaladin C showed antibacterial activity against Sacina lutea and Corynebacterium xerosis[21] Rhopaladines C and D were prepared starting from indole-3-carboxaldehydes.
Coscinamides A and B
Coscinamides A and B are bis (indole)-containing marine natural products that were isolated from the marine sponge Coscinoderma sp. The preparation of coscinamides A and B started with the protection of 1H-indole-3-carboxaldehyde using Roush’s method[6].
Dipodazine, Isocryptolepine and Dipodazine was isolated and characterized as a major metabolite from Penicillium dipodomyis, and subsequently from meat-associated Penicillium nalgiovese[23]. Dipodazine was synthesized via a stereoselective aldol condensation from N-protected indole-3-carboxaldehyde 1b and 1,4diacetyl-2, 5-piperazinedione in the presence of cesium carbonate[24]. Despite the absence of any biological activity expressed by dipodazine, it has several analogues reported as being active as antifouling agents[22]. Isocryptolepine, an indoloquinoline alkaloid, was isolated from the West African plant Cryptolepis sanguinolenta[25]. The total synthesis of isocryptolepine via a photo-induced cyclization was reported in 2011[25]. The reaction of 1H-indole-3-carboxaldehyde (1a) with aniline in glacial acetic acid afforded the corresponding Schiff base, which is a key step.
Carbazole Alkaloids: Mukonine and Clausine E
The 1-oxygenated carbazole alkaloids (clausine E, mukonine, and koenoline) were isolated from higher plants of the Rutaceae family. Its synthesis involved an activation and intramolecular cyclization of monoester acids that were obtained via the reaction of 1H-indole-3-carboxaldehyde (1a) with dimethyl succinate and sodium hydride in methanol (Stobbe condensation)[26].
References
Yannai, S. Dictionary of Food Compounds with CD-ROM: Additives, Flavors, and Ingredients; CRC Press: Boca Raton, 2003.
Nakajima, E.; Nakano, H.; Yamada, K.; Shigemori, H.; Hasegawa, K. Phytochemistry 2002, 61, 863.
El-Sawy, E.; Abo-Salem, H.; Mandour, A. Egypt. J. Chem. 2017, 60, 723.
Philip, N. J.; Synder, H. R. Org. Synth. 1959, 39, 30.
Dzurilla, M.; Kutschy, P.; Zaletova, J.; Ruzinsky, M.; Kovacik, V. Molecules 2001, 6, 716.
Kuramochi, K.; Osada, Y.; Kitahara, T. Tetrahedron 2003, 59, 9447.
Wang, Y. Y.; Chen, C. J. Chin. Chem. Soc. 2013, 54, 1363.
(a) González-Lamothe, R.; Mitchell, G.; Gattuso, M.; Diarra, M. S.; Malouin, F.; Bouarab, K. Int. J. Mol. Sci. 2009, 10, 3400. (b) Burnett, J. C.; Rossi, J. J. Cell Chem. Biol. 2012, 19, 60.
Herrmann, J.; Fayad, A. A.; Mu?ller, R. Nat. Prod. Rep. 2017, 34, 135.
Tang Y. U. and Bonner J., The enzymatic inactivation of indole acetic acid. I. Some characteristics of the enzyme contained in pea seedlings, Arch Biochemistry, 13, 25 (1947).
Pedras M. S. C., Minic Z. and Sarma-Mamillapalle V. K., Brassinin oxidase mediated transformation of the phytoalexin brassinin: Structure of the elusive co-product, deuterium isotope effect and stereoselectivity, Bioorganic of Medicinal Chemistry,19, 1390 (2011).
Chi-Hsinchu H.-T. (TW), US Pat20130273617A1 (2013).
Ellinger A. and Flamand C., About synthetically Obtained tryptophan and some of its derivatives, Hoppe-Seyler's, Zeitschrift fur Physiologische Chemie, 55, 8 (1908).
British Pat. 618, 638 (1949) (Chem. Abst., 1949,
Philip N.J. and Synder H.R., Indole-3-carboxaldhyde, Organic Synthesis, 39, 539 (1959).
Tyson F.J. and Shaw J.T., A new approach to 3-indolecarboxaldehyde, Journal of American Chemical Society, 74, 2273 (1952).
Sridar V., Maheswari R. and Reddy B. S. R.,An unusual oxidation of gramine methiodides under NaNO2/DMF conditionsIndian, Indian Journal of Chemistry (Section B), 40, 1253 (2001).
