Abstract
One prerequisite for a successful clinical outcome of human pluripotent stem cell (hPSC) based therapies is immune compatibility between grafted cells/tissue and recipient. This study explores immune determinants of human embryonic stem cell lines (hESC) and induced human pluripotent stem cell (hiPSC) lines and hepatocyte- and cardiomyocyte-like cells derived from these cells. HLA class I was expressed on all pluripotent hPSC lines which upon differentiation into hepatocyte-like cells was considerably reduced in contrast to cardiomyocyte-like cells which retained class I antigens. No HLA class II antigens were found in the pluripotent or differentiated cells. Histo-blood group carbohydrate antigens SSEA-3/SSEA-4/SSEA-5, Globo H, A, Lex/Ley and sialyl-lactotetra were expressed on all hPSC lines. Blood group AB(O)H antigen expression was in accordance with ABO genotype. Interestingly, only a subpopulation of A1O1 cells expressed A. During differentiation of hPSC, some histo-blood group antigens showed congruent alteration patterns while expression of other antigens differed between the cell lines. No systematic difference in the hPSC cell surface tissue antigen expression was detected. In conclusion, hPSC and their derivatives express cell surface antigens that may cause an immune rejection. Furthermore, tissue antigen expression must be established for each individual stem cell line prior to clinical application.
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Introduction
The potential clinical applications of stem cell-based technology and products, derived from human embryonic stem cells (hESC) isolated from the inner cell mass of blastocysts1 and human induced pluripotent stem cells (hiPSC) generated from adult cells2, are currently explored. Human pluripotent stem cells (hPSC, i.e. hESC and hiPSC) can under optimal culturing conditions be propagated indefinitely while maintaining their ability to differentiate into all human cell types3. Besides being an endless source of material for tissue engineering and replacement therapy4, both the pluripotent and the differentiated cell states can serve as in vitro models of various human diseases as well as disease-free controls, thereby facilitating drug development and toxicology screening.
One of the barriers to overcome before hPSC-derived products can be brought to the clinic is the challenge of the recipient’s immune system to non-self antigens, which may command for lifelong immunosuppressive therapy. Generating and maintaining patient-specific hiPSC lines, which may overcome this obstacle5,6,7, is at present costly and time consuming. However, a more feasible approach to enable non-autologous therapies may be to assemble hPSC line banks with diverse HLA (human leukocyte antigen) and ABO blood group types.
Initially hPSC were assumed to be immune privileged due to their undifferentiated state, which partly was reinforced by early experimental data8. However, several studies have contradicted this assumption9,10. Seemingly, hPSC and their derivatives are subject to the same immunological barriers as conventional allografts. The strongest histocompatibility antigen barriers are the HLA antigens and the ABO blood group systems. HLA class I (HLA-A/B/C) antigens are expressed on almost all nucleated cells11, while class II (HLA-DR/DQ/DP) antigens are constitutively expressed mainly on antigen presenting cells but can be induced by cytokines, mainly interferon-gamma. Early studies of hESC demonstrated low levels of HLA class I antigens, with a modest induction during differentiation, and absence of HLA class II12,13. Similar results have been reported for hiPSC14. In a recent study, including both hESC and hiPSC lines, Chen et al. found normal and varying HLA haplotypes as well as confirmatory phenotypic expression of low levels of HLA class I15.
Adult cardiomyocytes do not express HLA class I or II, but class I can be found in patients with myocarditis or allograft rejection16,17. In contrast, the presence of HLA class I antigens on hepatocytes is not clearly established. Several studies failed to detect HLA class I in normal livers18,19,20,21,22,23, while other reported weak or variable expression15,24,25,26. Adult hepatocytes do not express HLA class II, although expression is inducible in patients with immune mediated liver disease24,25,27.
Regarding the ABO blood group system it was initially unclear whether hPSC and their derivatives express AB(O)H antigens28. Mölne et al. demonstrated that several hESC lines expressed A/B antigens corresponding to the ABO genotype29. During differentiation into cardiomyocyte-like cells, A/B antigen expression was lost while the antigens were retained in hepatocyte-like cells. AB(O)H antigens are not present in adult cardiomyocytes30 or hepatocytes27,31.
Several stage-specific antigens (SSEA) of carbohydrate nature have been identified in mice during early embryo development32,33. Studies of AB(O)H and Lewis blood group antigen expression during human embryonic development are few. However, Szulman was able to study different fetal tissues and organs from fetuses 5–15 weeks of gestational age and found an inverse correlation between age and distribution34,35,36. Certain tissues showed a consecutive expression during development, while others demonstrated a diminishing trend and a few, including liver and heart, lacked AB(O)H antigens within the observed timeframe.
