第38卷第5期 吉林大学学报(医学版) Vol. 38 No.5
2012年9月 Journal of Jilin University (Medicine Edition) sep.2012
持续高剂量电磁辐射对小鼠外周血免疫细胞数量影响的长期效应
张怡堃1,李慧2,黄根山2,董波3,苏振涛3
(1.第二炮兵总医院血液科,北京100088; 2.总装司令部黄寺门诊部,北京100021;
3.军事医学科学院放射与辐射医学研究所,北京100850)
【摘要】
目的:观察慢性持续高剂量电磁辐射照射后小鼠外周血免疫细胞数量及比例变化,探讨慢性持续高剂量电磁辐射对小鼠免疫系统的影响。
方法:采用随机、平行对照分组法,将30只雄性Balb/c小鼠平均分为正常对照组、10mW·cm-2辐照组及环磷酰胺给药组,每组10只。辐照组动物予以30 min·d-1、每周辐照5d,持续4周;给药组在辐照组开始辐照时给药,每次每只30 mg·kg-1,共7次;各组小鼠于辐照结束后30,45,60,75,90,105和120d分别采集尾静脉血,应用流式细胞术检测外周血中CD4+ T细胞、CD8+ T细胞、CD4+/CD8+比率、CD49+ N细胞数量及比例的变化。
结果: 经持续高剂量电磁辐射后,小鼠的外周血白细胞数量显著上升,CD4+他细胞数量于辐照后75 d后开始明显升高,辐照后90d开始下降但仍高于正常组(P<0.05),观察周期结束时,CD4+ T细胞数量下降到与正常组相同(120d),CD8+T细胞数量于辐照后75d明显降低,直到观察周期结束时(120d),T细胞的数量恢复至与正常组的T细胞数量相同;CD4+/CD8+比率在持续高剂量电磁辐射诱导下呈上升趋势,并且明显高于正常对照组(P<0.05);CD49+ NK细胞数量在辐射明显低于正常对照组(P<0.05)。
结论:慢性、持续性大剂量电磁辐射可导致小鼠免疫系统的紊乱,通过检测外周血中CD4+T细胞、CD8+T细胞、CD4+/CD8+T细胞、CD49+ NK细胞数量及比例的变化,可了解辐照后机体的免疫状态。
【关键词】电磁辐射;免疫细胞;小鼠,近交BALB/C
【中图分类5】 R 358.4
【文献标志码】A
【文章编号】1671-587X(2012)05-0856-05
Long-term effects of lasting and high-dose electromagnetic Radiation on peripheral blood immune cells in mice
ZHANG Yi-kun1,Li Hui2,HUANG Gen-shan2,DONG Bo2,SU Zhen-tao3
(1. Department of Hematology,General Hospital of PLA Second Artillery Forces, Beijing 100088,China;
2. Huangsi Out-patient Department,General Equipment Department Headquarters,Beijing 100021,China;
3. Institute of Radiation Medicine,Academy of Military Medical Sciences,Beijing 100850,China)
Abstract: Objective
To study the long-term effects of lasting and high-dose electromagnetic radiation on number and percent of peripheral immune cells in mice and explore the influence of the lasting and high-dose electromagnetic radiation in murine immune system. Methods
Thirty BALB/c mice were randomly divided into control group,CTX group and irradiation group. The mice in irradiation group were exposed to electromagnetic radiation at the power density of 10 mW·cm-2,30 min a day,for 5 consecutive days every week,lasting for 4 weeks. the mice in CTX group were fed with CTX with the concentration of 30 mg·kg-1,for seven times. The number and percents of CD4+ T cells,CD8+T cells,CD4+/CD8+、CD49+ NK cells in peripheral blood cells were detected 30,45,60,75,90,105 and 120 d after electromagnetic radiation.
