Design and Synthesis of Fluorescent 1,8-Napthalimide Derivatives and Their Identification of Cysteine

doi:10.6023/cjoc202306016

Abstract

Determination of sulfhydryl amino acid content is of great importance for disease research. Therefore, it is necessary to develop a fluorescent probe that can detect sulfhydryl amino acids. In this paper, sixty-one 1,8-naphthoyl derivatives were successfully synthesized. These performances of compounds were measured by UV-Vis spectra and fluorescence spectra (FL). Unlike the non-fluorescent nitro-substituted compounds N-methyl-4-nitro-1,8-napthalimide (4a)~N-(m-fluorophenyl)-4-nitro-1,8-napthalimide (4s), the amino-substituted compounds N-methyl-4-amino-1,8-napthalimide (5a)~N-(m-fluorophenyl)-4-amino-1,8-napthalimide (5s) have strong yellow fluorescence, and the maleic anhydride-sub- stituted compounds N-methyl-4-(1H-pyrrole-2,5-diketone-1-yl)-1,8-napthalimide (6a)~N-(m-fluorophenyl)-4-(1H-pyrrole- 2,5-diketone-1-yl)-1,8-napthalimide (6s) have weak blue fluorescence. Of the 61 probes, 7 probes have fluorescent OFF-ON effect on cysteine (Cys) solutions. It was found that these probes have the potential to detect cysteine. The specificity of the probe for cysteine detection was explored by adding 21 amino acids as distracters. The fluorescence intensity at different pH values were studied. The response time between the detection probe and cysteine, and the variation of the fluorescence intensity of the probe solution with amino acid concentration were also studied. The linear correlation coefficients reached above 0.95. The response time of the probe was tested by fluorescence time spectral scanning. Through the above experiments, it was found that the probe showed a better sensitivity and selectivity for cysteine. The ability of seven fluorescent probes to be used for intracellular cysteine detection was explored by Hela cell fluorescence imaging and screened out probes with potential for biological detection.

Key words: synthesis, fluorescence molecular probe, cysteine, 1,8-napthalimide derivatives, cell fluorescence imaging

Cite this article

Weiqing Yang, Yanbing Ge, Yuanyuan Chen, Ping Liu, Haiyan Fu, Menglin Ma. Design and Synthesis of Fluorescent 1,8-Napthalimide Derivatives and Their Identification of Cysteine[J]. Chinese Journal of Organic Chemistry, 2024, 44(1): 180-194.