This study explored the phenotype expression of HLA antigens, histo blood group AB(O)H and related carbohydrate antigens in correlation to the individual HLA and ABO genotypes in three hESC and three hiPSC lines by flow cytometry (FC) and immunohistochemistry (IH). Studies of total glycosphingolipid fractions as well as protein extracts of the cells were performed in an attempt to differentiate determinants carried by lipids or proteins. In addition, we explored the alterations of these antigens during differentiation into cardiomyocyte- and hepatocyte-like cells.
Materials and Methods
hESC lines, culture and differentiation procedures
The hESC lines SA121 and SA181 (Takara Bio Europe AB) originate from human in vitro fertilized embryos (Sahlgrenska university hospital Sweden). The GMP-grade hESC line Val 9, derived as previously described37,38,39,40, was obtained from the National Stem Cell Bank of Spain and developed under xeno-free conditions aimed for clinical applications39. The hiPSC lines ChiPSC4, ChiPSC15 and ChiPSC22 (Takara Bio Europe AB) were derived from human dermal fibroblasts using retroviral programming40,41.
The cells were thawed, maintained, and passaged in the feeder-free Cellartis® DEF-CS™ 500 Culture System (Takara Clontech, Y30010) according to the manufacturer’s recommendations.
The cell lines were used in subsequent differentiation experiments at the following passages: SA121 p.9–13, 15–22, 24; SA181 p.8, 10–18, 21–22, 24–25; Val 9 p 29, 31, 33; ChiPSC4 p.12, 17, 18, 23; ChiPSC15 p.23, 24; ChiPSC22 p.20, 21.
The hPSC were differentiated into definitive endoderm (DE) cells by applying Cellartis® Definitive Endoderm differentiation kit (Takara Clontech, Y30035). At day 7, the cells were harvested according to the manufacturer’s recommendations and differentiated into hepatocyte-like cells applying the Cellartis® Hepatocyte differentiation kit (Takara Clontech, Y30050,42). Cells for analysis were harvested as single cells at different time points as described below. The hiPSC line ChiPSC22 was differentiated into cardiomyocyte-like cells according to Takara Bio Europe AB´s standard protocol (Cellartis® Cardiomyocytes, Y10075).
Genomic HLA and ABO blood group typing
DNA was extracted from cell suspensions using a biorobot (EZ1, Qiagen). HLA-A/B/C, DRB1, DQA1 and DQB1 typing was performed on a Luminex platform (Luminex) using PCR-SSO technique (OneLambda) and Fusion 2.0 software (OneLambda).
ABO-typing was achieved by a modified PCR-SSP method according to a protocol from Downing and Darke43, using Taq PCR Master Mix Kit (QIAGEN, 201443) on a GeneAmp PCR System 9700 (Applied Biosystems). Primers were bought from Scandinavian Gene Synthesis and the gels were analyzed using a LumiBIS detection system (DNR Bio-Imaging Systems Ltd).
Flow Cytometry (FC)
Characterization of the HLA and histo-blood group antigen expression on the cell surface of hPSC lines and alterations during differentiation into hepatocyte-like and cardiomyocyte-like cells was performed using single-color fluorescence. For detailed description of cell preparation, staining methodology and data analysis see Supplemental information text and Figure S1. Briefly, trypsinized single cell suspensions of 2−3 × 105 cells were incubated at 4 °C with primary monoclonal antibodies (Supplemental Table S1), followed by corresponding FITC-conjungated secondary antibodies and isotype controls (Supplemental Table S2) after extensive washing-procedure. Duplicate samples were prepared and all hPSC lines and cells at consecutive differentiation days were examined on three separate occasions. The samples were analyzed by a FACSCaliburTM flow cytometer (Becton Dickinson), with the use of CellQuestTM and (Becton Dickinson) FlowJo (v10.1.r5, FlowJo LLC) software.
Complement-dependent cytotoxicity crossmatch (CDC-XM)
Functional assays of the HLA A and B series were performed according to the protocol for assessing recipient and donor compatibility prior to organ transplantation44. In brief, the hPSC were incubated with HLA-specific sera with known HLA A and B specificity. Thereafter, rabbit complement (Bio-Rad Medical, 824050) and fluorescent dyes (acridine orange and ethidium bromide) were added. The plates were rotated manually, mounted using cover slips and paraffin and incubated for 30 min. The reaction was evaluated using fluorescence microscopy.
