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呼吸道易感性增加的蛋白质组学风险评分:一项多队列研究

Proteomic Risk Score of Increased Respiratory Susceptibility: A Multi-Cohort Study.

作者信息

Liu Gabrielle Y, Perry Andrew S, Washko George R, Farber-Eger Eric, Colangelo Laura A, Sheng Quanhu, Wells Quinn, Huang Xiaoning, Thyagarajan Bharat, Guan Weihua, Alexandria Shaina J, San José Estépar Raúl, Bowler Russell P, Esposito Anthony J, Khan Sadiya S, Shah Ravi V, Choi Bina, Kalhan Ravi

机构信息

University of California Davis School of Medicine, Division of Pulmonary, Critical Care, and Sleep Medicine, Sacramento, California, United States.

Vanderbilt University Medical Center, Division of Cardiology, Nashville, Tennessee, United States.

出版信息

Am J Respir Crit Care Med. 2024 Sep 10;211(1):64-74. doi: 10.1164/rccm.202403-0613OC.

DOI:10.1164/rccm.202403-0613OC
PMID:39254293
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11755364/
Abstract

RATIONALE

Accelerated decline in lung function is associated with incident COPD, hospitalizations and death. However, identifying this trajectory with longitudinal spirometry measurements is challenging in clinical practice.

OBJECTIVE

To determine whether a proteomic risk score trained on accelerated decline in lung function can assess risk of future respiratory disease and mortality.

METHODS

In CARDIA, a population-based cohort starting in young adulthood, longitudinal measurements of FEV1 percent predicted (up to six timepoints over 30 years) were used to identify accelerated and normal decline trajectories. Protein aptamers associated with an accelerated decline trajectory were identified with multivariable logistic regression followed by LASSO regression. The proteomic respiratory susceptibility score was derived based on these circulating proteins and applied to the UK Biobank and COPDGene studies to examine associations with future respiratory morbidity and mortality.

MEASUREMENTS AND RESULTS

Higher susceptibility score was independently associated with all-cause mortality (UKBB: HR 1.56, 95%CI 1.50-1.61; COPDGene: HR 1.75, 95%CI 1.63-1.88), respiratory mortality (UKBB: HR 2.39, 95% CI 2.16-2.64; COPDGene: HR 1.83, 95%CI 1.33-2.51), incident COPD (UKBB: HR 1.84, 95%CI 1.71-1.98), incident respiratory exacerbation (COPDGene: OR 1.11, 95%CI 1.03-1.20), and incident exacerbation requiring hospitalization (COPDGene: OR 1.18, 95%CI 1.08-1.28).

CONCLUSIONS

A proteomic signature of increased respiratory susceptibility identifies people at risk of respiratory death, incident COPD, and respiratory exacerbations. This susceptibility score is comprised of proteins with well-known and novel associations with lung health and holds promise for the early detection of lung disease without requiring years of spirometry measurements.

摘要

原理

肺功能加速下降与慢性阻塞性肺疾病(COPD)的发生、住院和死亡相关。然而,在临床实践中,通过纵向肺量计测量来识别这种轨迹具有挑战性。

目的

确定基于肺功能加速下降训练的蛋白质组风险评分是否可以评估未来呼吸系统疾病和死亡风险。

方法

在始于青年期的基于人群的队列研究CARDIA中,使用预测的第一秒用力呼气容积(FEV1)百分比的纵向测量值(30年内多达六个时间点)来识别加速下降和正常下降轨迹。通过多变量逻辑回归和套索回归确定与加速下降轨迹相关的蛋白质适体。基于这些循环蛋白得出蛋白质组呼吸易感性评分,并应用于英国生物银行和慢性阻塞性肺疾病基因(COPDGene)研究,以检查与未来呼吸系统发病率和死亡率的关联。

测量与结果

较高的易感性评分与全因死亡率(英国生物银行:风险比[HR] 1.56,95%置信区间[CI] 1.50 - 1.61;COPDGene:HR 1.75,95%CI 1.63 - 1.88)、呼吸死亡率(英国生物银行:HR 2.39,95%CI 2.16 - 2.64;COPDGene:HR 1.83,95%CI 1.33 - 2.51)、新发COPD(英国生物银行:HR 1.84,95%CI 1.71 - 1.98)、新发呼吸加重(COPDGene:比值比[OR] 1.11,95%CI 1.03 - 1.20)以及需要住院治疗的新发加重(COPDGene:OR 1.18,95%CI 1.08 - 1.28)独立相关。

结论

呼吸易感性增加的蛋白质组特征可识别有呼吸死亡、新发COPD和呼吸加重风险的人群。这种易感性评分由与肺健康有已知和新关联的蛋白质组成,有望在无需多年肺量计测量的情况下早期检测肺部疾病。