Passive and post-exercise cold-water immersion augments PGC-1α and VEGF expression in human skeletal muscle

All subjects gave written informed consent to participate after details and procedures of the study had been fully explained. All subjects had no history of neurological disease or musculoskeletal abnormality and none was under any pharmacological treatment during the course of the study. All procedures performed in the study were approved by the University Ethics Committee and in accordance with the 1964 Helsinki declaration and its later amendments.

Study 1 examined the impact of post exercise two-legged CWI on these markers of mitochondrial biogenesis and angiogenesis. Following baseline measures, subjects completed an intermittent running protocol followed by CWI or a control condition (seated rest; CONT). Subsequent to this, subjects recovered in a semi-reclined position under normal laboratory temperatures (23 ± 0.5 °C) until 3 h post-exercise. Study 2 examined the impact of passive CWI on PGC-1α and VEGF mRNA expression and protein content. Subjects arrived at the laboratory and underwent a series of resting measures before completing a CWI protocol without prior exercise. Subjects then remained in a semi-reclined position until 6 h had passed whilst various physiological measures were conducted and blood and muscle biopsies were sampled. All trials were conducted under normal laboratory ambient temperatures (23 ± 0.5 °C) and at the same time of day (~9 am start) in order to avoid the circadian variation in internal body temperature. Trials were randomly counterbalanced with at least 1 week between conditions.

Roughly 10–14 days prior to the subjects scheduled test day they underwent a standard incremental treadmill test for determination of maximal oxygen uptake (\(\dot{V}{\text{O}}_{2} \hbox{max}\)). This was completed in Study 1 in order to permit calculation of running speeds required during the intermittent exercise protocol and in Study 2 for population purposes. Briefly, the protocol commenced at a treadmill speed of 10 km h⁻¹ for 4-min followed by 2-min stages at 12, 14 and 16 km.h⁻¹, respectively. Upon completion of the 16 km h⁻¹ stage the treadmill incline was increased by 2 % every 2-min thereafter until volitional exhaustion. The \(\dot{V}{\text{O}}_{2} \hbox{max}\) was only achieved by reaching the following end point criteria: (1) heart rate (HR) within 10 beats min⁻¹ of age-predicted maximum, (2) respiratory exchange ratio (RER) >1.1, and (3) plateau of oxygen uptake (\(\dot{V}{\text{O}}_{2}\)) despite increased workload.

Test day preparation and baseline measurements were similar for both studies. On the morning of testing subjects arrived at the laboratory following an overnight fast having refrained from exercise, alcohol, tobacco and caffeine for 72 h. All subjects recorded nutritional and fluid intake prior to the first exercise trial to permit them to repeat their preparation for the remaining trial. Subjects were instructed to ingest 5 ml of water per kg of body mass 2 h before arriving at the laboratory. Nude body mass (KG; Seca, Birmingham, UK) was measured before subjects rested for 30 min in a semi-reclined position. Baseline measures of HR (Polar RS400, Polar Electro, Kempele, Finland), \(\dot{V}{\text{O}}_{2}\) (Jaeger Oxycon Pro, Carefusion, Leibnizstrasse, Germany), and skin and rectal temperature (CTF 9004, Ellab) were taken at this point.

Muscle temperature was assessed using a technique previously described (Mawhinney et al. 2013). Briefly, a needle thermistor (13050; Ellab, Rodovre, Denmark) was inserted into the vastus lateralis. Thigh skinfold thickness was measured using Harpenden skinfold callipers (HSK BI; Baty International, West Sussex, UK) and divided by 2 to determine the thickness of the thigh subcutaneous fat layer over each participant’s vastus lateralis. The needle thermistor was then placed at a depth of 3 cm, plus one-half of the skinfold measurement, for the determination of deep muscle temperature. After stabilisation of temperature the thermistor was withdrawn at increments of 1 cm for the determination of muscle temperature at 2 and 1 cm below the subcutaneous layer. Core temperature was assessed via a rectal thermistor (MRV-55044-A, Ellab, Roedovre, Denmark) self-inserted 10–15 cm beyond the anal sphincter. Skin temperature probes were attached to the lateral upper thigh and medial calf (MHF-18050-A, Ellab) using adhesive surgical tape.