Immunohistochemistry (IH)
Immunohistochemical analyses of HLA and histo-blood group antigen expression on hPSC lines and their alterations during differentiation were performed as previously described29. Cells were harvested by trypsin digestion or scraped of tissue culture flasks as monolayers and fixed in buffered paraformaldehyde. After paraffin embedding, and sectioning, antigen retrieval was performed by microwave treatment. Immunostainings were performed either in a computer-assisted Autostainer Plus processor (Dako) or manually using a Vectastain Elite ABC kit (Vector Laboratories/BioNordika), see Supplemental Table S1 for details.
Isolation and characterization of lipid-linked carbohydrate antigens
Total neutral (non-acid) and acid glycosphingolipid fractions were isolated from 1 × 109 hESC of cell line SA121 and SA181 respectively, and individual glycosphingolipid components were structurally characterized45,46,47. Thin-layer chromatography and chromatogram binding assays were performed using aluminum- or glass-backed silica gel 60 high performance thin-layer chromatography plates eluted with chloroform/methanol/water (60:35:8, v/v/v) as solvent system. Glycosphingolipids were applied to the plates in quantities of 1–4 µg of pure glycosphingolipids and 40–80 µg of total glycosphingolipid fractions. Chemical detection was done with anisaldehyde and monoclonal antibody reactivity with glycosphingolipids was tested as previously described29,46,47.
Characterization of protein-linked antigens
Western blot (WB) protein binding assay was performed as previously described47. Briefly, 13 µg of cell lysates from hESC lines SA121 and SA 181 and 1 µg of the neoglycoproteins were diluted, reduced, heated and loaded onto Bis-Tris gels (NuPage). After electrophoresis, the proteins were stained with ImperialTM Protein Stain (Thermo Scientific) or transferred to nitrocellulose membranes (Bio-Rad), blocked for 1 h and thereafter incubated with primary antibodies (Table S1) over night at 4 °C, followed by incubation with alkaline phosphatase-conjugated secondary antibodies (Table S2) for 1 h at room temperature. Nitroblue tetrazolium dye/5-bromo-4-chloroindol-2-yl phosphate (NBT/BCIP, Sigma) was used for visualization. The experiments were repeated three times.
Results
Characterization of HLA and histo-blood group antigens in hPSC lines
The expression of cell surface HLA and histo-blood group antigens on hESC (Val 9, SA121 and SA181) and hiPSC (ChiPSC4, ChiPSC15 and ChiPSC22) lines was analyzed by flow cytometry (FC) and immunohistochemistry (IH) and the results are shown in Figs 1, 2 and summarized in Table 1. In an attempt to characterize the molecular structure of the antigens, immunostaining of purified glycosphingolipid fractions separated by thin-layer chromatography and western blot (WB) of extracted protein fractions were performed and selected experimental data is shown in Fig. 3. Antigen expression alterations during differentiation into hepatocyte- and cardiomyocyte-like cells are shown in Figs 2, 4, 5, 6B and S3. All cell lines analyzed showed a homogenous staining intensity and antigen expression pattern with no significant variation in antigen expression between different cell passages and experimental repetitions. No major systematic differences were observed between the hESC and hiPSC lines. The chemical structure and short hand designations of the histo-blood group carbohydrate determinants are shown in Table S3.
Pluripotency markers
The pluripotency state for each cell line was evaluated by phenotypic profiling of established markers such as TRA-1–60, SSEA-3 and SSEA-4 and the recently identified sialyl-lactotetra (S-Lc4)47. All hPSC lines abundantly expressed these markers (Figs 1 and 2A). However, in contrast to anti-S-Lc4, anti-TRA-1–60 and anti-SSEA-4, the FC analysis with anti-SSEA-3 showed a diverse binding between cell lines and only a modest expression. Immunohistochemistry revealed mainly an intracellular expression of SSEA-3 (Figure S2A), whereas the other pluripotency markers in addition were localized on the cell surface, most evident for S-Lc4 (Fig. 2A). The H type 1/SSEA-5 antigen, a novel marker for hPSC48, showed a weak staining in all cell lines by FC, while IH analysis was negative (Fig. 1) using an antibody with validated specificity against H type 146. This discrepancy between FC and IH results was noted for some antibodies and is discussed in detail below. All hPSC lines studied were negative for SSEA-1 (Table 1), known to be a marker for undifferentiated rodent cells but not found in hPSC49.
HLA antigen expression in hPSC
Genomic HLA tissue typing revealed normal and expected antigen patterns of a Caucasian population (Table 1). HLA class I was abundantly expressed on all hPSC lines when analyzed by FC and IH (Figs 1 and 2B), with the exception of Val 9 that was positive in FC but negative in IH. No expression of HLA class II antigens was detected by either FC or IH.