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References 15

[1]	(a) Sun, Y.; Fu, M. L; Bian, M. L; Zhu, Q. Biotechnol Bioeng. 2023, 120, 7. doi: 10.1002/bit.v120.1
	(b) Ahmed, N.; Zareen, W.; Ye, Y. Chin. Chem. Lett. 2022, 33, 2765. doi: 10.1016/j.cclet.2021.12.092
	(c) Liu, F. R.; Jing, J.; Zhang, X. L. Chin. J. Org. Chem. 2023, 43, 2053 (in Chinese). doi: 10.6023/cjoc202209005
	(刘飞冉, 敬静, 张小玲, 有机化学, 2023, 43, 2053.)
[2]	(a) Kolinska, J.; Grzelakowska, A. Spectrochim. Acta, A Mol. Biomol. Spectrosc. 2021, 262, 120151. doi: 10.1016/j.saa.2021.120151
	(b) Zhang, Y. L; Shao, X. M; Wang, Y.; Pan, F. C.; Kang, R. X.; Peng, F. F.; Huang, Z. T.; Zhang, W. J; Zhao, W. L. Chem. Commun. 2015, 51, 4245. doi: 10.1039/C4CC08687B
	(c) Ge, C. P.; Wang, H.; Zhang, B. X.; Yao, J.; Li, X. M; Feng, W. M; Zhou, P. P.; Wang, Y. W; Fang, J. G Chem. Commun. 2015, 51, 14913.
[3]	(a) Xu, Z. Y.; Zhao, X. F.; Zhou, M.; Zhang, Z. J; Qin, T. Y; Wang, D.; Wang, L.; Peng, X. J.; Liu, B. Sens. Actuators, B 2021, 345, 130367. doi: 10.1016/j.snb.2021.130367
	(b) Xu, Z. Y.; Si, S. F.; Zhang, Z. J; Tan, H. Y; Qin, T. Y; Wang, Z. L; Wang, D.; Wang, L.; Liu, B. Anal. Chim. Acta 2021, 1176, 338763. doi: 10.1016/j.aca.2021.338763
[4]	(a) Anbu, S.; Paul, A.; Surendranath, K.; Sidali, A.; Pombeiro, A. J. L. J. Inorg. Biochem. 2021, 220, 111466. doi: 10.1016/j.jinorgbio.2021.111466
	(b) Dimov, S. M.; Georgiev, N. I.; Asiri, A. M.; Bojinov, V. B J. Fluoresc. 2014, 24, 1621.
	(c) Georgiev, N. I.; Dimov, S. M.; Asiri, A. M.; Alamry, K. A.; Obaid, A.Y.; Bojinov, V. B. J. Lumin. 2014, 149, 325. doi: 10.1016/j.jlumin.2014.01.028
[5]	Qu, L. J.; Yin, C. X; Huo, F. J.; Li, J. F; Chao, J. B; Zhang, Y. B. Sens. Actuators, B 2014, 195, 246. doi: 10.1016/j.snb.2014.01.026
[6]	Vasilev, A. A.; Baluschev, S.; Cheshmedzhieva, D.; Ilieva, S.; Castano, O. D.; Vaquero, J. J.; Angelova, S. E.; Landfester, K. Aus. J. Chem. 2015, 68, 1399. doi: 10.1071/CH15139
[7]	Girouard, S.; Houle, M. H.; Grandbois, A.; Keillor, J. W.; Michnick, S. W. J. Am. Chem. Soc. 2005, 127, 559. doi: 10.1021/ja045742x
[8]	Khosravi, A.; Moradian, S.; Gharanjig, K.; Afshar, F. T. J. Chin. Chem. Soc. 2005, 52, 495. doi: 10.1002/jccs.v52.3
[9]	Alexiou, M. S.; Tyman, J. H. P. J. Chem. Res. Miniprint 2000, 5, 632.
[10]	Costi, M. P.; Tondi, D.; Rinaldi, M.; Barlocco, D.; Cignarella, G.; Santi, D. V.; Musiu, C.; Pudu, I.; Vacca, G.; Colla, P. L. Eur. J. Med. Chem. 1996, 31, 1011. doi: 10.1016/S0223-5234(97)86180-6
[11]	Cui, L.; Peng, Z. X.; Ji, C. F.; Huang, J. H. Huang, D. T.; Ma, J.; Zhang, S. P.; Qian, X. H.; Xu, Y. F. Chem. Commun. 2014, 50, 1485. doi: 10.1039/C3CC48304E
[12]	Zhou, J; Fang, C. L; Liu, Y; Zhao, Y; Zhang, N; Liu, X. J.; Wang, F. Y.; Shangguan, D. H. Org. Biomol. Chem. 2015, 13, 3931. doi: 10.1039/C5OB00302D
[13]	Wang, J. F; Jin, S.; Akay, S.; Wang, B. H. Eur. J. Med. Chem., 2007, 13, 2091.
[14]	Yuan, D. W; Brown, R. G.; Hepworth, J. D.; Alexiou, M. S.; Tyman, J. H. P. J. Heterocycl. Chem. 2008, 45, 397. doi: 10.1002/jhet.v45:2
[15]	Li, X. M; Zheng, Y. J; Tong, H. J; Qian, R.; Zhou, L.; Liu, G. X; Tang, Y.; Li, H.; Lou, K. Y.; Wang, W. Chem.-Eur. J. 2016, 27, 9247.

