Synthetic biology and applications of high-adhesion protein materials

LI Quanfei; CHEN Qian; LIU Hao; HE Kundong; PAN Liang; LEI Peng; GU Yi’an; SUN Liang; LI Sha; QIU Yibin; WANG Rui; XU Hong

doi:10.12211/2096-8280.2025-043

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Synthetic biology and applications of high-adhesion protein materials

Invited Review | 更新时间：2025-09-05

- Synthetic biology and applications of high-adhesion protein materials
- Synthetic Biology Journal Vol. 6, Issue 4, Pages: 806-828(2025)
- 作者机构：
  
  1.南京工业大学食品与轻工学院，江苏南京 210009
  2.材料化学工程全国重点实验室，江苏南京 210009
- 作者简介：
- 基金信息：
- DOI：10.12211/2096-8280.2025-043
  CLC： Q816
- Received：08 May 2025，
  
  Revised：2025-07-02，
  
  Published：31 August 2025
- 稿件说明：
移动端阅览
李全飞，陈乾，刘浩，贺坤东，潘亮，雷鹏，谷益安，孙良，李莎，邱益彬，王瑞，徐虹. 高黏性蛋白材料的合成生物学及应用［J］. 合成生物学， 2025， 6（4）： 806-828

LI Quanfei， CHEN Qian， LIU Hao， HE Kundong， PAN Liang， LEI Peng， GU Yi’an， SUN Liang， LI Sha， QIU Yibin， WANG Rui， XU Hong. Synthetic biology and applications of high-adhesion protein materials［J］. Synthetic Biology Journal， 2025， 6（4）： 806-828
李全飞，陈乾，刘浩，贺坤东，潘亮，雷鹏，谷益安，孙良，李莎，邱益彬，王瑞，徐虹. 高黏性蛋白材料的合成生物学及应用［J］. 合成生物学， 2025， 6（4）： 806-828 DOI： 10.12211/2096-8280.2025-043.

LI Quanfei， CHEN Qian， LIU Hao， HE Kundong， PAN Liang， LEI Peng， GU Yi’an， SUN Liang， LI Sha， QIU Yibin， WANG Rui， XU Hong. Synthetic biology and applications of high-adhesion protein materials［J］. Synthetic Biology Journal， 2025， 6（4）： 806-828 DOI： 10.12211/2096-8280.2025-043.

摘要

高黏性蛋白材料因其卓越的生物黏附性和潜在的生物相容性，在生物医用材料和黏合剂领域展现出巨大的应用潜力。然而，传统方式获取的高黏蛋白材料面临诸多挑战，如产量低、结构复杂、难以规模化生产等。合成生物学作为新兴的交叉学科，为解决这些瓶颈提供了创新策略。本综述系统总结了近年来高黏性蛋白材料的生物合成、改性及应用进展，重点突出了合成生物学在解决高黏性蛋白材料产量、可控性以及功能多样性等方面的优势。全面梳理了基因工程实现对贻贝黏蛋白、藤壶胶蛋白和扇贝足丝蛋白等黏附蛋白的精确设计和高效表达，从而克服高黏蛋白材料在产量和可控性方面的限制。同时，综述了这些蛋白材料在生物黏合剂和医用功能涂层方面的独特优势，如贻贝蛋白的湿面黏附性、藤壶胶蛋白的强黏附性以及类弹性蛋白的可调控性。通过合成生物学方法，可以突破高黏蛋白材料在产量、性能和功能方面的限制，加速其在组织工程、表界面改性等领域的应用。最后，总结了当前合成生物学在高黏蛋白材料领域的最新进展和创新点，并展望了其未来的发展方向，为开发高性能、多功能的高黏蛋白材料提供了新的思路和策略。

Abstract

Due to their exceptional bioadhesive properties and potential biocompatibility

high-viscosity protein materials exhibit significant application prospects in the fields of biomedical materials and adhesives. However

traditionally sourced high-viscosity protein materials encounter numerous challenges

including low yields

structural complexity

and difficulties in scaling up production. Synthetic biology

as an emerging interdisciplinary field

offers innovative strategies to address these bottlenecks. This review systematically summarizes recent advances in the biosynthesis

modification

and applications of high-viscosity protein materials

focusing on the advantages of synthetic biology in addressing issues related to the yield

controllability

and functional diversity of these materials. The precise design and efficient expression of adhesive proteins

such as mussel adhesive proteins

barnacle cement proteins

and scallop foot proteins

achieved through genetic engineering

are comprehensively reviewed

demonstrating the overcoming of limitations in the production and controllability of high-viscosity protein materials. Furthermore

the unique advantages of these protein materials in bioadhesives and functional medical coatings

such as the wet adhesion of mussel proteins

the strong adhesion of barnacle cement proteins

and the tunable properties of elastin-like proteins

are summarized. By employing synthetic biology approaches

limitations in the yield

performance

and functionality of high-viscosity protein materials can be overcome

thereby accelerating their application in areas such as tissue engineering and surface modification. Finally

the latest advancements and innovations in the field of synthetic biology for high-viscosity protein materials are summarized

and future development directions are envisioned

offering new ideas and strategies for the development of high-performance

multifunctional high-viscosity protein materials.

关键词

Keywords

references

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