Results
After high-dose electromagnetic radiation,the number of WBC was increased obviously(P<0.05).The number of CD4+ T cells was increased on the 75th day(P<0.05)and began to decrease on the 90th day,while the number was much more than that in control group(0 mW·cm-2). Until the 120th day,the number of T cells was as the same as the control. After the long term effect of lasting and high-dose electromagnetic radiation, the number of CD8+ T cells was decreased,and from the 90th day to the 120th day the number of T cells became normal (P<0.05). The ratio of CD4+/CD8+ and the number of CD49+NK cells were lower than those in control group after irradiation(P<0.05)
Conclusion
Chronic,persistent large doses of electromagnetic radiation can lead to immune system disorders,through detecting the changes in the number of peripheral blood CD4+ T cells,CD8+ T cells,CD49+ NK cells and the proportion of CD4+/CD8+,the immune status of mice after irradiation can be found.
Key words: electromagnetic radiation;immune cells;mice,inbred BALBC
电磁污染己成为新的环境污染因素,其对人群的健康威胁日益凸显[1-2]。近来国内外报道:在电磁辐射超出卫生标准的作业环境中的人群,发生神经症状、行为能力下降、免疫功能减弱和血液细胞突变的几率增加,提示应当重视该人群的健康追踪研究[3-4]。高剂量电磁辐射对生物的损伤效应的研究取得了一定的进展[5-6]。但是电磁辐射对人体淋巴细胞免疫活性的影响及进而产生的远期效应尚无定论[7-8]。因此,本研究拟建立高剂量电磁辐射的动物研究模型,通过检测辐照后小鼠外周血中免疫细胞数量及比例的变化,初步探讨电磁辐射对免疫系统的损伤以及损伤程度与辐照剂量之问的关系,为深入研究电磁辐射的生物效应提供借鉴。
1材料与方法
1. 1主要仪器及试剂
辐射源由军事医学科学院放射与辐射医学研究所提供,流式细胞仪(BD pharmingen公司,美国),MEK-7222K全自动血细胞分析仪(日本光电工业株式会社,日本),高速冷冻离心机(德国Heraeus贺力氏),台式高速离心机(上海安亭科学仪器厂)。肝素、FITC
anti-mouse CD3ε抗体、APC anti-mouse CD8a抗体、PE anti-mouse CD4抗体和PE anti-mouse CD49b抗体(BioLegend公司,美国)。
1. 2实验动物及分组
30只雄性Balb/c小鼠,6~8周龄,体质量(20 ± 2)g,由军事医学科学院动物实验中心提供[BASK-(军)2007-004],30只小鼠随机分为正常对照组、环磷酰胺CTX 及辐照组共3组,每组10只。
1. 3照射及给药处理
小鼠供试前在清洁动物房中适应性喂养1周,动物基本状态良好即开始实验。辐照组小鼠接受照射,照射剂10mW·cm-2,每天照射30min,连续4周;给药组小鼠,每次每只给予CTX30 mg·kg-1,7次;正常对照组放置于电磁辐射室外未接受照。
1. 4小鼠外周血象白细胞的检测
将小鼠固定于小鼠固定器,在尾静脉的中下1/3尾静脉,采50uL,静脉血置于己抗凝的(EDTA-K2)的EP管中,混匀,吸出20uL,加到2ml稀释液中,加入对应的荧光抗体,在室温下避光孵育15min,加500uL红细胞溶解素,室温避光孵育10min,1500r·min离心5min,弃上清,加1mLPBS洗细胞重悬细胞,1500r.min离心5min,弃上清,加300uL0. 5%多聚甲醛的PBS重悬细胞,混匀后利用流式细胞仪检测白细胞的总数。
1.5小鼠外周血免疫细胞的检测
