Changes in microbial composition during flue-cured tobacco aging and their effects on chemical composition: a review

Yangyang Yu; Yongfeng Yang; Tao Jia; Hang Zhou; Yao Qiu; Mengyao Sun; Hongli Chen

doi:10.1186/s40643-025-00883-8

Bioresources and Bioprocessing ›› 2025, Vol. 12 ›› Issue (1) : 43 DOI: 10.1186/s40643-025-00883-8

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Changes in microbial composition during flue-cured tobacco aging and their effects on chemical composition: a review

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Abstract

The aging is a crucial stage in tobacco processing, which contributes to the reduction of impurities and irritation, and the stabilization of the internal chemical composition of the leaves. However, it usually takes a long time (2–3 years) for the nature aging process of tobacco (20 °C–30 °C, relative humidity of 65–75%), which seriously affects the processing efficiency of tobacco. Microorganisms play an important role in the change of chemical composition and characteristic aromatic substances of tobacco. Acinetobacter, Sphingomonas Aspergillus, Bacilli, and Pseudonocardia is the main microorganism in the aging process of tobacco, which increasing the aromatic substances (such as alcohols, ketones, and esters) by the action of the enzymes and metabolites, and degrade the harmful components (such as alkaloid, nicotine and nitrosamines in tobacco). This review systematically summarizes recent advancements in understanding the primary microbial composition and the changes in chemical composition during tobacco aging. This knowledge is helpful for screening functional strains, and control the process of tobacco aging by the inoculation of these strains.

Keywords

Aging / Aroma components / Chemical composition / Microorganism / Tobacco

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Yangyang Yu, Yongfeng Yang, Tao Jia, Hang Zhou, Yao Qiu, Mengyao Sun, Hongli Chen. Changes in microbial composition during flue-cured tobacco aging and their effects on chemical composition: a review. Bioresources and Bioprocessing, 2025, 12(1): 43 DOI:10.1186/s40643-025-00883-8

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References

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[1]	AriharaK, ZhouL, OhataM. Bioactive properties of Maillard reaction products generated from food protein-derived peptides. Adv Food Nutr Res, 2017, 81: 161-185

[2]	AtawodiSE, RichterE. Bacterial reduction of N-oxides of tobacco- specific nitrosamines (TSNA). Hum Exp Toxicol, 2016, 15: 329-334

[3]	BanozicM, JokicS, AckarD, BlazicM, SubaricD. Carbohydrates-key players in tobacco aroma formation and quality determination. Molecules, 2020, 25: 1734

[4]	ChattopadhyayS, RamachandranP, MalayilL, MongodinEF, SapkotaAR. Conventional tobacco products harbor unique and heterogenous microbiomes. Environ Res, 2023, 220: 115205

[5]	ChenG, ChenC, LeiZ. Meta-omics insights in the microbial community profiling and functional characterization of fermented foods. Trends Food Sci Technol, 2017, 65: 23-31

[6]	ChenY, RenK, HeX, GongJ, HuX, SuJ, JinY, ZhaoZ, ZhuY, ZouC. Dynamic changes in physiological and biochemical properties of flue-cured tobacco of different leaf ages during fluecuring and their effects on yield and quality. BMC Plant Biol, 2019, 19: 1-21

[7]

ChopykJ, ChattopadhyayS, KulkarniP, SmythEM, HittleLE, PaulsonJN, PopM, BuehlerSS, ClarkPI, MongodinEF, SapkotaAR. Temporal variations in cigarette tobacco bacterial community composition and tobacco-specific nitrosamine content are influenced by brand and storage conditions. Front Microbiol, 2017, 8: 358

[8]	DaiJ, DongA, XiongG, LiuY, HossainMS, LiuS, GaoN, LiS, WangJ, QiuD. Production of highly active extracellular amylase and cellulase from Bacillus subtilis ZIM3 and a recombinant strain with a potential application in tobacco fermentation. Front Microbiol, 2020, 11: 1539