The complement-dependent cytotoxicity crossmatch showed a high level of positive staining in all investigated cell lines, including in the negative controls. This high background staining could not be overcome despite several repetitions and protocol modifications and seemed to be caused by non-specific lysis of the hPSC upon exposure to the rabbit complement itself.
AB(O)H histo-blood group antigen expression in hPSC
Three out of six cell lines studied were of blood group A genotype and displayed a blood group A phenotype (Fig. 1, Table 1). Interestingly, only a subpopulation of the cells (30–50%) expressed A antigens on their cell surface when analyzed by FC (Fig. 1) using three different antibody clones (Table S1). This was verified by IH (Fig. 2C, Table 1), showing clear anti-A staining of a subpopulation of cells (35–50%), while the remaining cells were completely negative. The cells were either clearly positive or completely negative and no transient antigen expression was seen. All cell lines were blood group B antigen negative.
Antibodies specific for different blood group H determinants (H type 1 and Globo H) were used to further characterize the cell lines. The Globo H structure was clearly positive for all blood group O and A cell lines using FC (Fig. 1, Table 1), and IH (Fig. 2E, Table 1). A majority of the cells in all six hPSC lines expressed blood group H type 1/SSEA-5, albeit weakly, when characterized by FC while IH was negative. The Forssman antigen (based on the globo-core saccharide), recently identified as a novel blood group system50, was not present in any of the analyzed cell lines.
To further characterize the expression of AB(O)H antigens in hPSC, efforts were made to distinguish between antigens carried by lipids or proteins by analyzing purified total glycosphingolipid fractions (Fig. 3A) and total protein extracts (Fig. 3B) from cell lines SA121 and SA181. Compared to the results from immunostaining of purified glycosphingolipid fractions (Fig. 3A), WB of the crude cell protein extracts gave a significant higher background (Fig. 3B). We evaluated blood group A antigen expression using three different anti-A antibodies (Table S1) at various concentrations. No specific binding of anti-A was detected in the protein extracts (data not shown), whereas the glycosphingolipid fractions revealed one single blood group A compound (Fig. 3A), which was identified as a blood group A glycosphingolipid with six sugars based on a type 1 core chain46. No expression of blood group B antigens was detected in the total protein extractions or the glycosphingolipid fractions (data not shown).
Lewis histo-blood group and related antigen expression in hPSC
The type 1 core chain based Lewis blood group antigens, Lea and Leb, were not expressed on any of the hPSC lines when analyzed by FC (Table 1) or by biochemical analysis of the SA121 and SA181 cells46. The type 2 chain isomers, Lex and Ley, were both identified in all hPSC lines (Fig. 1, Table 1). Lex expression followed the same pattern as for blood group A antigens, hence only a subpopulation of cells (25–65%) were positive, except for ChiPSC22 where the majority of cells expressed Lex when analyzed by FC (Fig. 1). No Lex expression was detected in hPSC by IH (Table 1). However, Ley was intensely expressed on all cells when analyzed by both FC and IH (Figs 1 and 2F). Thin-layer chromatography immunostaining of the total neutral glycosphingolipid fractions showed several Ley glycosphingolipids migrating in the hepta- to dodecaglycosylceramide region in both cell lines investigated (Fig. 3A). The anti-Lex monoclonal antibody stained only slow-migrating neutral glycosphingolipids in hESC lines SA181 and SA121. Western blot analysis of the total protein extracts with anti-Ley displayed one distinct band at 37kD in both hESC lines, whereas no binding was evident with anti-Lex antibody (Fig. 3B).
Sialic acid terminating antigen expression in hPSC
The sialylated type 1 core chain compound lactotetraosylceramide (sialyl-lactotetra, S-Lc4) was present in all hPSC lines analyzed as described above. Addition of a terminal sialic acid residue to the SSEA-1 and SSEA-3 antigens forms the S-Lex and SSEA-4, respectively (Table S3). No expression of S-Lex was detected in any of the analyzed hPSC lines (Table 1). All hPSC lines stained with anti-SSEA-4, were positive when analyzed by FC (Fig. 1) and IH (data not shown). Furthermore, the expression of the gangliosides GM1 and GM2 was analyzed by FC and IH in hESC line SA121 and SA181 with negative results (data not shown).
Expression of co-stimulatory factors and CD133 in hPSC
Neither of the co-stimulatory T-cell signaling proteins B7-1 (CD80), B7-2 (CD86), ICOS (CD278) or CTLA-4 (CD152) were found by FC analysis. However, the intercellular adhesion molecule ICAM (CD54) was present on the cell surface of all analyzed cell lines (i.e. SA121, SA181, Figure S2B). The anti-CD133 antibody recognizes a carbohydrate epitope of the CD133 antigen that evidently was expressed on all hPSC lines analyzed in this study (Figure S2C).