取小鼠外周血约500ul,置于肝素抗凝的EP管中。依据外周血WBC计数,按照抗体所需标准量分别加入anti-mouse CD4抗体0. 625ul常温避光,孵育30 min。按比例加入红细胞裂解液NH4Cl-NaHCO3液,振荡混匀,常温避光,孵育15min,溶血。加PBS终止溶血,离心,1700 r·min-1×5 min,弃上清,后再用PBS洗涤细胞2遍,1700 r·min-1 × 5 min,离心,弃上清,用250 μl PBS重悬细胞,加入250 μl 4%多聚甲醛混匀后利用流式细胞仪进行分析,检测CD4+ T细胞、CD8+ T细胞的数量,计算CD4+/CD8+比例。
1. 6观察指标
各实验组均于照射后30,45,60,75,90,105和120 d于尾静脉的中下1/3处采静脉血,取10 μl抗凝血至1.5ml EP管中,加入10 μl 1:50倍稀释大鼠血清10 μl封闭Fc受体,加入1:300稀释的anti-CD49单抗(1 mg ·L-1) 10 μl,避光标记15 min,加入FACS专用裂解液200 μl,充分混匀,避光室温作用5 min应用流式细胞仪检测淋巴细胞表面标志CD49+。
1. 7统计学分析
使用Chiss 2005统计学软件进行统计学分析,CD4+ T细胞、CD8+ T细胞、CD4+/CD8+比率等指标以
± s表示,多组间样本均数比较采用单因素方差分析。
2结果
2.1电磁辐射对小鼠体温的影响
为排除电磁辐射的热效应而检测其生物效应,于辐照前后检测小鼠肛温的变化,对于肛温变化≤1℃的小鼠进行生物效应的检测。照射组10只小鼠肛温度变化均小于1℃。
2.2持续高剂量电磁辐射作用下小鼠外周血白细胞总数的变化
慢性持续高剂量的电磁辐射后,与正常对照组及环磷酰胺组比较,辐照组小鼠外周血白细胞总数在检测时间内显著降低(P<0.05)。见表1。
表1 各组小鼠外周血白细胞总数的变化 Tab 1 Changes of the number of white blood cells in peripheral blood of the mice in various groups . |
Group
| No. of white blood cells |
30 | 45 | 60 | 75 | 90 | 105 | 120 |
control | 14.00±2.84 | 17.68±2.31 | 10.26±2.00 | 16.48±5.00 | 4.30±0.97△ | 25.61±6.69 | 28.59±7.17 |
CTX | 15.07±2.65 | 13.13±3.30* | 10.43±3.07 | 19.91±6.32 | 7.58±1.29 | 20.04±5.06* | 25.82±4.67 |
Irradiation | 5.84±3.35** | 13.14±2.60* | 10.81±3.29 | 13.50±2.49△ | 4.54±1.46△ | 14.78±3.14 | 24.84±5.21 |
| *P<0.05 compared with control group; △P<0.05 compared with CTX group. |
2.3持续高剂量电磁辐射诱导小鼠外周血CD4+ T细胞数量的变化
电磁辐射后,与正常对照组比较,照射组小鼠外周血淋巴细胞CD4+ T细胞数量均明显升高;与环磷酰组比较,在照射后75 d及105 d CD4+ T细胞数量升高,且差异有统计学意义(P<0.05)。见表2。
表2 各组小鼠外周淋巴细胞CD4+ T细胞数量的变化 Tab 2 Changes of the number of lymphocytes CD4+ T cells in peripheral blood of the mice in various groups . |
Group | NO. of CD4+ T cells |
| 60 | 75 | 90 | 105 | 120 |
control | 32.05±7.15 | 36.69±6.59 | 33.16±5.51 | 35.13±2.62△ | 24.20±8.94 |
CTX | 31.82±3.95 | 34.01±4.99 | 33.00±3.16 | 27.28±2.57 | 24.95±3.49 |
Irradiation | 33.65±5.75 | 42.92±5.31* | 35.85±2.48 | 36.61±4.49△ | 23.77±4.85 |
| *P<0.05 compared with control group; △P<0.05 ;△△P<0.01 compared with CTX group. |
2.4持续高剂量电磁辐射诱导小鼠外周血CD8+ T细胞数量的变化
电磁辐射后,与对照组比较,辐照组小鼠淋巴细胞CD8+ T细胞数量显著下降;与加药组比较,辐照组小鼠在照射后60,75及105 d CD8+ T细胞数量明显降低,各组之间比较差异均有统计学意义(P<0.05)见表3
表3 各组小鼠外周血淋巴细胞CD8+ T细胞数量的变化 Tab 3 Changes of the number of lymphocytes CD8+ T cells in peripheral blood of the mice in various groups (n=10,x±s) |