[9]	DanX, HuangZ, JinzhongX, YameiJ, YishengC, LunanG, ZhengyuJ, XuemingX. Improving bread aroma using low-temperature sourdough fermentation. Food Biosci, 2020, 37: 100704-100704

[10]	Di GiacomoM, PaolinoM, SilvestroD, VigliottaG, ImperiF, ViscaP, AlifanoP, ParenteD. Microbial community structure and dynamics of dark fire-cured tobacco fermentation. Appl Environ Microbiol, 2007, 73: 825-837

[11]	DongX, YuJ, YeC, LiuD, ZouD, HanZ, YuQ, HuangK, LiH, WeiX. Control of tobacco-specific nitrosamines by the Bacillus siamensis: strain isolation, genome sequencing, mechanism analysis and genetic engineering. J Hazard Mater, 2024, 469 ArticleID: 133877

[12]	Espinoza-SánchezEA, Álvarez-HernándezMH, Torres-CastilloJA, Rascón-CruzQ, Gutiérrez-DíezA, Zavala-GarcíaF, Sinagawa-GarcíaSR. Stable expression and characterization of a fungal pectinase and bacterial peroxidase genes in tobacco chloroplast. Electron J Biotechnol, 2015, 18: 161-168

[13]	FanJ, KongG, YaoH, WuY, ZhaoG, LiF, ZhangG. Widely targeted metabolomic analysis reveals that volatile metabolites in cigar tobacco leaves dynamically change during fermentation. Biochem Biophys Rep, 2023, 35: 101532-101532

[14]	FengY, YuanQ, YangZ, TingtingZ, LiuX, ChenggangL, WangE, MaS, ZhangZ. Effect of Sphingomonas sp. strain on degradation of polyphenols in redried tobacco leaves. Acta Tabacaria Sin, 2019, 25: 19-24

[15]	FisherMT, BennettCB, HayesA, KargaliogluY, KnoxBL, XuD, Muhammad-KahR, GaworskiCL. Sources of and technical approaches for the abatement of tobacco specific nitrosamine formation in moist smokeless tobacco products. Food Chem Toxicol, 2012, 50: 942-948

[16]	GaoY, ZhangY, ZhangS, WangJ, LiangT, YinQ, GuoW. Relationship of carotenoid and its degradation products with sensory quality of flue-cured tobacco of different flavor styles. Tobacco Sci Technol, 2014, 319: 38-43

[17]	GongX-W, YangJ-K, DuanY-Q, DongJ-Y, ZheW, WangL, LiQ-H, ZhangK-Q. Isolation and characterization of Rhodococcus sp. Y22 and its potential application to tobacco processing. Res Microbiol, 2009, 160: 200-204

[18]

HinnehM, SemanhyiaE, Van de WalleD, De WinneA, Tzompa-SosaDA, ScaloneGLL, De MeulenaerB, MessensK, Van DurmeJ, AfoakwaEO, De CoomanL, DewettinckK. Assessing the influence of pod storage on sugar and free amino acid profiles and the implications on some Maillard reaction related flavor volatiles in Forastero cocoa beans. Food Res Int, 2018, 111: 607-620

[19]	HuY, MouD, LiY, WangX, ZhaoY. Study on the relationship between aging time of Yunnan redired lamina and quality. Acta Tabacaria Sin, 2004, 10: 1-7

[20]	HuW, CaiW, ZhengZ, LiuY, LuoC, XueF, LiD. Study on the chemical compositions and microbial communities of cigar tobacco leaves fermented with exogenous additive. Sci Rep, 2022, 12: 19182

[21]	JiaY, NiuCT, LuZM, ZhangXJ, ChaiLJ, ShiJS, XuZH, LiQ. A bottom-up approach to develop a synthetic microbial community model: application for efficient reduced-salt broad bean paste fermentation. Appl Environ Microbiol, 2020, 86 ArticleID: e00306

[22]	JiaY, NiuC-T, LuZ-M, ZhangX, ChaiL, ShiJ-S, XuZ-H, LiQ. A bottom-up approach to develop simplified microbial community model with desired functions: application for efficient fermentation of broad bean paste with low salinity. Appl Environ Microbiol, 2020, 86 ArticleID: e00306

