Murdock Benjamin J, Zhou Tingting, Kashlan Samy R, Little Roderick J, Goutman Stephen A, Feldman Eva L
Department of Neurology, University of Michigan, Ann Arbor.
Department of Biostatistics, School of Public Health, University of Michigan, Ann Arbor.
JAMA Neurol. 2017 Dec 1;74(12):1446-1454. doi: 10.1001/jamaneurol.2017.2255.
Amyotrophic lateral sclerosis (ALS) has an immune component, but previous human studies have not examined immune changes over time.
To assess peripheral inflammatory markers in participants with ALS and healthy control individuals and to track immune changes in ALS and determine whether these changes correlate with disease progression.
DESIGN, SETTING, AND PARTICIPANTS: In this longitudinal cohort study, leukocytes were isolated from peripheral blood samples from 35 controls and 119 participants with ALS at the ALS Clinic of the University of Michigan, Ann Arbor, from June 18, 2014, through May 26, 2016. Follow-up visits occurred every 6 to 12 months. Fifty-one participants with ALS provided samples at multiple points. Immune cell populations were measured and compared between control and ALS groups. Surface marker expression of CD11b+ myeloid cells was also assessed. Changes over time were correlated with disease progression using multivariate regression.
The number of immune cells per milliliter of blood and the fold expression of cell surface markers. Multivariate regression models were used to correlate changes in immune metrics with changes on the Revised Amyotrophic Lateral Sclerosis Functional Rating Scale (ALSFRS-R).
Thirty-five controls (17 women [48.6%] and 18 men [51.4%]; mean [SD] age, 63.5 [9.9] years) and 119 participants with ALS (50 women [42.0%] and 69 men [68.0%]; mean [SD] age, 61.4 [11.5] years) were enrolled. Compared with controls, participants with ALS had increased mean (SEM) counts ( × 106/mL) of total leukocytes (4.57 [0.29; 95% CI, 3.94-5.11] vs 5.53 [0.16; 95% CI, 5.21-5.84]), neutrophils (2.87 [0.23; 95% CI, 2.40-3.35] vs 3.80 [0.12; 95% CI, 3.56-4.04]), CD16+ monocytes (0.03 [0.003; 95% CI, 0.02-0.04] vs 0.04 [0.002; 95% CI, 0.03-0.04]), CD16- monocytes (0.25 [0.02; 95% CI, 0.21-0.30] vs 0.29 [0.01; 95% CI, 0.27-0.31]), and natural killer cells (0.13 [0.02; 95% CI, 0.10-0.17] vs 0.18 [0.01; 95% CI, 0.16-0.21]). We also observed an acute, transient increase in a population of CD11b+ myeloid cells expressing HLA-DR, CD11c, and CX3CR1. Finally, early changes in immune cell numbers had a significant correlation with disease progression measured by change in ALSFRS-R score, particularly neutrophils (-4.37 [95% CI, -6.60 to -2.14] per 11.47 × 104/mL [SD, 58.04 × 104/mL] per year) and CD4 T cells (-30.47 [95% CI, -46.02 to -14.94] per -3.72 × 104/mL [SD, 26.21 × 104/mL] per year).
Changes in the immune system occur during ALS and may contribute to the pathologic features of ALS.
肌萎缩侧索硬化症(ALS)存在免疫成分,但既往人体研究未对免疫变化进行长期观察。
评估ALS患者与健康对照个体的外周炎症标志物,追踪ALS患者的免疫变化,并确定这些变化是否与疾病进展相关。
设计、地点和参与者:在这项纵向队列研究中,于2014年6月18日至2016年5月26日期间,从密歇根大学安娜堡分校ALS诊所的35名对照者和119名ALS患者的外周血样本中分离白细胞。每6至12个月进行一次随访。51名ALS患者在多个时间点提供了样本。对对照组和ALS组的免疫细胞群体进行测量和比较。还评估了CD11b⁺髓样细胞的表面标志物表达。使用多变量回归分析时间变化与疾病进展的相关性。
每毫升血液中的免疫细胞数量以及细胞表面标志物的表达倍数。使用多变量回归模型将免疫指标的变化与修订的肌萎缩侧索硬化症功能评定量表(ALSFRS-R)的变化相关联。
纳入35名对照者(17名女性[48.6%]和18名男性[51.4%];平均[标准差]年龄为63.5[9.9]岁)和119名ALS患者(50名女性[42.0%]和69名男性[68.0%];平均[标准差]年龄为61.4[11.5]岁)。与对照组相比,ALS患者的总白细胞平均(标准误)计数(×10⁶/mL)增加(4.57[0.29;95%CI,3.94 - 5.11]对5.53[0.16;95%CI,5.21 - 5.84])、中性粒细胞(2.87[0.23;95%CI,2.40 - 3.35]对3.80[0.12;95%CI,3.56 - 4.04])、CD16⁺单核细胞(0.03[0.003;95%CI,0.02 - 0.04]对0.04[0.002;95%CI,0.03 - 0.04])、CD16⁻单核细胞(0.25[0.02;95%CI,0.21 - 0.30]对0.29[0.01;95%CI,0.27 - 0.31])和自然杀伤细胞(0.13[0.02;95%CI,0.10 - 0.17]对0.18[0.01;95%CI,0.16 - 0.21])。我们还观察到表达HLA-DR、CD11c和CX3CR1的CD11b⁺髓样细胞群体出现急性、短暂增加。最后,免疫细胞数量的早期变化与通过ALSFRS-R评分变化衡量的疾病进展显著相关,尤其是中性粒细胞(每年每11.47×10⁴/mL[标准差,58.04×10⁴/mL]变化-4.37[95%CI,-6.60至-2.14])和CD4 T细胞(每年每-3.72×10⁴/mL[标准差,26.21×10⁴/mL]变化-30.47[95%CI,-46.02至-14.94])。
ALS病程中免疫系统发生变化,可能促使ALS病理特征的形成。