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A general scheme of lipoprotein particle isolation
Figure 1 shows the general scheme of lipoprotein particle isolation starting from whole blood, using sequential flotation ultracentrifugation16. If desired, other lipoprotein particle fractions like VLDL and IDL particles can be harvested during this protocol. The fixed-angle titanium rotor in combination with polypropylene quick-seal tubes is suitable to withstand the centrifugation forces. To avoid tube collapse, it is important to avoid air bubbles in the tube. Centrifugation is carried out at 4 °C to minimize protein degradation. Usually starting from plasma (60-80 mL per donor) of pooled blood donations of three volunteers, a yield of LDL and HDL particle solution volumes of 3 mL each with concentrations in the range of 1-3 mg/mL can be expected. The whole procedure, starting from blood donation, took around 7 days.

Figure 1: Flowchart of lipoprotein isolation. Centrifuge blood from healthy volunteers in vacuum container tubes and collect plasma (upper phase). After the adjustment of its density to ρ = 1.019 g/mL using KBr, centrifuge the solution at 214,000 x g for 20 h at 4 °C. After the adjustment of the density of the bottom fraction to ρ = 1.063 g/mL using KBr, centrifuge the solution again at 214,000 x g for 20 h at 4 °C. Store the upper fraction containing LDL particles temporary at 4 °C. After the adjustment of the density of the bottom fraction to ρ = 1.220 g/mL using KBr, centrifuge the solution twice at 214,000 x g for 20 h at 4 °C. Collect the upper fraction containing HDL particles, dialyze both the HDL and LDL particle solutions and exchange the buffer after 1, 2, and 4 h. After 24 h, determine the protein concentration and store the samples under inert gas at 4 °C. Please click here to view a larger version of this figure.
Reconstitution of HDL particles
The reconstitution of HDL particles was performed according to a protocol previously published by Jonas7. The first step was the delipidation of HDL particles as shown in Figure 2A, followed by the second step of relipidation (i.e., reconstitution) as shown in Figure 2B, using lipid PC, CO, and C in addition to a mixture of miRNA and spermine. We chose human mature miR-223 and miR-155 because miR-223 shows a high abundance and miR-155 is rare in lipoprotein particles17. Usually, both steps are performed on two sequential days. During reconstitution, other lipophilic and/or amphiphilic components could be added as desired. The complete evaporation of ethanol/diethyl ether and methanol/chloroform solvent of PC, CO, and C was critical. The last step—as shown in Figure 2C—was the dialysis procedure to separate reconstituted HDL particles (rHDL) from free lipids/miRNA/detergent. This took an additional 1-2 days. The addition of absorbent beads to the dialysis solution kept the density gradient along the dialysis membrane constant. A yield of 50% of rHDL particles can be expected.

Figure 2: Flowchart of HDL particle reconstitution. (A) Delipidation: Mix the HDL particle solution with precooled ethanol/diethyl ether and incubate at -20 °C for 2 h. After discarding the supernatant, resuspend the pellet and repeat the procedure. Dry the pellet with N2 gas and resuspend it in buffer A. After the determination of the concentration, store the delipidated HDL under inert gas atmosphere at 4 °C. (B) Reconstitution: After mixing phosphatidyl-choline (PC), cholesteryl oleate (CO), and cholesterol (C), evaporate the solvent using N2 gas while rotating the tube. Incubate the miRNA aliquot with spermine solution for 30 min at 30 °C, add sodium deoxycholate and resuspend the dried lipid film. Stir the sample for 2 h at 4 °C, add the delipidated HDL solution, and stir the sample again, this time overnight at 4 °C under inert gas atmosphere. (C) Dialysis: Transfer the solution from panel B containing reconstituted HDL (rHDL) particles to a dialysis membrane chamber (molecular weight cut-off: 20 kDa) and dialyze against PBS and absorbent beads at 4 °C. Exchange the buffer and the beads after 1 h and 2 h. Recover the rHDL particle solution after 24 h, determine the concentration, and store the sample under inert gas atmosphere at 4 °C. Please click here to view a larger version of this figure.
Labeling of LDL particles
The labeling of LDL particles with miRNA (Figure 3) as demonstrated for HDL particles was not feasible due to the hydrophobicity of the apoB-100 protein, which is the main constituent of the LDL particle. DMSO was used for the penetration of the lipid monolayer of the LDL particle and, thus, mediated the miRNA association. The whole procedure took 1-2 days with a yield close to 100%.

