Tetrahedral framework nucleic acid–based small-molecule inhibitor delivery for ecological prevention of biofilm

Yuhao Liu; Kechen Li; Weijie Zhuang; Lulu Liang; Xiangyi Chen; Dongsheng Yu

doi:10.1111/cpr.13678

Cell Proliferation ›› 2024, Vol. 57 ›› Issue (9) : e13678 DOI: 10.1111/cpr.13678

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Tetrahedral framework nucleic acid–based small-molecule inhibitor delivery for ecological prevention of biofilm

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Abstract

Biofilm formation constitutes the primary cause of various chronic infections, such as wound infections, gastrointestinal inflammation and dental caries. While preliminary achievement of biofilm inhibition is possible, the challenge lies in the difficulty of eliminating the bactericidal effects of current drugs that lead to microbiota imbalance. This study, utilizing in vitro and in vivo models of dental caries, aims to efficiently inhibit biofilm formation without inducing bactericidal effects, even against pathogenic bacteria. The tetrahedral framework nucleic acid (tFNA) was employed as a delivery vector for a small-molecule inhibitor (smI) specifically targeting the activity of glucosyltransferases C (GtfC). It was observed that tFNA loaded smI in a small-groove binding manner, efficiently transferring it into Streptococcus mutans, thereby inhibiting GtfC activity and extracellular polymeric substances formation without compromising bacterial survival. Furthermore, smI-loaded tFNA demonstrated a reduction in the severity of dental caries in vivo without adversely affecting oral microbial diversity and exhibited desirable topical and systemic biosafety. This study emphasizes the concept of ‘ecological prevention of biofilm’, which is anticipated to advance the optimization of biofilm prevention strategies and the clinical application of DNA nanocarrier-based drug formulations.

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Yuhao Liu, Kechen Li, Weijie Zhuang, Lulu Liang, Xiangyi Chen, Dongsheng Yu. Tetrahedral framework nucleic acid–based small-molecule inhibitor delivery for ecological prevention of biofilm. Cell Proliferation, 2024, 57(9): e13678 DOI:10.1111/cpr.13678

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References

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[1]	ZhengT, JingM, GongT, et al. Regulatory mechanisms of exopolysaccharide synthesis and biofilm formation in Streptococcus mutans. J Oral Microbiol. 2023; 15:2225257.

[2]	ZhangQ, MaQ, WangY, Wu H, ZouJ. Molecular mechanisms of inhibiting glucosyltransferases for biofilm formation in Streptococcus mutans. Int J Oral Sci. 2021; 13:30.

[3]	da SilvaRAG, Afonina I, KlineKA. Eradicating biofilm infections: an update on current and prospective approaches. Curr Opin Microbiol. 2021; 63:117-125.

[4]	BenoitDSW, SimsKR Jr, FraserD. Nanoparticles for oral biofilm treatments. ACS Nano. 2019; 13:4869-4875.

[5]	MukherjeeS, Bassler BL. Bacterial quorum sensing in complex and dynamically changing environments. Nat Rev Microbiol. 2019; 17:371-382.

[6]	WuYK, ChengNC, ChengCM. Biofilms in chronic wounds: pathogenesis and diagnosis. Trends Biotechnol. 2019; 37:505-517.

[7]	TanP, FuH, MaX. Design, optimization, and nanotechnology of antimicrobial peptides: from exploration to applications. Nano Today. 2021; 39:101229.

[8]	LiJ, ChenD, LinH. Antibiofilm peptides as a promising strategy: comparative research. Appl Microbiol Biotechnol. 2021; 105:1647-1656.

[9]	MottaJP, Wallace JL, BuretAG, DeraisonC, Vergnolle N. Gastrointestinal biofilms in health and disease. Nat Rev Gastroenterol Hepatol. 2021; 18:314-334.

[10]	HardyL, CercaN, JespersV, Vaneechoutte M, CrucittiT. Bacterial biofilms in the vagina. Res Microbiol. 2017; 168:865-874.

[11]	Di SommaA, Moretta A, CaneC, CirilloA, DuilioA. Antimicrobial and antibiofilm peptides. Biomolecules. 2020; 10.

[12]	JiangW, WangY, LuoJ, et al. Antimicrobial peptide GH12 prevents dental caries by regulating dental plaque microbiota. Appl Environ Microbiol. 2020; 86.

[13]	LuoY, SongY. Mechanism of antimicrobial peptides: antimicrobial, anti-inflammatory and antibiofilm activities. Int J Mol Sci. 2021; 22.

