Exercise is capable of inducing apoptosis in immune cells. There are various measurement limitations, particularly relating to the amount of time required to isolate and treat a blood sample prior to the assessment. Demonstrated is a rapid and minimally invasive procedure for the analysis of exercise-induced lymphocyte apoptosis.
Exercise is a physiological stimulus capable of inducing apoptosis in immune cells. To date, various limitations have been identified with the measurement of this phenomenon, particularly relating to the amount of time required to isolate and treat a blood sample prior to the assessment of cell death. Because of this, it is difficult to determine whether reported increases in immune cell apoptosis can be contributed to the actual effect of exercise on the system, or are a reflection of the time and processing necessary to eventually obtain this measurement. In this article we demonstrate a rapid and minimally invasive procedure for the analysis of exercise-induced lymphocyte apoptosis. Unlike other techniques, whole blood is added to an antibody panel immediately upon obtaining a sample. Following the incubation period, red blood cells are lysed and samples are ready to be analyzed. The use of a finger-stick sampling procedure reduces the volume of blood required, and minimizes the discomfort to subjects.
1. Finger-Stick Blood Sampling
2. Cell Phenotyping and Apoptosis Staining
Tube 1 | Tube 2 | Tube 3 | Tube 4 |
Cells only tube | Annexin V – FITC | Annexin V – FITC | Annexin V – FITC |
Anti Human CD4 – PE | Anti Human CD8 – PE | Anti Human CD19 – PE | |
7-AAD | 7-AAD | 7-AAD | |
Anti Human CD45RA – APC | Anti Human CD45RA – APC |
It is recommended that at a minimum, the following controls be utilized: a cells only tube to serve as a negative control in detecting background autofluorescence, and tubes containing each individual fluorochrome to set compensation during initial set up of the flow cytometer. In addition, we have used compensation standard beads successfully to set up our experiments.
A minimally invasive sample collection procedure and subsequent analysis is demonstrated for the analysis of both early and late phases of exercise-induced lymphocyte apoptosis. It is also possible to clearly exclude those cells, which are necrotic, and not apoptotic. This procedure overcomes the drawbacks and discomfort associated with invasive venipuncture from the antecubital region at multiple time points prior to, during, and immediately after exercise, or securing a catheter for the duration of the exercise bout. In terms of the investigators, such procedures typically require specialized training in phlebotomy, which not all individuals have. In addition, subject recruitment and retention is expected to be enhanced using this procedure, thus increasing the potential statistical power of finding a significant effect if one is present.
Previous investigations employing venipuncture blood sampling have reported resting and post-exercise values for overall lymphocytes. Utilizing annexin V, Simpson et al. reported approximately 1.2% apoptotic lymphocytes at rest, and ~1.3% following treadmill running 1. Similarly, Steensberg et al. reported ~1.8% total apoptotic lymphocytes at rest, and approximately 2.1% after 2.5 hours of running 2. Our results for apoptotic lymphocytes using the finger-stick procedure described here are similar, with 0.7±0.2% observed at rest, and 1.1±0.4% post-exercise in five subjects who completed a graded exercise test (unpublished results).
One of the limitations of previous methodology used to determine exercise-induced immune cell death was the amount of time required to process a blood sample. In previous investigations, samples obtained immediately postexercise by venipuncture were subjected to a lengthy isolation and preparation process (as long as 2 h) before eventually being assessed for cell death 3-5. It is reasonable to speculate that such processing delays may artificially elevate reported post-exercise lymphocyte apoptosis values. In some cases, annexin V positive lymphocytes have been reported to be as high as ~25% 6. Further interpretation of this methodological confounder raises the question of whether the reported values for lymphocyte apoptosis were due to exercise or blood processing delays. We suggested that previous methodology did not accurately reflect the effect that exercise has on inducing cell death in immune cells 7.
Utilizing the methodology demonstrated here decreases the amount of blood required for each collection time point. Also, our approach decreases sample-processing time, which may reduce the incidence of false positives for lymphocyte apoptosis. In this protocol, whole blood is added to the antibody panel within 30-seconds after blood collection, thus reducing the potential that lymphocytes progress through the apoptotic process and are eliminated prior to antibody staining. This procedure overcomes the measurement limitations previously discussed, and allows for the quantification of apoptotic lymphocytes induced by exercise as a physiological stimulus. Future study with regards to this methodology should evaluate the potential differences with larger gauge lancets.
In addition, the methodology described in this paper allows for the determination of both early and late stage exercise-induced apoptosis in lymphocyte subsets (see Table 1). Cells stained with Annexin V only are in the early phase of apoptosis, whereas double-staining with Annexin V and 7-AAD indicate progression through the cell death process to the latter stages. Cells marked with 7-AAD alone are indicative of undergoing cell death through necrosis. Phenotyping of lymphocytes is accomplished through cluster of differentiation markers (CD4 = helper T-lymphocytes, CD8 = cytotoxic/suppressor T-lymphocytes, CD45RA = naive subfractions, CD19 = B-lymphocytes).
The authors have nothing to disclose.
This research was supported by a New Faculty Grant from the Faculty Scholarship Council at Western Kentucky University.
Material Name | Typ | Company | Catalogue Number | Comment |
---|---|---|---|---|
Flow Cytometry Binding Buffer | eBioscience | 00-4222-26 | ||
RBC Lysis Buffer | eBioscience | 00-4333-57 | ||
Lancet Device | Accu Check Soft Touch | Roche Diagnostics Corp. | ||
Capillary tubes | Heparinized Capillary Tubes | Chase Scientific Glass, Inc. | 501 | |
Centrifuge | GmC Lab | Gilson | PMS-880 | |
Annexin V-FITC Conjugated | Biovision Inc. | K201-400-1 | ||
CD4-PE Conjugated | Anti-human, clone RPA-T4 | eBioscience | 12-0049-42 | |
CD8-PE Conjugated | Anti-human, clone OKT8 | eBioscience | 12-0086-73 | |
CD19-PE Conjugated | Anti-human, clone HIB19 | eBioscience | 12-0199-42 | |
7-AAD Viability Staining Solution | eBioscience | 00-6993-50 | ||
CD45RA-APC Conjugated | Anti-human, clone HI100 | eBioscience | 17-0458-42 | |
Flow cytometer | C6 | Accuri |