Alterations of HLA and histo-blood group antigen expression during differentiation
Human PSC can be stimulated in vitro to differentiate into cell types from all three embryonic germ layers; ectoderm, mesoderm and endoderm. In this study, one hiPSC (ChiPSC4) and three hESC (Val 9, SA121, SA181) lines were differentiated into hepatocyte-like cells (endoderm) and one hiPSC line (ChiPSC22) into cardiomyocyte-like cells (mesoderm). Flow cytometry and complementary IH analysis were performed at different time points during differentiation. In general, the experiments were repeated three times and the results were, as for the undifferentiated cells, highly reproducible within and with a few exceptions also between the investigated cell lines.
Differentiation into hepatocyte-like cells
The alterations of antigen expression observed during differentiation into hepatocyte-like cells are shown in Figs 4 and S3. Expression of the pluripotency markers TRA-1–60, SSEA-3, SSEA-4 and S-Lc4 decreased during differentiation and all markers (except SSEA-4) had disappeared after 11–14 days.
HLA class I expression rapidly decreased in all cell lines (Fig. 4), with legible positivity remaining at day 7 and onwards (except ChiPSC4 that showed a slight rebound at day 21). Complementary IH showed abundant HLA class I expression on day 0 in the investigated cell lines (except Val 9, Fig. 2B, Table 1). In accordance with FC, no expression was found at day 7 or onward by IH, except for a rebound focal positivity noted exclusively in hepatocyte-like cells derived from ChiPSC4 (data not shown). HLA class II (HLA-DR/DQ/DP) antigens, absent in the pluripotent cells (see above, Table 1), did not appear during differentiation (data not shown) when analyzed by either FC or IH.
Histo-blood group AB(O)H and related carbohydrate antigens showed variable expression patterns during differentiation (Figs 4, S3). The expression of blood group H type 1/SSEA-5 and Globo H decreased, except for Val 9 that showed a rebound expression of Globo H in the hepatocyte-like cells. The blood group A positive cell lines SA121 and SA181 displayed contradicting anti-A staining patterns (Fig. 4). Complementary IH analysis of cell line SA181 showed distinct staining with anti-A on day 0 (Fig. 2C), focal traces of staining on day 4 and negative expression from day 7 and onwards (data not shown). In general, a decreasing Lex and Ley expression was seen by FC analysis in all cell lines (Fig. 4). Lex decreased from approximately 50% positive cells to zero from day 13 and onwards. Ley expression declined from 100% to about 40% positivity in all cell lines at day 21, except for hepatocyte-like SA181 cells that were Ley negative. Complementary IH analysis of Lex antigen demonstrated positive subpopulations of approximately 20%, 10% and 75% of cells at day 7 derived from Val 9, SA181 and ChiPSC4 respectively, whereas remaining cells were negative (Fig. 2G,H show IH images for cell line Val 9 and ChiPSC4, data for cell line SA181 are not shown). This is in accordance with the FC analysis, where the highest level of Lex positive cells occurred at day 7 (range 50–80%, Fig. 4). No Lex expression was detected by IH on day 0, 11 or 21 of differentiation into hepatocyte-like cells (data not shown). Immunohistochemistry demonstrated extensive anti-Ley staining in all cell lines on day 0 (Fig. 2F), followed by rapidly diminishing expression during differentiation (data not shown). Sialylated Lex (S-Lex) expression was modestly, but continuously, increased in SA121 and SA181 lines, while Val 9 and ChiPSC4 showed negligible positivity when analyzed by FC (Fig. 4). Complementary IH partly verified these results, demonstrating no expression at day 0, but a 5–10% anti-sialyl-Lex positive population on day 14–21 in cell line ChiPSC4 and SA181 (Fig. 2I), but not in Val 9 (data not shown).
No expression of blood group B, Lea, Leb, or Forssman antigens was identified during the four separate time points of differentiation using FC and IH.
Differentiation into cardiomyocyte-like cells
The pluripotency markers were eliminated during differentiation of hiPSC line ChiPSC22 into cardiomyocyte-like cells (Figs 5, S4), with the exception of SSEA-4 that showed rebound positivity. HLA class I expression during differentiation into cardiomyocyte-like cells showed a different pattern compared to the hepatocyte-like cells. Initially the expression rapidly diminished, followed by a considerable increase and all cardiomyocyte-like cells expressed HLA class I at day 26 (Fig. 5D). Similar to the hepatocyte-like cell differentiation, HLA class II antigens were not detected by FC analysis during differentiation. All cardiomyocyte-like cells were negative for blood group A, H type 1/SSEA-5, Globo H, Lex and Ley antigens (Fig. 5B,C). Anti-blood group B, anti-Lea, anti-Leb, anti-sialyl-Lex and anti-Forssman antibodies showed no positivity in FC analysis during day 0–26 (data not shown).