[23]	JiaY, LiuY, HuW, CaiW, ZhengZ, LuoC, LiD. Development of Candida autochthonous starter for cigar fermentation via dissecting the microbiome. Front Microbiol, 2023, 14: 1138877

[24]	LakshmiHP, PrasadUV, YeswanthS, SwarupaV, PrasadOH, NarasuML, SarmaPVGK. Molecular characterization of alpha-amylase from Staphylococcus aureus. Bioinformation, 2013, 9: 281-285

[25]	LawAD, FisherC, JackA, MoeLA. Tobacco, microbes, and carcinogens: correlation between tobacco cure conditions, tobacco-specific nitrosamine content, and cured leaf microbial community. Microb Ecol, 2016, 72: 120-129

[26]	LawlerTS, StanfillSB, ZhangL, AshleyDL, WatsonCH. Chemical characterization of domestic oral tobacco products: total nicotine, pH, unprotonated nicotine and tobacco-specific N-nitrosamines. Food Chem Toxicol, 2013, 57: 380-386

[27]	LiY, HechtSS. Carcinogenic components of tobacco and tobacco smoke: a 2022 update. Food Chem Toxicol, 2022, 165: 113179

[28]	LiH, LiX, DuanY, ZhangK-Q, YangJ. Biotransformation of nicotine by microorganism: the case of Pseudomonas spp. Appl Microbiol Biotechnol, 2010, 86: 11-17

[29]	LiJ, ZhaoY, QinY, ShiH. Influence of microbiota and metabolites on the quality of tobacco during fermentation. BMC Microbiol, 2020, 20: 1-5

[30]	LiX, BinJ, YanX, DingM, YangM. Application of chromatographic technology to determine aromatic substances in tobacco during natural fermentation: a review. Separations, 2022, 9: 187

[31]	LiZ-J, YangD-D, WeiZ-Y, HuangJ, ChiY-Q, LuY-X, YinF-W. Reduction of nicotine content in tobacco through microbial degradation: research progress and potential applications. Biotechnol Biofuels Bioprod, 2024, 17: 144

[32]	LiuJ, MaG, ChenT, HouY, YangS, ZhangK-Q, YangJ. Nicotine-degrading microorganisms and their potential applications. Appl Microbiol Biotechnol, 2015, 99: 3775-3785

[33]	LiuF, WuZ, ZhangX, XiG, ZhaoZ, LaiM, ZhaoM. Microbial community and metabolic function analysis of cigar tobacco leaves during fermentation. Microbiologyopen, 2021, 10 ArticleID: e1171

[34]	LiuZ, CaiS, ZhangS, XiaoY, DevahastinS, GuoC, WangY, WangT, YiJ. A systematic review on fermented chili pepper products: sensorial quality, health benefits, fermentation microbiomes, and metabolic pathways. Trends Food Sci Technol, 2023, 141: 104189

[35]	LvH-P, ZhongQ-S, LinZ, WangL, TanJ-F, GuoL. Aroma characterisation of Pu-erh tea using headspace-solid phase microextraction combined with GC/MS and GC–olfactometry. Food Chem, 2012, 130: 1074-1081

[36]	MengL, SongW, ChenS, HuF, PangB, ChengJ, HeB, SunF. Widely targeted metabolomics analysis reveals the mechanism of quality improvement of flue-cured tobacco. Front Plant Sci, 2022, 13: 1074029

[37]	MuY, ChenQ, ParalesRE, LuZ, HongQ, HeJ, QiuJ, JiangJ. Bacterial catabolism of nicotine: catabolic strains, pathways and modules. Environ Res, 2020, 183: 109258

[38]	MytinovaZ, MotykaV, HaiselD, LubovskaZ, TravnickovaA, DobrevP, HolikJ, WilhelmovaN. Antioxidant enzymatic protection during tobacco leaf ageing is affected by cytokinin depletion. Plant Growth Regul, 2011, 65: 23-34