Venous blood samples were drawn from a superficial vein in the anti-cubital crease of the forearm using standard venepuncture techniques (Vacuatiner Systems, Becton, Dickinson, Europe). Samples were collected into vacutainers (Becton, Dickinson) containing EDTA or serum separation tubes and stored on ice or at room temperature (serum samples, ~1 h) until centrifugation at 1500 rev min⁻¹ for 15-min at 4 °C. Following centrifugation, aliquots of plasma and serum were stored at −80 °C for later analysis. Samples from both studies were analysed for blood glucose and lactate using commercially available kits (Randox Laboratories, Antrim, UK). Plasma adrenaline and noradrenaline concentrations (Study 2 only) were measured using liquid chromatography-tandem mass spectrometry (Peaston et al. 2010). All samples were analysed in duplicate.

Muscle biopsies were obtained from the vastus lateralis muscle under local anaesthesia (0.5 % marcaine) using a Pro-Mag 2.2 biopsy gun (MD-TECH, Manan Medical Products, Northbrook, IL, USA) as previously described (Morton et al. 2009). Each incision was anaesthetised individually and occurred at a distance of 2–3 cm from the previous incision. Once obtained, samples (~50 mg of tissue) were immediately frozen in liquid nitrogen and stored at −80 °C for later analysis. The biopsied limb was counterbalanced for leg dominance between trials, in both studies. The incision was protected using butterfly closure sterile strips and waterproof adhesive dressings.

Real-time RT-PCR Total RNA was isolated from muscle biopsies (20–30 mg) using Trizol reagent (Invitrogen), according to the manufacturer’s protocol. RNA quality and quantity were determined using Implen Nanophotometer (Implen, Munchen, Germany) and the RNA was stored at −80 °C. cDNA was synthesised using random hexamers (Applied Biosystems) and Superscript III enzyme (Invitrogen), using manufacturer’s protocol. Gene specific expression data was obtained using probes selected from Human Universal Probe Library (Roche Diagnostics) with compatible oligonucleotide primers (MWG Eurofins), except for VEGF₁₆₅ for which Green technology was applied. One microliter of each cDNA sample was analysed in triplicate with negative controls using AB 7500 Real-Time Quantitative PCR instrument (Applied Biosystems) and Agilent Brilliant II qPCR Master Mix with Low ROX (Agilent Technologies). One microliter of cDNA, 500 nM of primer and 200 nM of probe were used for each 20-μl reaction. Primers were designed to detect for PGC-1α (Forward: CAAGCCAAACCAACAACTTTATCTCT, Reverse: ACGACCAAATCCGTTGACTC; Probe 60), VEGF (Forward: CCT TGCTGCTCTACCTCCAC, Reverse: CCACTTCGTGATGATTCTGC; Probe 29), VEGF₁₆₅ (Forward: TGTGAATGCAGACCAAAGAAAGA, Reverse: TGCTTTCTCCGCTCTGAGC) and GAPDH (Forward: GCTCTCTGCTCCTCCTGTTC, Reverse: ACGACCAAATCCGTTGACTC; Probe 60). The following cycling parameters were used: 50 °C for 2 min, initial denaturation at 95 °C for 10 min, followed by 40 cycles of denaturation at 95 °C for 15 s and annealing/elongation at 60 °C for 1 min. For SYBR green reactions additional post-qPCR melting curve analysis was also performed for QC-purposes. Data was collected and analysed using AB SDS 1.43 Software (Applied Biosystems, Foster City, USA). Changes in mRNA content were calculated according to the 2-ΔΔCt method where GAPDH was used as the housekeeping gene. In order determine the optimum housekeeping gene(s) GAPDH, β2M and β-actin pre-tests were run on all samples to ensure no variability between time points. The use of GAPDH as a single reference gene was used due to variability in other housekeeping genes (β2M and β-actin).

