Synthetic biology promotes the development of bacterial vaccines

ZHANG Jinyong; GU Jiang; GUAN Shan; LI Haibo; ZENG Hao; ZOU Quanming

doi:10.12211/2096-8280.2023-070

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Synthetic biology promotes the development of bacterial vaccines

Invited Review | 更新时间：2025-03-20

- Synthetic biology promotes the development of bacterial vaccines
- Synthetic Biology Journal Vol. 5, Issue 2, Pages: 321-337(2024)
- 作者机构：
  
  陆军军医大学国家免疫生物制品工程技术研究中心，陆军军医大学药学与检验医学系微生物与生化药学教研室，重庆 400037
- 作者简介：
- 基金信息：
- DOI：10.12211/2096-8280.2023-070
  CLC： Q819
- Received：07 October 2023，
  
  Revised：2023-12-05，
  
  Published：30 April 2024
- 稿件说明：
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章金勇，顾江，关山，李海波，曾浩，邹全明. 合成生物学助力细菌疫苗研发［J］. 合成生物学， 2024， 5（2）： 321-337

ZHANG Jinyong， GU Jiang， GUAN Shan， LI Haibo， ZENG Hao， ZOU Quanming. Synthetic biology promotes the development of bacterial vaccines［J］. Synthetic Biology Journal， 2024， 5（2）： 321-337
章金勇，顾江，关山，李海波，曾浩，邹全明. 合成生物学助力细菌疫苗研发［J］. 合成生物学， 2024， 5（2）： 321-337 DOI： 10.12211/2096-8280.2023-070.

ZHANG Jinyong， GU Jiang， GUAN Shan， LI Haibo， ZENG Hao， ZOU Quanming. Synthetic biology promotes the development of bacterial vaccines［J］. Synthetic Biology Journal， 2024， 5（2）： 321-337 DOI： 10.12211/2096-8280.2023-070.

摘要

细菌感染已成为全球第二大死亡因素，给人类健康与公共安全造成了巨大威胁。抗生素一直是治疗细菌感染最为主要的手段，但越来越严重的耐药问题给传统的抗生素疗法带来了严峻挑战。除了抗生素之外，疫苗被认为是防治传染性疾病传播最为科学、经济、安全和有效的手段，在人类抗击病原体感染斗争中发挥了重要作用。然而，细菌基因组庞大，致病机制复杂，研发疫苗存在有效抗原筛选、设计、制备难，抗原组合配伍难，有效性评价难，研发周期长等诸多瓶颈，导致细菌疫苗研发进展缓慢，尤其是临床常见的严重耐药致病菌尚无有效的疫苗可用。合成生物学是一门新兴的交叉学科，近年来在疫苗研究领域已经得到了广泛应用，包括抗原的筛选、理性设计、配伍组合，载体、佐剂和递送系统的设计以及免疫应答调控等。本文综述了细菌疫苗研究的现状以及耐药细菌疫苗临床试验研究进展，总结了合成生物学技术在几种重要类型细菌疫苗研发中的应用进展，最后对相关前景进行了展望。合成生物学在疫苗的形式、疫苗递送、疫苗的研制效率等方面为研究人员提供了更为广阔的空间，未来，应最大化地发挥合成生物学的优势，充分发展和应用合成生物学技术手段，建立科学、理性、有效、可行的管理制度，建设生物安全保障法律体系和监管措施，高效推动细菌疫苗研发，解决抗生素耐药问题，造福人类健康。

Abstract

In recent years

bacterial infections have emerged as the second leading cause of death globally

posing a serious threat to public health and demanding prioritized intervention from the healthcare community worldwide. While antibiotics have conventionally been used as the primary strategy to combat bacterial infections

their efficacy is increasingly compromised due to the emergence of drug-resistant bacteria

especially multi-drug-resistant and even pan-drug-resistant superbacteria. Vaccines are thus considered as one of the most scientific

economical

safe

and effective means to prevent infectious diseases and improve public health

which are estimated to save 2 to 3 million lives annually

and can serve as a critical tool in the battle against an

timicrobial resistance. However

the complexity of bacterial structure and pathogenic mechanism has hindered the development of vaccines. Challenges include screening and rationally design of effective antigens

ensuring compatibility of various antigen combinations

establishing animal models for preclinical evaluation

and defining reliable endpoints for clinical efficacy assessment. As a result

only a small number of bacteria vaccines have been successfully developed so far

and none of them has been licensed to combat the most prevalent drug-resistant infections

such as

Staphylococcus aureus

Acinetobacter baumannii

Pseudomonas aeruginosa

and

Klebsiella pneumoniae

. Synthetic biology is a brand-new multidisciplinary focusing on repurposing natural biological systems and inventing innovative biological tools

technologies

devices

and systems for practical applications

and its concepts

principles and technologies have been extensively employed to facilitate vaccine development

including rational design

screening

and optimization of antigen

carrier

adjuvant and delivery system as well as the modulation of bacterial pathogenicity and immune responses. Herein

we outline the current status of the development of bacterial vaccines and the advancement of clinical trials for drug-resistant bacterial vaccines. Then

we summarize the application of synthetic biology technology in the development of major bacterial vaccines. Finally

we prospect the potential of synthetic biology in creating novel bacterial vaccines. Researchers have access to a greater variety of design possibilities for bacterial vaccines through synthetic biology. To maximize these benefits

we should employ synthetic biology and related technologies more efficiently in developing bacterial vaccines. Meanwhile

we should develop a scientific

reasonable

effective

and feasible management system

as well as regulatory measures

to expedite the development of efficient bact

erial vaccines

therefore addressing the problem of antibiotic resistance to protect human health.

关键词

Keywords

references

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