Comparison of cell surface staining of anti-SSEA-1 (MC480) and anti-Lex (P12) antibodies in hPSC and their derivatives
SSEA-1 is extensively expressed in mouse but not in human PSC32,49 and is considered synonymous to the Lex compound. However, in this study the anti-SSEA-1 antibody (clone MC480) and anti-Lex antibody (clone P12) showed different staining patterns in all hPSC lines analyzed by FC (Fig. 6A). None of the cell lines showed staining with MC480 in the undifferentiated state. However, a subpopulation of the hPSC was positive for the P12 antibody (Fig. 1) and Lex terminating glycosphingolipids were identified in the hPSC cells (Fig. 3A). About 10% of the cells transiently expressed SSEA-1 (median fluorescence intensity 208) on day 7 during differentiation into hepatocyte-like cells (Fig. 6B). This observation was reproducible upon experimental repetition as well as consistent between all cell lines used in this study. Complementary IH results showed a small percentage of positive cells exclusively on day 7 of differentiation in the Val 9 line, whereas the SA181 and ChiPSC4 were negative for anti-SSEA-1 throughout differentiation (data not shown). SSEA-1 was not expressed during the differentiation into cardiomyocyte-like cells (day 0, 11, 26) when analyzed by FC (data not shown).
Alteration of CD133 expression during differentiation of hPSC
The expression of CD133 in hPSC and alterations during differentiation into hepatocyte-like and cardiomyocyte-like cells are illustrated in Figure S2C. Positive staining with anti-CD133 was found in all cell lines at day 0 during differentiation into hepatocyte-like cells, but became almost negative at day 7 to be succeeded by an increasing positivity on day 14. In contrast, during differentiation of ChiPSC22 into cardiomyocyte-like cells the expression of CD133 declined rapidly and was undetectable from day 11 and onwards.
Discussion
The HLA and ABO histo-blood group systems are the major immune barriers in organ transplantation. The initial perception of an immune privileged state in hPSC has been challenged in several studies9,10. In contrast to previous studies12,13, all six hPSC lines in our study extensively expressed cell surface HLA class I antigens, which are potential targets for the immune system of a HLA-mismatched recipient. The HLA class I expression diminished during differentiation into hepatocyte-like cells (except for one cell line), in congruence with the adult status. Unexpectedly, differentiation into cardiomyocyte-like cells resulted in a rebound expression of HLA class I at day 21 although adult cardiomyocytes lack HLA class I antigens17. This, as well as other antigen fluctuations noted during differentiation could be a consequence of different developmental processes but also a potential rebound effect driven by culturing conditions and differentiation protocols. Identification of such external factors altering immunogenicity could facilitate manipulation of differentiation into products with more favorable antigenicity and must be further investigated before therapeutic hPSC-based applications can be realized. The HLA-genotyping of all cell lines disclosed expression of alleles in consistency with their presumed origin from a Caucasian population and in alignment with earlier studies15,51. Therefore, as in allotransplantation, it is necessary to establish the HLA haplotypes of the donor and recipient in stem cell therapy. Our efforts to investigate the functional significance of the expressed HLA antigens were not successful due to a high non-specific background, most likely caused by an unspecific lysis of the hPSC by the rabbit complement itself.
Favorable transplantation aspects are that, in analogue with earlier studies12,15,51,52, no HLA class II antigens were found on the hPSC. Furthermore, the hPSC did not express co-stimulatory factors (i.e. B7-1/CD80, B7-2/CD86, ICOS/CD278, CTLA-4/CD152) necessary for successful T-lymphocyte activation.