[14]	RenS, YangY, XiaM, et al. A Chinese herb preparation, honokiol, inhibits Streptococcus mutans biofilm formation. Arch Oral Biol. 2023; 147:105610.

[15]	RenZ, ChenL, LiJ, LiY. Inhibition of Streptococcus mutans polysaccharide synthesis by molecules targeting glycosyltransferase activity. J Oral Microbiol. 2016; 8:31095.

[16]	NijampatnamB, Ahirwar P, PukkanasutP, et al. Discovery of potent inhibitors of Streptococcus mutans biofilm with antivirulence activity. ACS Med Chem Lett. 2021; 12:48-55.

[17]	ChenY, CuiG, CuiY, ChenD, LinH. Small molecule targeting amyloid fibrils inhibits Streptococcus mutans biofilm formation. AMB Express. 2021; 11:171.

[18]	RenZ, CuiT, ZengJ, et al. Molecule targeting glucosyltransferase inhibits Streptococcus mutans biofilm formation and virulence. Antimicrob Agents Chemother. 2016; 60:126-135.

[19]	ZhangZ, LiuY, LuM, et al. Rhodiola rosea extract inhibits the biofilm formation and the expression of virulence genes of cariogenic oral pathogen Streptococcus mutans. Arch Oral Biol. 2020; 116:104762.

[20]	GaoZ, ChenX, WangC, et al. New strategies and mechanisms for targeting Streptococcus mutans biofilm formation to prevent dental caries: a review. Microbiol Res. 2024; 278:127526.

[21]	ZhangT, TianT, LinY. Intrinsic wettability in pristine graphene. Adv Mater. 2022; 34:e2107820.

[22]	WangQ, ChengJ, LiuF, et al. Modulation of cerebrospinal fluid dysregulation via a SPAK and OSR1 targeted framework nucleic acid in hydrocephalus. Adv Sci. 2024; 11:e2306622.

[23]	ChenY, ChenX, ZhangB, et al. DNA framework signal amplification platform-based high-throughput systemic immune monitoring. Signal Transduct Target Ther. 2024; 9:28.

[24]	LiuY, SunY, LiS, et al. Tetrahedral framework nucleic acids deliver antimicrobial peptides with improved effects and less susceptibility to bacterial degradation. Nano Lett. 2020; 20:3602-3610.

[25]	ZhangY, XieX, MaW, et al. Multi-targeted antisense oligonucleotide delivery by a framework nucleic acid for inhibiting biofilm formation and virulence. Nano-Micro Lett. 2020; 12:74.

[26]	ZhangB, QinX, ZhouM, et al. Tetrahedral DNA nanostructure improves transport efficiency and anti-fungal effect of histatin 5 againstCandida albicans. Cell Prolif. 2021; 54:e13020.

[27]	ZhangM, ZhangX, TianT, et al. Anti-inflammatory activity of curcumin-loaded tetrahedral framework nucleic acids on acute gouty arthritis. Bioact Mater. 2022; 8:368-380.

[28]	LiY, CaiZ, MaW, BaiL, LuoE, LinY. A DNA tetrahedron-based ferroptosis-suppressing nanoparticle: superior delivery of curcumin and alleviation of diabetic osteoporosis. Bone Res. 2024; 12:14.

[29]	LiuZ, ChenX, MaW, et al. Suppression of lipopolysaccharide-induced sepsis by tetrahedral framework nucleic acid loaded with quercetin. Adv Funct Mater. 2022; 32:2204587.

[30]	HeJ, ChenW, ChenX, et al. Tetrahedral framework nucleic acid loaded with glabridin: a transdermal delivery system applicated toanti-hyperpigmentation. Cell Prolif. 2023; 56:e13495.

[31]	SirongS, YangC, TaoranT, et al. Effects of tetrahedral framework nucleic acid/wogonin complexes on osteoarthritis. Bone Res. 2020; 8:6.

[32]	XieX, ShaoX, MaW, et al. Overcoming drug-resistant lung cancer by paclitaxel loaded tetrahedral DNA nanostructures. Nanoscale. 2018; 10:5457-5465.

[33]	YanR, CuiW, MaW, LiJ, LiuZ, LinY. Typhaneoside-tetrahedral framework nucleic acids system: mitochondrial recovery and antioxidation for acute kidney injury treatment. ACS Nano. 2023; 17:8767-8781.