Figure 3: Flowchart of LDL particle labeling. Incubate the miRNA aliquot with spermine solution for 30 min at 30 °C and add DMSO and LDL buffer. Incubate LDL sample wit LDL buffer for 10 min on ice and add miRNA/spermine/DMSO mixture. After incubation at 40 °C for 2 h, transfer the solution into a dialysis membrane chamber (molecular weight cut-off: 20 kDa) and dialyze against PBS and absorbent beads at +4 °C. Exchange buffer and beads after 1 & 2 h. Recover labeled LDL particle solution after 24 h, determine the concentration and store under inert gas atmosphere at +4 °C. Please click here to view a larger version of this figure.
Quality control of lipoprotein particles
HS-AFM can be used to examine the size and shape of native and reconstituted/labeled lipoprotein particles on mica. Just before use, mica has to be freshly cleaved (use adhesive tape to remove the upper layer[s]) in order to provide a clean and flat surface. When incubating HDL/LDL particles on mica, the dilution factor (and/or the incubation time) needs to be adjusted to observe individual particles. Clusters do not allow a determination of particle dimensions. HDL particles are mobile on mica. When using conventional AFM instead of HS-AFM, the immobilization protocol needs to be adapted accordingly (buffer, surface coating) to reduce the lateral particle mobility. While scanning the sample, the imaging force has to be kept low (tapping mode) to avoid any deformation of the particles, which will consequently affect the measured values. For data analysis, particles were detected via a threshold algorithm (e.g., in Gwyddion: Grains > Mark by threshold) and their height was determined with respect to the mica surface. Measuring the particles’ height is the most precise way to determine particle sizes, as the apparent lateral dimensions are broadened by the tip shape (see exemplary images in Figure 4). Probability density functions (pdfs) of particle heights were calculated for statistical evaluation and comparison of size distributions of the various lipoprotein particles. A comparison of native and miRNA-labeled LDL particles as shown in Figure 4 makes it possible verify the principal similarity between labeled and nonlabeled (i.e., native) lipoprotein particles (labeled LDL particles without the addition of miRNA/spermine mixtures are shown as a control for the labeling procedure itself). The whole procedure took approximately 1 day.

Figure 4: Flowchart and representative results of HS-AFM measurements. Dilute the HDL/LDL particle sample in PBS (1:102-1:103) and incubate it on freshly cleaved mica for 5 min, followed by a careful rinse with PBS to remove free (not electrostatically adsorbed) particles. Perform HS-AFM imaging and check the particle density on the surface. Carry out the measurements in PBS at room temperature. The top image of this figure shows a too high particle density; the bottom image is suitable for analysis. The height of single particles was analyzed after thresholding and native (black curve) and reconstituted/labeled (red and green curve) particles were compared in a statistical evaluation. The scale bar = 100 nm. This figure has been modified from Axmann et al.19. Please click here to view a larger version of this figure.
miRNA extraction, reverse transcription, and qPCR
The extraction of miRNA from native/artificially enriched lipoprotein or cell samples was performed using a miRNA extraction kit as shown in Figure 5A. Hereby, an RNase-free environment was critical. This step took approximately 1 h. Reverse transcription of the extracted miRNA sample (Figure 5B) was performed using standard biochemical procedures as described by the manufacturer. This step took approximately 1.5 h. Finally, the amount of cDNA obtained during the last step was determined using qPCR (Figure 5C). A standard curve, which relates the obtained cq values to the absolute miRNA strand number, yielded the absolute miRNA content of the initial sample. This took approximately 2.5 h.

Figure 5: Flowchart of miRNA extraction, reverse transcription, and qPCR. (A) miRNA extraction: Mix the sample with lysis reagent and lyse it via aspiration using a syringe. Incubate for 5 min and add CHCl3. Shake vigorously for 15 s and incubate for 3 min. After centrifugation at 1,200 x g for 15 min at 4 °C, collect the top phase and mix it with ethanol. Transfer the solution to a spin column (maximum volume <700 µL) and centrifuge it at 8,000 x g for 15 s. Discard the eluent and repeat the last step with the rest of the solution. Add the first washing buffer and centrifuge at 8,000 x g for 15 s. Discard the eluent, add the second washing buffer, and centrifuge at 8,000 x g for 15 s. Repeat the last step with a centrifugation time of 2 min. Further dry the membrane via centrifugation at maximum speed for 1 min. Elute the miRNA with H2O and centrifuge at 80,000 x g for 1 min. Store the extracted miRNA sample at -20 °C. (B) Reverse transcription: Thaw the 10x buffer, H2O, dNTP mix, inhibitor, and enzyme on ice and prepare the master mix. Add the extracted miRNA from panel A to the master mix and the reverse transcription primer and perform reverse transcription using a thermocycler machine. Store the cDNA sample at -20 °C. (C) qPCR: Thaw the supermix, H2O, and primer on ice and prepare the master mix. Add the cDNA from panel B to the master mix and perform qPCR. Analyze the data to obtain cq values and calculate the absolute miRNA content of the sample (see Figure 6 and the representative results for details). Please click here to view a larger version of this figure.
Absolute miRNA content and transfer rate
The absolute miRNA content of native and artificially enriched HDL and LDL particles was calculated from the cq values of the samples and a standard curve of the respective miRNA as shown in Figure 6. Figure 6A shows data as calculated by the analysis software (with activated DynamicTube normalization [for the compensation of different background levels using the second derivative of each sample trace] and Noise slope correction [normalization to the noise level]). cq values of standard curves were determined using the Auto-find threshold function of the software package on the normalized fluorescence signal measured by the qPCR machine. Hereby, the software maximized the R-value of the fit of the standard curve. The threshold level was kept constant for each specific miRNA sample analysis. Subsequently, the cq values were plotted as a function of the number of miRNA strands, and a regression line was calculated. Sample cq values were determined with the same threshold level as shown in Figure 6B; reaction efficiency differences between different qPCR runs were compensated automatically by the software using one additional calibration curve sample included in each run. Using the regression line equation, the unknown amount of miRNA in the sample could be calculated. The lipoprotein particle number was estimated from the initial protein concentration and its average molecular weight (MWHDL ~250 kDa). Thereby, no lipid contribution to the molecular weight was assumed—thus, the number of miRNA strands per lipoprotein particle was slightly overestimated. Moreover, a 100% recovery rate of miRNA during the miRNA extraction step was assumed. Furthermore, the miRNA content of the cells before and after the incubation with HDL particles was determined and the miRNA transfer rate was calculated as shown in Figure 6C.