[39]	NiJ, WuY-T, TaoF, PengY, XuP. A coenzyme-free biocatalyst for the value-added utilization of lignin-derived aromatics. J Am Chem Soc, 2018, 140: 16001-16005

[40]	NingY, ZhangL-Y, MaiJ, SuJ-E, CaiJ-Y, ChenY, JiangY-L, ZhuM-J, HuB-B. Tobacco microbial screening and application in improving the quality of tobacco in different physical states. Bioresour Bioprocess, 2023, 10: 32

[41]	OldhamMJ, DeSoiDJ, RimmerLT, WagnerKA, MortonMJ. Insights from analysis for harmful and potentially harmful constituents (HPHCs) in tobacco products. Regul Toxicol Pharmacol, 2014, 70: 138-148

[42]	PopovaV, IvanovaT, ProkopovT, NikolovaM, StoyanovaA, ZheljazkovV. Carotenoid-related volatile compounds of tobacco (Nicotiana tabacum L.) essential oils. Molecules, 2019, 24: 3446

[43]	Ramos-PinedaAM, CarpenterGH, Garcia-EstevezI, Escribano-BailonMT. Influence of chemical species on polyphenol-protein interactions related to wine astringency. J Agric Food Chem, 2020, 68: 2948-2954

[44]	ReidJJ, McKinstryDW, HaleyDE. The fermentation of cigar-leaf tobacco. Science, 1937, 86: 404-404

[45]	RiveraAJ, TyxRE. Microbiology of the American smokeless tobacco. Appl Microbiol Biotechnol, 2021, 105: 4843-4853

[46]	RoemerE, SchorpMK, PiadeJ-J, SeemanJI, LeydenDE, HaussmannH-J. Scientific assessment of the use of sugars as cigarette tobacco ingredients: a review of published and other publicly available studies. Crit Rev Toxicol, 2012, 42: 244-278

[47]	RuanA, GaoY, FangC, XuY. Isolation and characterization of a novel nicotinophilic bacterium, Arthrobacter sp. aRF-1 and its metabolic pathway. Biotechnol Appl Biochem, 2018, 65: 848-856

[48]	RuanL, MengM, WangC, HouL. Draft genome sequence of Candida versatilis and osmotolerance analysis in soy sauce fermentation. J Sci Food Agric, 2019, 99: 3168-3175

[49]	SarlakS, LalouC, AmoedoND, RossignolR. Metabolic reprogramming by tobacco-specific nitrosamines (TSNAs) in cancer. Semin Cell Dev Biol, 2020, 98: 154-166

[50]	SlaghenaufiD, PerelloM-C, MarchandS, de RevelG. Quantification of megastigmatrienone, a potential contributor to tobacco aroma in spirits. Food Chem, 2016, 203: 41-48

[51]	SuC, GuW, ZheW, ZhangK-Q, DuanY, YangJ. Diversity and phylogeny of bacteria on Zimbabwe tobacco leaves estimated by 16S rRNA sequence analysis. Appl Microbiol Biotechnol, 2011, 92: 1033-1044

[52]	Tamayo A, Cancho F (1953) Microbiology of the fermentation of Spanish tobacco. In: International Congress of Microbiology. pp 48–53

[53]	TangH, YaoY, WangL, YuH, RenY, WuG, XuP. Genomic analysis of Pseudomonas putida: genes in a genome island are crucial for nicotine degradation. Sci Rep, 2012, 2: 377

[54]	VigliottaG, Di GiacomoM, CarataE, MassardoDR, TrediciSM, SilvestroD, PaolinoM, PontieriP, Del GiudiceL, ParenteD, AlifanoP. Nitrite metabolism in Debaryomyces hansenii TOB-Y7, a yeast strain involved in tobacco fermentation. Appl Microbiol Biotechnol, 2007, 75: 633-645