Initially it was unclear if the antigens of the blood group ABO system were expressed on hPSC28. However, IH studies of nine hESC lines revealed blood group A and B antigen expression29 which was confirmed by biochemical analyses46. In the SA121 and SA181 lines, both blood group A and H glycosphingolipids based on a type 1 core saccharide chain (lactotetra) were identified, while the Lea/Leb compounds were lacking46. Since the Le gene frequency in the Caucasian population is approximately 80%53 it is likely that some of the hPSC lines should be Le positive. This indicates that the Le gene coded enzyme is not active in hPSC. The opposite relationship was seen for the expression of corresponding blood group antigens based on type 2 (neo-lactotetra) core saccharides. No type 2 chain based A antigens were found while the Lex/Ley compounds were present showing that the fucosyltransferase working on the neolactotetra saccharide substrate was active. Interestingly, a subpopulation of 30–45% of the hPSC cells within a specific cell line expressed blood group A antigen, whereas the majority were completely negative when analyzed by either FC or IH. This may be a consequence of the blood group A1 glycosyltransferase becoming active at certain stages of cell development and may reflect a heterogeneous cell population in various stages of maturation. Furthermore, in contrast to adult human organs/cells that contain several structurally different blood group A glycosphingolipids, cell lines SA121 and SA181 only contained one blood group A glycosphingolipid compound with six sugar residues29. No blood group A antigens carried by proteins were found in the blood group A genotype cell lines, suggesting that A antigens are mainly lipid-linked in hPSC. This is in contrast to adult human erythrocytes were a majority of AB(O)H antigens are linked to proteins53 and the AB(O)H glycosphingolipids are based on type 2 core chains54. During differentiation into cardiomyocyte-like cells, expression of blood group A antigens diminished and was negligible from day 11, which is concordant with adult cardiomyocytes lacking A antigens30. However, the alterations during differentiation into hepatocyte-like cells were more inconsistent, with decreasing expression in cell line SA181 in accordance with adult hepatocytes lacking AB(O)H antigens and the study by Mölne et al. demonstrating retained blood group B antigen expression in the hESC-derived hepatocyte-like cells27,29,31. In contrast, A antigen expression was increased in the SA121 line.
The use of several different analytical techniques strengthened our results regarding the detection and expression of antigen epitopes in the cell lines. Nonetheless, there are methodological aspects to be discussed depending on the analytical techniques used. Generally, we found weaker staining in IH compared to FC analyses. However, with few exceptions, the results were congruent between the two antibody-dependent methods. For example, no expression of Lex could be detected by IH in the hPSC, but positive staining was obtained during differentiation in alignment with more intense expression in FC analysis. The discrepancies may be due to the higher sensitivity of FC or alterations in epitope-structures caused by the fixation and deparaffinization processes used in IH55. Furthermore, biochemical analysis of the cell lines available in sufficient amounts strengthened the identification of the carbohydrate antigens identified by the immune techniques.
Phenotypic profiling with immunostaining techniques is an essential tool to evaluate pluripotency in stem cells. The different techniques and markers used in this study, together with alteration of the markers during cell differentiation, enabled us to compare presumed pluripotency markers. Compared to TRA-1–60 and sialyl-lactotetra that showed an anticipated and technique-independent expression pattern, SSEA-3 and SSEA-4 were more suboptimal markers. Anti-SSEA-3 showed a diverse and weak staining of hPSC in FC analysis, which has been previously described1, and was partly explained by its mainly intracellular localization reveled by IH. On the contrary, SSEA-4 was abundantly expressed in the hPSC with a remaining positivity in 15% of the hepatocyte-like cells consistent with earlier work56. In the cardiomyocyte-like cells an increased expression from day 11 and onwards was found congruent with findings that adult cardiomyocytes express SSEA-457. The H type 1/SSEA-5 antigen has recently been proposed to be a marker of undifferentiated cells48. This is partly confirmed by our study showing that H type 1/SSEA-5 expression in hPSC diminishes upon differentiation. However, the level of antigens and fluorescence intensity in the pluripotent cells was low as seen in the FC histograms, and no reaction was found with IH analysis.
The results from this study, together with our previous work47,58, shows that sialyl-lactotetra (s-Lc4) can be used as a phenotypic pluripotency marker. Based on this work this may also be the case for the Ley epitope. Both antibodies work well in various immunostaining techniques and can besides being markers of undifferentiated cells, be used as selection tools during differentiation for exclusion of undifferentiated cells in heterogeneous cultures. These two structurally well-defined antigens are lost upon differentiation into hepatocyte-like (i.e. endoderm), cardiomyocyte-like (i.e. mesoderm) and neural stem cells (i.e. ectoderm,58). However, in contrast to sialyl-lactotetra, the Ley antigen is present in some adult human tissues and in a fraction of hepatocyte-like and neural stem cells, but not in cardiomyocyte-like cells. Noteworthy, functional pluripotency assays using anti-S-Lc4 or anti-Ley have not yet been done.