Compd.	λ_max/nm	ε/(10³ L• mol^－¹•cm^－¹)	Compd.	λ_max/nm	ε/(10³ L• mol^－¹•cm^－¹)	Compd.	λ_max/nm	ε/(10³ L• mol^－¹•cm^－¹)	Compd.	λ_max/nm	ε/(10³ L• mol^－¹•cm^－¹)
4a	353	10.78	5a	436	13.60	6a	338	17.20	6a＋Cys	348	16.25
4b	352	10.86	5b	436	21.15	6b	346	16.10	6b＋Cys	366	9.60
4c	352	7.64	5c	434	11.40	6c	338	17.85	6c＋Cys	344	15.90
4d	350	11.29	5d	437	13.70	6d	353	9.00	6d＋Cys	351	7.45
4e	354	14.85	5e	441	10.15	6e	354	9.75	6e＋Cys	355	8.55
4f	352	13.70	5f	436	10.55	6f	352	7.10	6f＋Cys	351	5.70
4g	354	13.50	5g	437	8.10	6g	344	9.55	6g＋Cys	348	10.60
4h	355	12.60	5h	440	18.40	6h	346	7.30	6h＋Cys	344	8.20
4i	354	4.45	5i	434	10.85	6i	347	10.80	6i＋Cys	347	8.30
4j	354	8.90	5j	436	12.10	6j	344	12.25	6j＋Cys	349	13.30
4k	354	11.95	5k	437	9.65	6k	344	15.85	6k＋Cys	348	14.60
4l	356	12.70	5l	438	10.75	6l	348	13.20	6l＋Cys	349	12.10
4m	354	11.45	5m	437	8.80	6m	364	15.05	6m＋Cys	364	15.90
4n	353	13.45	5n	437	12.15	6n	348	14.25	6n＋Cys	354	14.20
4o	357	14.15	5o	438	15.15	6o	345	13.35	6o＋Cys	359	13.10
4p	357	13.80	5p	437	19.25	6p	345	12.40	6p＋Cys	345	11.15
4q	359	11.90	5q	437	17.10	6q	345	10.45	6q＋Cys	365	9.70
4r	352	8.75	5r	437	30.25	6r	342	12.15	6r＋Cys	359	10.55
4s	353	5.10	5s	436	7.55	6s	341	9.05	6s＋Cys	340	8.65

Compd.	λ_max/nm	ε/(10³ L• mol^－¹•cm^－¹)	Compd.	λ_max/nm	ε/(10³ L• mol^－¹•cm^－¹)	Compd.	λ_max/nm	ε/(10³ L• mol^－¹•cm^－¹)	Compd.	λ_max/nm	ε/(10³ L• mol^－¹•cm^－¹)
4a	353	10.78	5a	436	13.60	6a	338	17.20	6a＋Cys	348	16.25
4b	352	10.86	5b	436	21.15	6b	346	16.10	6b＋Cys	366	9.60
4c	352	7.64	5c	434	11.40	6c	338	17.85	6c＋Cys	344	15.90
4d	350	11.29	5d	437	13.70	6d	353	9.00	6d＋Cys	351	7.45
4e	354	14.85	5e	441	10.15	6e	354	9.75	6e＋Cys	355	8.55
4f	352	13.70	5f	436	10.55	6f	352	7.10	6f＋Cys	351	5.70
4g	354	13.50	5g	437	8.10	6g	344	9.55	6g＋Cys	348	10.60
4h	355	12.60	5h	440	18.40	6h	346	7.30	6h＋Cys	344	8.20
4i	354	4.45	5i	434	10.85	6i	347	10.80	6i＋Cys	347	8.30
4j	354	8.90	5j	436	12.10	6j	344	12.25	6j＋Cys	349	13.30
4k	354	11.95	5k	437	9.65	6k	344	15.85	6k＋Cys	348	14.60
4l	356	12.70	5l	438	10.75	6l	348	13.20	6l＋Cys	349	12.10
4m	354	11.45	5m	437	8.80	6m	364	15.05	6m＋Cys	364	15.90
4n	353	13.45	5n	437	12.15	6n	348	14.25	6n＋Cys	354	14.20
4o	357	14.15	5o	438	15.15	6o	345	13.35	6o＋Cys	359	13.10
4p	357	13.80	5p	437	19.25	6p	345	12.40	6p＋Cys	345	11.15
4q	359	11.90	5q	437	17.10	6q	345	10.45	6q＋Cys	365	9.70
4r	352	8.75	5r	437	30.25	6r	342	12.15	6r＋Cys	359	10.55
4s	353	5.10	5s	436	7.55	6s	341	9.05	6s＋Cys	340	8.65