[55]	WahlbergI, KarlssonK, AustinDJ, JunkerN, RoeraadeJ, EnzellCR, JohnsonWH. Effects of flue-curing and ageing on the volatile, neutral and acidic constituents of Virginia tobacco. Phytochemistry, 1977, 16: 1217-1231

[56]	WangS, LiuZ, XuP. Biodegradation of nicotine by a newly isolated Agrobacterium sp. strain S33. J Appl Microbiol, 2009, 107: 838-847

[57]	WangW-L, XuS-Y, RenZ-G, TaoL, JiangJ-W, ZhengS-S. Application of metagenomics in the human gut microbiome. World J Gastroenterol, 2015, 21: 803-814

[58]	WangJ, YangH, ShiH, ZhouJ, BaiR, ZhangM, JinT. Nitrate and nitrite promote formation of tobacco-specific nitrosamines via nitrogen oxides intermediates during postcured storage under warm temperature. J Chem, 2017, 2017: 6135215

[59]	WangF, ZhaoH, XiangH, WuL, MenX, QiC, ChenG, ZhangH, WangY, XianM. Species diversity and functional prediction of surface bacterial communities on aging flue-cured tobaccos. Curr Microbiol, 2018, 75: 1306-1315

[60]	WangY, WangD, GaoZ, JiangZ, XiY, FangM, LiuC, DuC. Changes of carotenoid degradation products and their relationship with sensory quality during natural alcoholization of flue-cured tobacco. J Zhejiang Agric Sci, 2020, 16: 340-344

[61]	WangF, JinY, ChenX, ZhangY, JiangX, ZhangG, ChenG, YangM, LengF, LiH, WuL, ZhangH. The diversity, structure and function of microbial communities changes across aging process of tobacco leaves. Environ Res Commun, 2022, 4: 095012

[62]	WangX, McClementsDJ, XuZ, MengM, QiuC, LongJ, JinZ, ChenL. Recent advances in the optimization of the sensory attributes of fried foods: appearance, flavor, and texture. Trends Food Sci Technol, 2023, 138: 297-309

[63]	WeeksW, CamposM, MoldoveanuS. Pyrolysis of cherry red tobacco and 1-Deoxy-1-[(S)-2-(3-pyridyl)-1-pyrrolidinyl]-.beta.-d-fructose (pyranose and furanose isomers) amadori products of cherry red tobacco. J Agric Food Chem, 1995, 43: 2247-2253

[64]	WeiX, DengX, CaiD, JiZ, WangC, YuJ, JiJ, ChenS. Decreased tobacco-specific nitrosamines by microbial treatment with Bacillus amyloliquefaciens DA9 during the air-curing process of burley tobacco. J Agric Food Chem, 2014, 62: 12701-12706

[65]	WisemanKD, CornacchioneJ, WagonerKG, NoarSM, MoraccoKE, TealR, WolfsonM, SutfinEL. Adolescents' and young adults' knowledge and beliefs about constituents in novel tobacco products. Nicotine Tob Res, 2016, 18: 1581-1587

[66]	WuL, LiuW, CaoJ, LiQ, HuangY, MinS. Analysis of the aroma components in tobacco using combined GC-MS and AMDIS. Anal Methods, 2013, 5: 1259-1263

[67]	WuX, ZhuP, LiD, ZhengT, CaiW, LiJ, ZhangB, ZhuB, ZhangJ, DuG. Bioaugmentation of Bacillus amyloliquefaciens Bacillus kochii co-cultivation to improve sensory quality of flue-cured tobacco. Arch Microbiol, 2021, 203: 5723-5733

[68]	WuX, CaiW, ZhuP, PengZ, ZhengT, LiD, LiJ, ZhouG, DuG, ZhangJ. Profiling the role of microorganisms in quality improvement of the aged flue-cured tobacco. BMC Microbiol, 2022, 22: 197

[69]	XuX, ZhangX, HuTW, MillerLS, XuM. Effects of global and domestic tobacco control policies on cigarette consumption per capita: an evaluation using monthly data in China. BMJ Open, 2019, 9 ArticleID: e025092