Western blotting Approximately 20–30 mg of frozen muscle was ground to powder and homogenised in 120 µl of ice cold lysis buffer [25 mM Tris/HCl (pH 7.4), 50 mM NaF, 100 mM NaCl, 5 mM EGTA, 1 mM EDTA, 10 mM Na-Pyrophosphatase, 1 mM Na₃VO₄, 0.27 M sucrose, 1 % Triton X-100, 0.1 % 2-mercaptoethanol] and supplemented with a protease inhibitor tablet (Complete mini, Roche Applied Science, West Sussex, UK). Homogenates were centrifuged at 14,000g for 10-min at 4 °C and the supernatant was collected. The protein content of the supernatant was determined using a bicinchoninic acid assay (Sigma, UK). Each sample was diluted with an equal volume of 2X Laemmli buffer (National Diagnostics, USA) and boiled for 5-min at 100 °C. For each blot, a standard and internal control was loaded along with 50 µg of protein from each sample and then separated in Tris–glycine running buffer (10 X Tris/Glycine, Geneflow Ltd, Staffordshire, UK) using self-cast 4 % stacking and 10 % separating gels (National Diagnostics, USA). Gels were transferred semi-dry onto nitrocellulose membrane (Geneflow Ltd, Staffordshire, UK) for 2 h at 200 V and 45 mA per gel in transfer buffers (anode 1; 0.3 M Tris, 20 % methanol, pH 10.4; anode 2; 0.25 M Tris, 20 % methanol, pH 10.4; cathode; 0.4 M 6-amino hexanoic acid, 20 % methanol, pH 7.6). After transfer, membranes were blocked for 1 h at room temperature in Tris-buffered saline (TBST: 0.19 M Tris pH 7.6, 1.3 M NaCl, 0.1 %Tween-20) with 5 % non-fat milk. The membranes were then washed for 3 × 5-min in TBST before being incubated overnight at 4 °C with specific protein total content antibodies; GAPDH (Cell Signalling, UK), VEGF (Santa Cruz Biotechnology, Germany) and PGC-1α (Calbiochem, Merck Chemicals, UK) all at concentrations of 1:1000 in 1 X TBST. The next morning, membranes were washed for a further 3 × 5-min in TBST and subsequently incubated with anti-species horseradish peroxidise-conjugated secondary antibody (Bio-Rad, UK or Dako, UK) for 1 h at room temperature. After a further 3 × 5-min washes in TBST, membranes were exposed in a chemiluminescence liquid (SuperSignal, Thermo Fisher Scientific, Rockford, IL, USA) for 5-min. Membranes were visualised using a Bio-Rad Chemi-doc system, and band densities were determined using ImageLab image-analysis software. In order to ensure the antibodies used in each study were specific to the protein of interest, a secondary control was run on every gel.

Physiological responses during exercise and recovery are presented in Table 1. Exercise HR and RPE were similar between CONT and CWI conditions (P > 0.05). Heart rate significantly increased from the first to final bout under both conditions (CONT, 176 ± 8–183 ± 9 beats min⁻¹; CWI, 179 ± 6–183 ± 7 beats min⁻¹; P < 0.001), with the final exercise bout equating to 94 and 95 % of HR_max in the CONT and CWI conditions respectively. Rating of perceived exertion following the final bout was 19 ± 1 and 20 ± 1 in the CONT and CWI condition respectively. Heart rate during CWI showed a significant increase (P < 0.05) in the first 2 min of immersion before returning to baseline values. \(\dot{V}{\text{O}}_{2}\) increased above pre-immersion levels in the 2nd and 6th minute of CWI (P < 0.05), whilst values in CONT remained stable throughout. Additionally, subjective measures of shivering showed significant increases in CWI (2nd and 8th minutes only; P < 0.05) with subjects reporting slight shivering. No differences were detected elsewhere (P > 0.05; Table 1). Blood glucose and lactate concentrations were similar between conditions pre-exercise, increasing in both CONT and CWI immediately after exercise (P < 0.05; except for glucose CONT post P = 0.07). Decreases were seen 1 h post-exercise in both conditions (P > 0.05) and remained unchanged at 3 h post exercise (Table 2).

