Quillin Sarah J, Luo Di, Gavagan Aoife, Prindle Arthur, Seifert H Steven
Department of Microbiology-Immunology, Northwestern University Feinberg School of Medicine, Chicago, Illinois, USA.
Department of Biochemistry and Molecular Genetics, Northwestern University Feinberg School of Medicine, Chicago, Illinois, USA.
mSphere. 2025 May 27;10(5):e0009425. doi: 10.1128/msphere.00094-25. Epub 2025 Apr 23.
The strict human pathogen (gonococcus [Gc]) infects an estimated 82 million individuals globally and is a World Health Organization-designated bacterial pathogen of public health importance due to escalating antimicrobial resistance. Gc vaccines have been hindered by Gc's ability to evade immune surveillance in part by varying its major surface antigens like the type IV pilus. We developed a quick and precise method for measuring pilin antigenic variation (Av) frequency using droplet digital PCR (ddPCR) technology. Two fluorescent probes were designed to detect either the hypervariable tail region of silent pilin locus 3-copy 1 (S3C1) or a sequence conserved in all variants (CYS2). The appropriate frequency of pilin antigenic variation is measured by the proportion of amplicons carrying the recombinant S3C1 copy relative to the total pilE amplicons measured by CYS2. The ddPCR assay is specific for RecA-dependent pilin antigenic variation. The reduced frequency of pilin Av in strains lacking RecA-modulating recombination protein RecX and the DNA helicase RecQ confirms the ability of the assay to measure changes in pilin Av frequency. We used the ddPCR assay to determine that pilin Av frequency is altered by the colony densities on a solid medium. The ddPCR assay is an accurate, efficient way to measure Gc pilin Av frequency.
Gonorrhea is a sexually transmitted infectious disease of the human genital and nasopharyngeal mucosa caused by the host-restricted bacterium . The rise of antibiotic-resistant gonorrhea is an urgent global threat to public health. Pilus antigenic variation is a gene conversion process that allows to evade host immune surveillance, and a mechanistic understanding of this process is crucial to understanding pathogenesis. This report shows that we can adopt a digital PCR methodology to quickly and accurately measure pilin antigenic variation.
严格的人类病原体(淋球菌[Gc])全球估计感染8200万人,由于抗菌药物耐药性不断升级,它是世界卫生组织指定的具有公共卫生重要性的细菌病原体。Gc疫苗的研发受到阻碍,因为Gc能够通过改变其主要表面抗原(如IV型菌毛)来部分逃避免疫监视。我们开发了一种使用液滴数字PCR(ddPCR)技术快速精确测量菌毛抗原变异(Av)频率的方法。设计了两种荧光探针,分别检测沉默菌毛基因座3拷贝1(S3C1)的高变尾区或所有变体中保守的序列(CYS2)。菌毛抗原变异的适当频率通过携带重组S3C1拷贝的扩增子相对于由CYS2测量的总pilE扩增子的比例来测量。ddPCR检测对RecA依赖性菌毛抗原变异具有特异性。缺乏RecA调节重组蛋白RecX和DNA解旋酶RecQ的菌株中菌毛Av频率降低,证实了该检测方法测量菌毛Av频率变化的能力。我们使用ddPCR检测确定菌毛Av频率会因固体培养基上的菌落密度而改变。ddPCR检测是测量Gc菌毛Av频率的准确、有效方法。
淋病是由宿主限制性细菌引起的人类生殖器和鼻咽部黏膜的性传播传染病。耐抗生素淋病的出现是对全球公共卫生的紧迫威胁。菌毛抗原变异是一个基因转换过程,使细菌能够逃避宿主免疫监视,对这一过程的机制理解对于理解淋病发病机制至关重要。本报告表明,我们可以采用数字PCR方法快速准确地测量菌毛抗原变异。