[70]	XuefengZ, WenshuiX, QixingJ, YanshunX, JingF. Contribution of mixed starter cultures to flavor profile of Suanyu—a traditional Chinese low-salt fermented whole fish. J Food Process Preserv, 2017, 41: e13131-e13131

[71]	YangY, PengQ, OuM, WuY, FangJ. Research progress in tobacco fermentation. J Biosci Med, 2018, 06: 105-114

[72]	YeJ, YanJ, ZhangZ, YangZ, LiuX, ZhouH, WangG, HaoH, MaK, MaY, MaoD, YangX. The effects of threshing and redrying on bacterial communities that inhabit the surface of tobacco leaves. Appl Microbiol Biotechnol, 2017, 101: 4279-4287

[73]	YuH, TangH, WangL, YaoY, WuG, XuP. Complete genome sequence of the nicotine- degrading Pseudomonas putida strain S16. J Bacteriol, 2011, 193: 5541-5542

[74]	YuY, LiL, XuY, LiH, YuY, XuZ. Metagenomics reveals the microbial community responsible for producing biogenic amines during mustard Brassica juncea (L.) fermentation. Front Microbiol, 2022, 13: 824644

[75]	YulinL, YifeiW, GuozhongZ, YunpingY. Identification of aroma compounds in Zhuhoujiang, a fermented soybean paste in Guangdong China. LWT Food Sci Technol, 2021, 142: 111057-111057

[76]

YuxinH, RuyangC, YulianC, Chi-TangH, AixiangH, XiluZ, MingzhiZ, ChunyanZ, YuanliangW, ZhonghuaL, YuX. Dynamics changes in volatile profile, non-volatile metabolites and antioxidant activities of dark tea infusion during submerged fermentation with Eurotium cristatum. Food Biosci, 2023, 55: 102966-102966

[77]	ZhangL-Y, MaiJ, ShiJ-F, AiK-B, HeL, ZhuM-J, HuB-B. Study on tobacco quality improvement and bacterial community succession during microbial co-fermentation. Ind Crops Prod, 2024, 208 ArticleID: 117889

[78]	ZhaoM, WangB, LiF, QiuL, LiF, WangS, CuiJ. Analysis of bacterial communities on aging flue-cured tobacco leaves by 16S rDNA PCR-DGGE technology. Appl Microbiol Biotechnol, 2007, 73: 1435-1440

[79]	ZhaoL, ZhuC, GaoY, WangC, LiX, ShuM, ShiY, ZhongW. Nicotine degradation enhancement by Pseudomonas stutzeri ZCJ during aging process of tobacco leaves. World J Microbiol Biotechnol, 2012, 28: 2077-2086

[80]	ZhongW, ZhuC, ShuM, SunK, ZhaoL, WangC, YeZ, ChenJ. Degradation of nicotine in tobacco waste extract by newly isolated Pseudomonas sp. ZUTSKD. Biores Technol, 2010, 101: 6935-6941

[81]	ZhouJ, YuL, ZhangJ, ZhangX, XueY, LiuJ, ZouX. Characterization of the core microbiome in tobacco leaves during aging. Microbiologyopen, 2020, 9 ArticleID: e984

[82]	ZhuX, YuanJ, QuH, HouF, MaoC, LeiJ, CaoX, LiL. Effects of different proportions of fruit tree branches on nicotine content and microbial diversity during composting of tobacco waste. J Environ Manag, 2024, 365 ArticleID: 121568

[83]	ZouX, BkA, RaufA, SaeedM, Al-AwthanYS, Al-DuaisMA, BahattabO, KhanMH, SuleriaHAR. Screening of polyphenols in tobacco (Nicotiana tabacum) and determination of their antioxidant activity in different tobacco varieties. ACS Omega, 2021, 6: 25361-25371

[84]	ZouL, SuJ, XuT, JiX, WangT, ChenY, JiangY, QiuJ, ZhangQ, HuB. Untargeted metabolomics revealing changes in aroma substances in flue-cured tobacco. Open Chem, 2023, 21: 20220326