2.1.

Materials and Methods

2.2.

Characterization Techniques

3.1.

HLA Class I Induction by IFN- $\gamma$ on the K562 Membrane Surface

Raman spectra obtained from K562 and other cells (time course treatment using IFN- $\gamma$ ) are similar to the spectra of most living cells.²¹ All the spectra show different Raman peaks at about 780, 850, 1004, 1125, 1450, and $1660{\mathrm{cm}}^{-1}$ . Typical bands in these spectra [see Fig. 1] are originated from nucleotide conformation $\left(700\text{to}800{\mathrm{cm}}^{-1}\right)$ , skeleton geometry and phosphate-related vibrations $\left(800\text{to}1200{\mathrm{cm}}^{-1}\right)$ , nucleotides $\left(1200\text{to}1600{\mathrm{cm}}^{-1}\right)$ , and $\mathrm{C}\mathrm{C}$ and $\mathrm{C}{\mathrm{H}}_x$ modes due to proteins and lipids (about $1450{\mathrm{cm}}^{-1}$ ). Also, amide vibrations, such as amide-I band (due to $\mathrm{C}\mathrm{O}$ stretching, $1650\text{to}1700{\mathrm{cm}}^{-1}$ ) and amide III band (due to $\mathrm{C}\mathrm{N}$ stretching, and $\mathrm{N}\mathrm{H}$ bending, about $1250{\mathrm{cm}}^{-1}$ ) in proteins are easily identifiable. The amide I bands in the range between 1620 and $1700{\mathrm{cm}}^{-1}$ also provide very important information about the conformation of secondary structure [ $\alpha$ -helix, $\beta$ -sheet, and random coil $\left(\gamma \right)$ structure] of proteins. Different amino acids are recognized explicitly at about 1004, 1011, and $1032{\mathrm{cm}}^{-1}$ in the Raman spectra. The cell’s conformational changes due to IFN- $\gamma$ treatment can be observed by intensity variation for the bands centered about 725, 855, and $1004{\mathrm{cm}}^{-1}$ (DNA bases and amino acid), whereas profile variation can be observed for the bands centered at $1450{\mathrm{cm}}^{-1}$ [ $\mathrm{C}{\mathrm{H}}_x$ deformation vibration (associated to DNA, protein, and lipid)], and in the range of $1625\text{to}1750{\mathrm{cm}}^{-1}$ (related to the proteins’ secondary structure). In the inset of Fig. 1, the zoomed area of Raman spectrum in the range of $1620\text{to}1740{\mathrm{cm}}^{-1}$ is shown. To avoid interference between the peaks during deconvolution, all the spectra were fitted after fixing the peak position and spectral linewidth. The three fitting curves, observed at around 1660, 1677, and $1686{\mathrm{cm}}^{-1}$ , are related to $\alpha$ , $\gamma$ , and $\beta$ secondary structure.