Group | NO. of CD8+ T cells |
(t/d)60 | 75 | 90 | 105 | 120 |
control | 67.95±7.15 | 63.31±6.59 | 66.84±5.51 | 64.87±2.62△ | 75.80±8.94 |
CTX | 68.18±3.95 | 66.00±4.99 | 67.00±3.16 | 72.72±2.57 | 75.05±3.49 |
Irradiation | 66.35±5.75 | 50.08±5.30*△ | 64.15±2.48 | 63.40±4.49△ | 76.23±4.85 |
| *P<0.05 compared with control group; △P<0.05; △△P<0.01 compared with CTX group. |
2. 5持续高剂量电磁辐射诱导小鼠外周血CD4+/CD8+比值的变化
电磁辐射后,辐照组血淋巴细胞绝对值呈上升趋势,辐照后75 d及105d辐照组与对照组相比显著上升(P<0.05)见表4
表4 各组小鼠外周血淋巴细胞CD4+/CD8+比值的变化 Tab 4 Changes of therations of CD4+/ CD8+ in peripheral blood of the mice in various groups . |
Group | CD4+/ CD8+ |
(t/d)60 | 75 | 90 | 105 | 120 |
control | 0.49±0.16 | 0.59±0.17 | 0.50±0.13 | 0.54±0.06 | 0.33±0.16 |
CTX | 0.47±0.09 | 0.52±0.12 | 0.49±0.07 | 0.37±0.05 | 0.33±0.06 |
Irradiation | 0.52±0.13 | 1.02±0.24*△ | 0.56±0.06 | 0.58±0.12 | 0.32±0.08 |
| *P<0.05 compared with control group; △P<0.05 compared with CTX group. |
2. 6持续高剂量电磁辐射诱导小鼠外周血CD49+ NK细胞数量的变化
电磁辐射后与正常对照组比较,辐照组小鼠淋巴细胞CD49+ NK细胞数量明显降低(P<0.05),表明小鼠免疫系统出现紊乱。见表5。
| 表5 各组小鼠外周血CD49+ T细胞数量的变化 Tab 5 Changes of number of CD49+ T cells in peripheral blood of the mice in various groups . |
Group | NO. of CD49+ T cells |
| 90 | 105 | 120 |
control | 32.44±4.59 | 19.76±2.75 | 13.65±2.67 |
CTX | 36.44±1.97 | 24.38±4.23 | 20.15±2.88* |
Irradiation | 22.93±2.24*△ | 15.68±1.71△ | 13.93±2.05 |
| *P<0.05 compared with control group; △P<0.05 compared with CTX group. |
3讨论
本研究采用随机、平行以及独立的动物实验方法,系统建立了慢性高剂量电磁照射小鼠模型,检测10 mW·cm-2大功率辐照对小鼠外周血免疫细胞的影响。为排除热效应的干扰,采用间断暴露[3]的方法,最终测定小鼠肛温在照射前后基本没有变化,保证实验研究的非热效应;同时,在实验过程中采用共同饲养、辐照,检测时分别采集动物样品,排除感染、疾病等生物学效应对血象的影响,保证实验结果具有良好的稳定性及重复性。
慢性高剂量密度电磁辐射对小鼠外周血免疫细胞的影响主要表现在CD4+ T,CD8+ T细胞以及CD4+/CD8+比值的变化。本研究结果显示:电磁辐射后小鼠外周血淋巴细胞CD4+ T细胞数量高于正常对照组,与对照组相比较,照射后75和105d淋巴细胞CD4+ T细胞数量增高,差异有统计学意义;电磁辐射后,辐照组小鼠淋巴细胞CD8+ T细胞数量与对照组相比显著下降,在照射后60,75及105 dCD8+ T细胞数量明显低于给药组;电磁辐射后辐照组外周血淋巴细胞CD4+/CD8+绝对值呈上升趋势,且明显高于正常对照组,在照射后75及105 d照射组高于正常对照组。本研究结果表明:慢性高剂量电磁辐射可导致小鼠外周血淋巴细胞数降低,外周血淋巴细胞CD4+/CD8+比值有所增大,在检测周期结束时小鼠外周血淋巴细胞数有恢复的趋势,提示去除高剂量辐射后,小鼠机体的免疫细胞数量可逐渐恢复。
综上所述,慢性大功率电磁辐射对生物体的免疫系统具有一定程度的损伤效应[9],但该方面研究目前还处于基础研究阶段,需要与辐射后小鼠的组织病理损伤、造血干细胞的变化情况相结合,从而进行更深入、系统的研究。
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