Lavrenov S. N., Korolev A. M., Reznikova M. I., Sosnov A. V. and Preobrazhenskaya M. N., Study of 1-deoxy-1-(indol-3-yl)-L-sorbose,1deoxy-1-(indol-3-yl)-L-tagatose, and their analogs, Carbohydrate Research, 338, 143 (2003).
Pedras, M. S. C.; Nycholat, C. M.; Montaut, S.; Xu, Y.; Khan, A. Q. Phytochemistry 2002, 59, 611.
Pedras, M. S. C.; Yaya, E. E.; Glawischnig, E. Nat. Prod. Rep. 2011, 28, 1381.
Janosik, T.; Johnson, A.-L.; Bergman, J. Tetrahedron 2002, 58, 2813.
Kumar, R. N.; Suresh, T.; Mohan, P. S. Tetrahedron Lett. 2002, 43, 3327.
Johnson, A.-L.; Janosik, T.; Bergman, J. ARKIVOC 2002, (viii), 57.
Sj?gren, M.; Johnson, A.-L.; Hedner, E.; Dahlstr?m, M.; G?ransson, U.; Shirani, H.; Bergman, J.; Jonsson, P. R.; Bohlin, L. Peptides 2006, 27, 2058.
Hingane, D. G.; Kusurkar, R. S. Tetrahedron Lett. 2011, 52, 3686
Budovská, M.; Kutschy, P.; Ko?ár, T.; Gondová, T.; Petrovaj, J. Tetrahedron 2013, 69, 1092.
Synthesis Reference(s)
Journal of the American Chemical Society, 68, p. 1156, 1946 DOI: 10.1021/ja01211a006The Journal of Organic Chemistry, 60, p. 7272, 1995 DOI: 10.1021/jo00127a036Organic Syntheses, Coll. Vol. 4, p. 539, 1963
Check Digit Verification of cas no
The CAS Registry Mumber 487-89-8 includes 6 digits separated into 3 groups by hyphens. The first part of the number,starting from the left, has 3 digits, 4,8 and 7 respectively; the second part has 2 digits, 8 and 9 respectively.
Calculate Digit Verification of CAS Registry Number 487-89:
(5*4)+(4*8)+(3*7)+(2*8)+(1*9)=98
98 % 10 = 8
So 487-89-8 is a valid CAS Registry Number.
InChI:InChI=1/C9H7NO/c11-6-7-5-10-9-4-2-1-3-8(7)9/h1-6,10H
487-89-8Relevant articles and documents
Triphenylphosphine/1,2-Diiodoethane-Promoted Formylation of Indoles with N, N -Dimethylformamide
Zhu, Yu-Rong,Lin, Jin-Hong,Xiao, Ji-Chang
supporting information, p. 259 - 263 (2021/11/22)
Despite intensive studies on the synthesis of 3-formylindoles, it is still highly desirable to develop efficient methods for the formylation of indoles, due to the shortcomings of the reported methods, such as inconvenient operations and/or harsh reaction conditions. Here, we describe a Ph3P/ICH2CH2I-promoted formylation of indoles with DMF under mild conditions. A Vilsmeier-type intermediate is readily formed from DMF promoted by the Ph3P/ICH2CH2I system. A onestep formylation process can be applied to various electron-rich indoles, but a hydrolysis needs to be carried out as a second step in the case of electron-deficient indoles. Convenient operations make this protocol attractive.
(±)-Camphor sulfonic acid assisted IBX based oxidation of 1° and 2° alcohols
Kumar, Kamlesh,Joshi, Penny,Rawat, Diwan S
, (2021/09/02)
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Hierarchical CeO2@N-C Ultrathin Nanosheets for Efficient Selective Oxidation of Benzylic Alcohols in Water
Han, Xiguang,Hao, Juan,Long, Zhouyang,Sun, Liming,Wang, Xiaojun,Zhan, Wenwen
supporting information, p. 7732 - 7737 (2021/06/27)
A monodisperse CeO2@N-C ultrathin nanosheet self-assembled hierarchical structure (USHR) has been prepared by metal-organic framework template methods. The uniform coating of nitrogen-doped carbon (N-C) layers could play an important role in the adsorption and activation of benzylic alcohol. The unique 3D hierarchical structure self-assembled by ultrathin nanosheets provided enough active sites for the catalytic reaction. Therefore, the CeO2@N-C USHR can afford excellent catalytic performance for selective oxidation of benzylic alcohols in water.