As previously described,^{21, 22, 23} $48\mathrm{h}$ IFN- $\gamma$ treatment of K562 induced a clear up-regulation of MHC class I molecules detected by the immunofluorescence technique, while at $72\mathrm{h}$ , the MHC class I levels start returning to the baseline levels. Similar findings were observed by FACS measurements, shown in Figs. 2, 2, 2, 2 . Figure 2 clearly shows the up-regulation of HLA class I levels after treatment with IFN- $\gamma$ for $48\mathrm{h}$ , and after $72\mathrm{h}$ there was down-regulation of HLA class I on the cell surface. The mean fluorescence intensity MFI of HLA class I by immunofluorescence technique is 7.8, 23.3, 14.0 for control, 48 and $72\mathrm{h}$ , respectively. The MFI values for different cells with the standard deviation as an error bar are shown in Fig. 2. The effect of IFN- $\gamma$ on the K562 cell line with time leads to the variation in HLA class I levels, as observed by FACS, and in parallel there was an alteration in secondary structure observed by micro-Raman spectroscopy, which is compared and shown in Fig. 2 and 3 . The Raman spectrum of the HLA class I monomer shows a dominant band attributed to $\alpha$ -helix at about $1655{\mathrm{cm}}^{-1}$ . The treatment of cells with IFN- $\gamma$ causes first a concomitant up-regulation of HLA class I on the cell membrane and Raman $\alpha$ -helix content (and consequently the decrease in $\beta$ -sheet/ $\alpha$ -helix and/or random coil/ $\alpha$ -helix ratio with respect to the K562 control cell: considering the $\beta$ -sheet and random coil not variable in percentage of total secondary structure), respectively. On the other hand, after $72\mathrm{h}$ , with IFN- $\gamma$ treatment of K562, we observed a reduction in HLA class I expression by immunofluorescence technique and an increase of the $\beta$ -sheet/ $\alpha$ -helix and/or random coil/ $\alpha$ -helix ratio with respect to the K562 cell after $48\mathrm{h}$ IFN- $\gamma$ treatments. Figure 3 shows the ratio of $\beta$ -sheet/ $\alpha$ -helix $(\beta ∕\alpha )$ and random coil/ $\alpha$ -helix $(\gamma ∕\alpha )$ by varying the time (h). However, in both cases, the ratio decreased for K562 cells treated for $48\mathrm{h}$ with IFN- $\gamma$ and, thereafter, an increase in the ratio values for K562 cells treated with IFN- $\gamma$ for $72\mathrm{h}$ . The decrease in ratio confirms an increase in $\alpha$ -helix structure on cell membrane, observed by FACS findings because the presence of IFN- $\gamma$ induces the increase of MHC I peptide with time. PCA was performed in the range between 700 and $1800{\mathrm{cm}}^{-1}$ to categorize and then to distinguish the cells on statistical bases. It is a statistical method whereby the information content of each spectrum is described by a limited number of variables (the PCs). A PCA scatter plot (PC2 versus PC3) is shown in Fig. 3. Raman spectra, as observed in Fig. 1, did not clearly show much difference from each other. The PCA analysis [shown in Fig. 3] makes them clearly distinguishable from each other. Moreover, the 3-D PC (PC1 versus PC2 versus PC3) plot is also shown in Fig. 3. The 3-D-PCA-plot curve shows an explicit distinction of these different cell types. The loadings curve corresponding to PC1, PC2, and PC3 are also presented in Fig. 4 to further substantiate the analysis. The first principal (PC1) loading curve with spectral variance of 79.5% mostly shows dissimilarities in the region of secondary structure $\left(1600\text{to}1700{\mathrm{cm}}^{-1}\right)$ , at around $1050{\mathrm{cm}}^{-1}$ , around $840{\mathrm{cm}}^{-1}$ , etc. The PC2 loading curve, with spectral variance of 10.8%, shows remarkable variance in the range of $1150\text{to}1300{\mathrm{cm}}^{-1}$ , and peaks at around $1460{\mathrm{cm}}^{-1}$ , $760{\mathrm{cm}}^{-1}$ , etc., whereas the PC3 loading curve with a spectral variance of less than 2% shows the major dissimilarities at around $1230{\mathrm{cm}}^{-1}$ .

Fig. 2

FACS results of three K562 cell series: (a) K562 control, (b) $\mathrm{K}562+\mathrm{IFN}\text{-}\gamma$ for $48\mathrm{h}$ , and (c) $\mathrm{K}562+\mathrm{IFN}\text{-}\gamma$ for $72\mathrm{h}$ , and (d) mean fluorescence intensity (MFI) of HLA class I expression on these cells [standard deviation (SD) is shown as an error bar].

Fig. 3

(a) Ratio of $\beta$ -sheet/ $\alpha$ -helix and random coil/ $\alpha$ -sheet versus K562 cell treated with IFN- $\gamma$ by varying time (h) (SD is shown as an error bar), (b) principal component analysis (PC2 versus PC3) for these three K562 cells, and (c) 3-D PCA plot (PC1 versus PC2 versus PC3) is for the K562 cell line.

Fig. 4

Loading curve for three PCs (PC1, PC2, and PC3) for the K562 cell lines.

3.2.

HLA Class I Induction for T2 and T3 and the Derived Cell Line

Since IFN- $\gamma$ has pleiotropic effect on genes other than MHC class I, we set out to monitor HLA class I molecules using Raman spectroscopy analysis in a more controlled and specific system; the T2/T3 experimental cell system, and in exogenous peptide pulsing experiments using the T2 cell line as peptide presenting cells.

