Braun Sascha D, Reinicke Martin, Diezel Celia, Müller Elke, Frankenfeld Katrin, Schumacher Thomas, Arends Hugo, Monecke Stefan, Ehricht Ralf
Leibniz Institute of Photonic Technology, Member of the Research Alliance "Leibniz Health Technologies" and the Leibniz Centre for Photonics in Infection Research (LPI), Jena, Germany.
InfectoGnostics Research Campus Jena, Center for Applied Research, Jena, Germany.
Front Microbiol. 2025 Aug 26;16:1650094. doi: 10.3389/fmicb.2025.1650094. eCollection 2025.
Carbapenemase-producing bacteria undermine the efficacy of carbapenems, a class of last-resort antibiotics used primarily to treat infections caused by multidrug-resistant Gram-negative pathogens. Carbapenemases are among the most alarming antimicrobial resistance mechanisms because they inactivate all β-lactam antibiotics leaving clinicians with few or no therapeutic options. The genes encoding these enzymes are typically located on mobile genetic elements (MGE), which facilitate rapid horizontal gene transfer among different bacterial species. These MGE's often additionally carry toxin-antitoxin systems that promote long-term persistence in bacterial populations. Carbapenem-resistant (CRE) often colonize the gastrointestinal tract without symptoms, serving as silent reservoirs for further dissemination. Infections caused by CRE are associated with high morbidity and mortality and are frequently resistant to multiple drug classes. Given the urgent clinical need for rapid diagnostics, immunochromatographic assays represent a promising and urgently needed approach for economic and available point-of-care detection. However, the development of such assays is often hindered by the time-consuming process of identifying high-affinity antibody pairs.
To accelerate this process, we evaluated a protein microarray platform as a high-throughput screening tool to identify optimal monoclonal antibody (mAb) pairs targeting the most clinically relevant carbapenemases. Monoclonal antibodies derived from hybridoma libraries and commercial sources were spotted in triplicates and tested in a single experiment against lysates from reference strains expressing the carbapenemase enzymes KPC, NDM, IMP, VIM, OXA-23/48/58, and MCR-1, an enzyme conferring resistance to colistin. Signal intensities were quantified, and diagnostic performance was assessed across four thresholds.
A cut-off > 0.2 yielded the best balance, with approximately 61% balanced accuracy and ≥99% specificity. Around 22% of tested antibodies showed strong, reproducible reactivity. For several targets-such as KPC, IMP, VIM, OXA-58, and MCR-1-100% sensitivity was achieved. The array allowed simultaneous mapping of cross-reactivity, a key advantage over conventional ELISA workflows.
Our findings confirm that protein-based microarrays offer a robust, efficient platform for antibody pair selection, reducing reagent use while accelerating assay development. The validated antibody pairs are directly applicable to ELISA or lateral flow test formats and provide a strong foundation for next-generation diagnostics capable of detecting an evolving panel of carbapenemases in clinical settings.
产碳青霉烯酶细菌会削弱碳青霉烯类抗生素的疗效,碳青霉烯类是一类主要用于治疗由多重耐药革兰氏阴性病原体引起的感染的最后一道防线抗生素。碳青霉烯酶是最令人担忧的抗菌耐药机制之一,因为它们会使所有β-内酰胺类抗生素失活,导致临床医生几乎没有或根本没有治疗选择。编码这些酶的基因通常位于可移动遗传元件(MGE)上,这有助于在不同细菌物种之间快速进行水平基因转移。这些MGE通常还携带毒素-抗毒素系统,可促进在细菌群体中的长期存活。耐碳青霉烯类(CRE)细菌通常无症状地定殖于胃肠道,成为进一步传播的隐匿储存库。由CRE引起的感染与高发病率和死亡率相关,并且通常对多种药物类别耐药。鉴于临床对快速诊断的迫切需求,免疫层析测定法是一种有前景且迫切需要的方法,可用于经济且可现场使用的即时检测。然而,此类测定法的开发常常受到识别高亲和力抗体对这一耗时过程的阻碍。
为了加速这一过程,我们评估了一种蛋白质微阵列平台作为高通量筛选工具,以识别针对临床上最相关的碳青霉烯酶的最佳单克隆抗体(mAb)对。将源自杂交瘤文库和商业来源的单克隆抗体一式三份点样,并在一次实验中针对表达碳青霉烯酶KPC、NDM、IMP、VIM、OXA-23/48/58和MCR-1(一种赋予对黏菌素耐药性的酶)的参考菌株的裂解物进行测试。对信号强度进行定量,并在四个阈值下评估诊断性能。
截止值>0.2产生了最佳平衡,平衡准确率约为61%,特异性≥99%。约22%的测试抗体显示出强的、可重复的反应性。对于几个靶点,如KPC、IMP、VIM、OXA-58和MCR-1,实现了100%的灵敏度。该阵列允许同时绘制交叉反应性图谱,这是优于传统ELISA工作流程的一个关键优势。
我们的研究结果证实,基于蛋白质的微阵列提供了一个强大、高效的抗体对选择平台,减少了试剂使用,同时加速了测定法的开发。经过验证的抗体对可直接应用于ELISA或侧向流动检测形式,并为能够在临床环境中检测不断变化的碳青霉烯酶组的下一代诊断方法提供了坚实基础。