Figure 6: Flowchart of calculation of the absolute miRNA content and transfer rate. (A) Standard curve for miR-155: A miR-155 aliquot (100 µL, 10 µM) was serially diluted with RNA-free water as indicated. qPCR yielded cq values for each serial dilution sample (measured twice) using the Auto-find threshold function of the software package. Negative control experiments (without the addition of miRNA) yielded cq values of >35. Data points of cq values as function of the number of miRNA strands per sample volume (calculated from the initial concentration and the serial dilutions) were fitted with the presented equation (red line, right image), yielding M = -3.36 and B = 42.12. The determined PCR efficiency was 0.98. The error bars were calculated from the results of experimental repetitions and were smaller than the diameter of the data point circle. (B) cq values of native/artificially enriched HDL particles were determined with the same threshold level as determined in panel A and converted to the number of miRNA strands in the qPCR sample volume. The absolute ratio of miRNA of the original sample was calculated from the number (concentration) of HDL particles in the sample volume (3.2 x 1011 particles). (C) Cell samples (cell line ldlA7-SRBI) were incubated for 16 h with artificially enriched HDL particles (50 µg/mL) and analyzed similarly. The determined cq values were 22.5, 22.5, and 19.3 for cells only, for cells incubated with native HDL, or for cells incubated with rHDL particle solution (both 50 µg/mL), respectively. These values were converted to the number of miRNA strands as done in panel B. The number of miRNA strands after incubation (7.3 x 106) were corrected by subtraction of the number of miRNA strands before incubation (8.6 x 105). The result was divided by the number of cells in the sample volume (3,100), the miRNA-particle-ratio (1.5 x 10-4), and the incubation time period (16 h). This yielded the transfer rate of lipoprotein particles via miRNA uptake (240 HDL particle uptake events per cell and second). This figure has been modified from Axmann et al.19. Please click here to view a larger version of this figure.
Multiwell microfluidic array
Due to small yields of miRNA extraction, reverse transcription of the extracted miRNA was followed by a preamplification step. Finally, qPCR, as shown in Figure 6, was performed. For all steps, standard biochemical procedures were used as described by the manufacturer. Here, a part of the global miRNA profile on HDL particles of uremic patients recruited for a study on the influence of CRF on cholesterol efflux from macrophages18 is shown. In this study, the cholesterol acceptor capacity of HDL or serum in—besides others—17 young adult uremic patients (CKD stages 3-5) and 14 young adult hemodialysis patients without associated diseases and matched controls was measured. To analyze the data, default settings were used (maximum allowable CT value: 40.0, including maximum CT values in calculations and excluding outliers among replicates). P-values were adjusted using Benjamini-Hochberg false discovery rate (correction of the occurrence of false positives), and as normalization method, Global Normalization was selected, which finds the common assays among all samples to use its median CT for normalization. In the representative results, some RQs of miRNAs isolated from HDLs of uremic patients are depicted (RQs of controls are 1). Obviously, miR-122 and miR-224 are highly expressed in the HDLs of uremic patients. This whole step took approximately 1 day.

Figure 7: Flowchart and representative results of the multiwell microfluidic array. After the miRNA extraction as shown in Figure 5A, mix the miRNA sample with reverse transcription primer and a master mix containing 10x buffer, H2O, dNTP mix, inhibitor, MgCl2, and enzyme. After incubation on ice for 5 min, perform the reverse transcription using a thermocycler machine. Add the preamplification master mix, incubate for 5 min on ice, and perform preamplification using a thermocycler machine. Add 0.1x TE (pH 8.0) and mix an aliquot with PCR master mix and H2O. Pipette the PCR reaction mix into the fill port of the multiwell microfluidic array and spin twice at 3,000 x g for 1 min each. Perform qPCR using a PCR system and analyze the data to yield RQ values (here, the figure shows RQ values of HDL particles of uremia patients in comparison to a healthy control group18). Please click here to view a larger version of this figure.