Nelson Nathaniel C, Wong Kendrew K, Mahoney Ian J, Malik Tahir, Rudym Darya, Lesko Melissa B, Qayum Seema, Lewis Tyler C, Chang Stephanie H, Chan Justin C Y, Geraci Travis C, Li Yonghua, Pamar Prerna, Schnier Joseph, Singh Rajbir, Collazo Destiny, Chang Miao, Kyeremateng Yaa, McCormick Colin, Borghi Sara, Patel Shrey, Darawshy Fares, Barnett Clea R, Sulaiman Imran, Kugler Matthias C, Brosnahan Shari B, Singh Shivani, Tsay Jun-Chieh J, Wu Benjamin G, Pass Harvey I, Angel Luis F, Segal Leopoldo N, Natalini Jake G
Division of Pulmonary, Critical Care, and Sleep Medicine, Department of Medicine, New York University Grossman School of Medicine, New York, New York.
Division of Pulmonary, Critical Care, and Sleep Medicine, Department of Medicine, New York University Grossman School of Medicine, New York, New York; NYU Langone Transplant Institute, NYU Langone Health, New York, New York.
J Heart Lung Transplant. 2025 Mar;44(3):422-434. doi: 10.1016/j.healun.2024.11.006. Epub 2024 Nov 17.
Lower airway enrichment with oral commensals has been previously associated with severe primary graft dysfunction (PGD) after lung transplantation (LT). We aimed to determine whether this dysbiotic signature is present across all PGD severity grades and whether it is associated with a distinct host inflammatory endotype.
Lower airway samples from 96 LT recipients were used to evaluate the lung allograft microbiota via 16S rRNA gene sequencing. Bronchoalveolar lavage (BAL) cytokine concentrations and cell differential percentages were compared across PGD grades. In a subset of samples, we evaluated the lower airway host transcriptome using RNA sequencing methods.
Differential analyses demonstrated lower airway enrichment with supraglottic-predominant taxa (SPT) in moderate and severe PGD. Dirichlet multinomial mixtures modeling identified 2 distinct microbial clusters. A greater percentage of subjects with moderate-severe PGD than no PGD were identified within the dysbiotic cluster (C-SPT, 48% and 29%, respectively) though this did not reach statistical significance (p = 0.06). PGD severity associated with increased BAL neutrophil concentration (p = 0.03) and correlated with BAL concentrations of MCP-1/CCL2, IP-10/CXCL10, IL-10, and TNF-α (p < 0.05). Furthermore, signatures of dysbiosis correlated with neutrophils, MCP-1/CCL-2, IL-10, and TNF-α (p < 0.05). C-SPT exhibited differential expression of TNF, SERPINE1, MPO, and MMP1 genes and upregulation of MAPK pathways, host signling associated with neutrophilic inflammation.
Lower airway dysbiosis within the lung allograft is associated with a neutrophilic inflammatory endotype, an immune profile commonly recognized as the hallmark for PGD. These data highlight a putative role of lower airway microbial dysbiosis in the pathogenesis of this syndrome.
肺移植(LT)后下气道共生菌富集先前已被证明与严重原发性移植功能障碍(PGD)有关。我们旨在确定这种生态失调特征是否存在于所有PGD严重程度分级中,以及它是否与一种独特的宿主炎症内型相关。
对96例LT受者的下气道样本进行16S rRNA基因测序,以评估肺移植微生物群。比较不同PGD分级的支气管肺泡灌洗(BAL)细胞因子浓度和细胞分类百分比。在一部分样本中,我们使用RNA测序方法评估下气道宿主转录组。
差异分析表明,在中度和重度PGD中,下气道以声门上优势菌群(SPT)为主。狄利克雷多项混合模型确定了2个不同的微生物簇。中度至重度PGD患者中处于生态失调簇(C-SPT)的比例高于无PGD患者(分别为48%和29%),尽管未达到统计学显著性(p = 0.06)。PGD严重程度与BAL中性粒细胞浓度升高相关(p = 0.03),并与BAL中MCP-1/CCL2、IP-10/CXCL10、IL-10和TNF-α浓度相关(p < 0.05)。此外,生态失调特征与中性粒细胞、MCP-1/CCL-2、IL-10和TNF-α相关(p < 0.05)。C-SPT表现出TNF、SERPINE1、MPO和MMP1基因的差异表达以及MAPK途径的上调,这是与中性粒细胞炎症相关的宿主信号传导。
肺移植同种异体移植物中的下气道生态失调与中性粒细胞炎症内型相关,这是一种通常被认为是PGD标志的免疫特征。这些数据突出了下气道微生物生态失调在该综合征发病机制中的假定作用。