FACS measurements were carried out to assess the relative HLA class I expression in various conditions with respect to the T2 cell line. The results show that HLA class I is highly expressed in the T3 cells, while the T2 cell line has a low residual amount of the molecules on their cell membrane. However, the T2 cells pulsed with exogenous HLA-A2-specific binding peptide, potentially increased the HLA class I expression on T2 cells [Fig. 5 ]. Taking together, the results show a greater amount of HLA class I expression in T3 cells (TAP genes transfected cells) and in the T2 cell line pulsed with HLA-A2 specific peptide than the T2 cell line, as shown in Fig. 5. The MFI of HLA class I expression was about 190 for T3 cells pulsed with HLA-A2 specific peptides with respect to the control HLA class I values detected on T2 cells treated with the complete medium (MFI being 62).

Fig. 5

(a) Mean fluorescence intensity variation in T2, T3, and T2 cells treated with A2 peptide and (b) the ratio of $\beta$ -sheet/ $\alpha$ -helix and random coil/ $\alpha$ -helix versus T2, T3, and T2 cells treated with A2 peptide, derived from Raman spectra.

Raman spectral analysis confirms the FACS data of HLA class I MFI trend regarding variation in HLA class I, as observed in Fig. 5. Figure 5 shows that the ratio of random coil $\left(\gamma \right)$ to $\alpha$ -helix $\left(\alpha \right)$ secondary structure, first, decreases for T3 cells with respect to T2 cells and, thereafter, an increase was observed with the induction of peptide A2, which induces the HLA class I. Since HLA class I carries $\alpha$ -helix content, the increase in HLA class I causes a decrease in the ratio between random coil and $\alpha$ -helix. Further analysis was carried out to strengthen our findings. Figure 6 , presents a PCA scatter plot for PC1 against PC3. PCA analysis again distinguishes cell types from one another [Fig. 6], which were similar in Raman spectra (Fig. 1). The results show that the induced HLA class I in the cell line can be clearly differentiated by combining Raman spectra and PCA multivariate analysis. Further, 3-D PCA plot is also shown in Fig. 6. Cluster analysis was performed using the Euclidean distance function on these PCs, as shown in Fig. 6. On the basis of the number of points belonging to their own group, we cluserted data with an error of around 13%. Figure 7 shows loading curves (PC1, PC2, and PC3) with a maximum variance around 63% (PC1). The figure shows that the maximum dissimilarity is observed in secondary structure region, the region around $1100{\mathrm{cm}}^{-1}$ . These results show that Raman spectroscopy results follow the trend of what has been observed by FACS, which is a well-known biomedical cell-screening technique.

Fig. 6

(a) PCA (PC1 versus PC3), (b) 3-D PCA plot (PC1 versus PC2 versus PC3), and (c) cluster analysis on the micro-Raman data extracted for T2, T3, and T2 treated with the A2 peptide.

Fig. 7

Loading plot for three primary PCs (PC1, PC2, and PC3) for the T2 cell line series.

Furthermore, Raman measurements were performed on HLA-A2 monomer, HLA unrefolded, and HAGE refolded in the range between 700 and $1800{\mathrm{cm}}^{-1}$ , as shown in Fig. 8 . The inset zoomed area shows the secondary structure in the range between 1600 and $1800{\mathrm{cm}}^{-1}$ . The Raman spectra in Fig. 8 shows clear presence of phenylalanine (Phe) centered at 1005, 1033, and $1550{\mathrm{cm}}^{-1}$ , the $\mathrm{P}\mathrm{O}$ stretching vibration due to Tris buffer at about $1080{\mathrm{cm}}^{-1}$ , and the $\mathrm{C}\mathrm{O}{\mathrm{O}}^{-}$ bending centered at about $767{\mathrm{cm}}^{-1}$ . The broad band in the region of $1600\text{to}1720{\mathrm{cm}}^{-1}$ is associated to the secondary structure of the monomer. We show clear evidence that the sharp peak reduced drastically for HLA-A2 unrefolded peptide with respect to the HLA-A monomer and again it begins to recover with HAGE refolding. The behavior of this band height variation is due to the change in $\alpha$ -helix structure of monomer. Therefore, we can conclude that the Raman spectroscopy follows the conformational changes of monomers, based on its secondary structure.

Fig. 8

Micro-Raman spectra for HLA-A monomer unrefolded, HLA-A monomer, and HAGE refolded in the range of $700\text{to}1800{\mathrm{cm}}^{-1}$ . In the Inset, the zoomed area of the plot in the region of $1600\text{to}1800{\mathrm{cm}}^{-1}$ .