Compd.	λ_Ex/nm	λ_Em/nm	Hight^b	Compd.	λ_Ex/nm	λ_Em/nm	Hight^b	Compd.	λ_Ex/nm	λ_Em/nm	Φ_F^a/%
5a	440	537	214.2	6a	274	328	67.6	6a＋Cys	378	468	9.06
5b	440	537	200.7	6b	272	328	171.0	6b＋Cys	372	472	—^c
5c	276	327	167.0	6c	273	326	182.0	6c＋Cys	372	470	—^c
5d	440	536	213.5	6d	280	310	28.7	6d＋Cys	378	470	11.36
5e	440	537	191.8	6e	280	310	33.9	6e＋Cys	370	467	12.56
5f	440	538	149.6	6f	370	472	66.6	6f＋Cys	375	468	16.32
5g	270	327	75.62	6g	270	324	60.2	6g＋Cys	370	465	—^c
5h	257	340	209.0	6h	280	310	36.7	6h＋Cys	370	468	0.18
5i	440	539	83.35	6i	273	325	72.3	6i＋Cys	371	468	—^c
5j	438	540	135.7	6j	280	310	33.1	6j＋Cys	380	469	1.52
5k	440	538	119.6	6k	280	310	29.6	6k＋Cys	370	471	1.50
5l	440	536	167.8	6l	370	466	48.7	6l＋Cys	370	468	19.25
5m	442	540	97.3	6m	280	310	34.8	6m＋Cys	370	459	—^c
5n	440	538	85.3	6n	280	310	32.6	6n＋Cys	370	468	11.89
5o	280	311	36.3	6o	280	311	34.1	6o＋Cys	370	470	8.26
5p	440	542	105.9	6p	280	310	35.2	6p＋Cys	372	466	6.71
5q	440	540	161.4	6q	280	310	35.2	6q＋Cys	370	470	17.89
5r	440	538	98.6	6r	280	310	36.8	6r＋Cys	370	462	—^c
5s	440	542	35.0	6s	280	310	36.3	6s＋Cys	370	309	0.13

Compd.	λ_Ex/nm	λ_Em/nm	Hight^b	Compd.	λ_Ex/nm	λ_Em/nm	Hight^b	Compd.	λ_Ex/nm	λ_Em/nm	Φ_F^a/%
5a	440	537	214.2	6a	274	328	67.6	6a＋Cys	378	468	9.06
5b	440	537	200.7	6b	272	328	171.0	6b＋Cys	372	472	—^c
5c	276	327	167.0	6c	273	326	182.0	6c＋Cys	372	470	—^c
5d	440	536	213.5	6d	280	310	28.7	6d＋Cys	378	470	11.36
5e	440	537	191.8	6e	280	310	33.9	6e＋Cys	370	467	12.56
5f	440	538	149.6	6f	370	472	66.6	6f＋Cys	375	468	16.32
5g	270	327	75.62	6g	270	324	60.2	6g＋Cys	370	465	—^c
5h	257	340	209.0	6h	280	310	36.7	6h＋Cys	370	468	0.18
5i	440	539	83.35	6i	273	325	72.3	6i＋Cys	371	468	—^c
5j	438	540	135.7	6j	280	310	33.1	6j＋Cys	380	469	1.52
5k	440	538	119.6	6k	280	310	29.6	6k＋Cys	370	471	1.50
5l	440	536	167.8	6l	370	466	48.7	6l＋Cys	370	468	19.25
5m	442	540	97.3	6m	280	310	34.8	6m＋Cys	370	459	—^c
5n	440	538	85.3	6n	280	310	32.6	6n＋Cys	370	468	11.89
5o	280	311	36.3	6o	280	311	34.1	6o＋Cys	370	470	8.26
5p	440	542	105.9	6p	280	310	35.2	6p＋Cys	372	466	6.71
5q	440	540	161.4	6q	280	310	35.2	6q＋Cys	370	470	17.89
5r	440	538	98.6	6r	280	310	36.8	6r＋Cys	370	462	—^c
5s	440	542	35.0	6s	280	310	36.3	6s＋Cys	370	309	0.13

1,8-萘酰亚胺衍生物的设计、合成及其对半胱氨酸的识别研究