Rectal temperature was similar between conditions throughout the experimental protocol (P > 0.05). Rectal temperature declined throughout immersion and the post-immersion recovery period with the greatest decrement observed at 3 h post-exercise in both conditions (P < 0.001). Post exercise thigh and calf skin temperatures were similar between conditions. CWI induced significant declines (P < 0.05) in thigh and calf temperatures compared to CONT, with the largest reduction (~16 °C CWI vs. CONT) occurring at the end of CWI. CONT temperatures remained relatively stable throughout the immersion and post-immersion recovery periods whilst thigh and calf skin temperatures remained significantly lower in CWI throughout the 3 h post-exercise period (P < 0.05; Fig. 1; Tcalf data not shown). Muscle temperature (3 cm depth) was similar between conditions immediately post-immersion (P > 0.05). Muscle temperature decreased during the 3 h post exercise period in both conditions with greater decreases in CWI compared with CONT at 1 h and 3 h post-exercise decreases (P < 0.05; Fig. 1).

Post-exercise PGC-1α mRNA remained similar to pre-exercise under both conditions (P > 0.05). However, PGC-1α mRNA increased in both CONT (~3.4-fold; P < 0.001) and CWI (~5.9-fold; P < 0.001) at 3 h post-exercise with a greater increase observed in CWI (P < 0.001) (Fig. 2). No change in total protein content of PGC-1α when expressed relative to GAPDH was observed at any time point in CONT or CWI conditions (P > 0.05) (Fig. 4). VEGF_total mRNA did not change immediately after exercise in both conditions (P > 0.05). However, VEGF_total mRNA increased after CWI only (~2.4-fold) compared with CONT (~1.1-fold) at 3 h post-exercise (P < 0.01). Post exercise VEGF₁₆₅ remained similar to pre-exercise under both conditions (P > 0.05). However, there was a trend for VEGF₁₆₅ to increase after 3 h post-exercise after CWI (~2.5-fold) compared with CONT (~1.4-fold; P = 0.06) (Fig. 2). No change in total protein content of VEGF when expressed relative to GAPDH was observed at any time point in CONT or CWI conditions (P > 0.05) (Figs. 3, 4).

Passive CWI had no impact on rectal temperature, however, it was able to induce significant decreases in 3 cm muscle temperature immediately post immersion and up to 3 h post-exercise (P < 0.05). Skin temperature (thigh and calf) showed peak decreases of ~15 °C by the end of the immersion period, gradually warming throughout the recovery period yet always remaining lower than pre-immersion values (P < 0.05) (Fig. 1; Tcalf values not shown).

Consistent with study 1, HR showed an initial cold shock response with significant increases in the first 2-mins of CWI (P < 0.001) before returning, and remaining, at levels similar to pre-immersion. \(\dot{V}{\text{O}}_{2}\) was elevated above resting values throughout CWI (significantly at 6 and 8 min; P = 0.03 and 0.04, respectively) before returning to pre-immersion values by 10 min. Despite a drop in \(\dot{V}{\text{O}}_{2}\) below pre-immersion values at 20-mins post-immersion (P = 0.05) by 30-mins post-exercise \(\dot{V}{\text{O}}_{2}\) had returned to baseline. Subjective measures of shivering indicated ‘slight shivering’ during the CWI protocol only (P = 0.01). No shivering was reported in the immediate recovery period (30 min) (P < 0.05) (Table 1). Blood glucose, lactate and plasma adrenaline were unchanged from baseline values throughout the immersion and recovery periods (P > 0.05). Plasma noradrenaline was significantly increased at 3 and 6 h post immersion (P < 0.01) (Fig. 3).

After CWI, PGC-1α mRNA content was significantly increased ~1.3-fold and 1.4-fold at 3 h (P = 0.001) and 6 h (P = 0.0004), respectively. No changes were observed in PGC-1α protein content (P = 0.25). Similarly, VEGF₁₆₅ mRNA was significantly increased after CWI ~1.9-fold at 3 h (P = 0.03) and 2.2-fold at 6 h (P = 0.009) post-immersion (Fig. 2). However, there were no changes in VEGF_total mRNA (P = 0.33) and VEGF protein content (P = 0.97) during the post-immersion period. Representative Western Blots are shown in Fig. 4.