Another stage-specific embryonic antigen of interest is SSEA-1, abundantly expressed in mouse but not in human PSC32,49. SSEA-1 is often presented as synonymous to CD15 and Lex, which is a misconception due to the fact that the antibody defining SSEA-1 (clone MC48032) is specific for the Lex epitope exclusively when presented on extended type 2 core chains59,60. This specificity entails the presence of Lex, but not SSEA-1, on hPSC found in this study. None of the cell lines expressed SSEA-1 in the pluripotent state, but about 10% of the cell population showed transient positivity on day 7 of differentiation into hepatocyte-like cells. This pattern is consistent with earlier work on embryonal carcinoma cells differentiated by retinoic acids, noting a peak of SSEA-1 expression on day 7 followed by declining expression61.
The transmembrane glycoprotein CD133 is often used to select or identify stem cells, such as hematopoietic stem cells and so-called cancer stem cells. This role has been challenged in recent years62. In this study, we found a fluctuating expression of CD133 during the differentiation into hepatocyte-like cells, while the expression diminished during differentiation into cardiomyocyte-like cells. The dynamic expression in differentiated, but still immature, cells contradicts the usability of CD133 as a marker for, and a target for drug development against, cancer stem cells.
The biological equivalence of hESC and hiPSC has been vividly debated63. We have previously shown that the composition of glycosphingolipids are similar between the two hPSC types, with the exception of reduced levels of GD1a, GD1b and increased levels of GM3 that was found in hiPSC compared to hESC58. In this study, we compared three hESC with three hiPSC lines and their derivatives and could not detect any apparent systematic differences in expression of HLA or AB(O)H histo-blood group antigens. However, our results indicate cell line specific expression patterns of tissue antigens in the pluripotent and differentiated states that are not generalizable to all hPSC lines. Consequently, all cell lines most be characterized individually before selecting suitable lines for clinical applications.
The results obtained in this descriptive analytical study, in addition to be a basic scientific exploration, also have clear clinical implications in the further development of the stem cell field with the ultimate goal to be used in the clinic for treatment of patients with end stage cell/organ failure. In conclusion, this study clearly demonstrates the necessity for hPSC-based therapies to address the status of the HLA and ABO blood group systems before clinical use.
References
Thomson, J. A. et al. Embryonic stem cell lines derived from human blastocysts. Science 282, 1145–1147 (1998).
Takahashi, K. et al. Induction of pluripotent stem cells from adult human fibroblasts by defined factors. Cell 131, 861–872 (2007).
Hanna, J. H., Saha, K. & Jaenisch, R. Pluripotency and cellular reprogramming: facts, hypotheses, unresolved issues. Cell 143, 508–525 (2010).
Kadereit, S. & Trounson, A. In Seminars in immunopathology. 551–562 (Springer).
Fairchild, P. J. The challenge of immunogenicity in the quest for induced pluripotency. Nature Reviews Immunology 10, 868–875 (2010).
Zhao, J. et al. Induced pluripotent stem cells: origins, applications, and future perspectives. Journal of Zhejiang University Science B 14, 1059–1069 (2013).
Scheiner, Z. S., Talib, S. & Feigal, E. G. The potential for immunogenicity of autologous induced pluripotent stem cell-derived therapies. J. Biol. Chem. 289, 4571–4577 (2014).
Li, L. et al. Human embryonic stem cells possess immune‐privileged properties. Stem Cells 22, 448–456 (2004).
Swijnenburg, R.-J. et al. Embryonic stem cell immunogenicity increases upon differentiation after transplantation into ischemic myocardium. Circulation 112, I-166–I-172 (2005).
Zhao, T., Zhang, Z.-N., Rong, Z. & Xu, Y. Immunogenicity of induced pluripotent stem cells. Nature 474, 212–215 (2011).
Berah, M., Hors, J. & Dausset, J. A study of HL-A antigens in human organs. Transplantation 9, 185–192 (1970).
Drukker, M. et al. Characterization of the expression of MHC proteins in human embryonic stem cells. Proceedings of the National Academy of Sciences 99, 9864–9869 (2002).
Draper, J. S., Pigott, C., Thomson, J. A. & Andrews, P. W. Surface antigens of human embryonic stem cells: changes upon differentiation in culture*. J. Anat. 200, 249–258 (2002).
Imberti, B., Monti, M. & Casiraghi, F. Pluripotent stem cells and tolerance induction in organ transplantation. Current opinion in organ transplantation 20, 86–93 (2015).
Chen, H.-F. et al. Characteristic expression of major histocompatibility complex and immune privilege genes in human pluripotent stem cells and their derivatives. Cell Transplant. 24, 845–864 (2015).
Daar, A., Fuggle, S., Fabre, J., Ting, A. & Morris, P. The detailed distribution of MHC Class II antigens in normal human organs. Transplantation 38, 293–298 (1984).
Rose, M. L., Coles, M. I., Griffin, R. J., Pomerance, A. & Yacoub, M. H. Expression of class i and class ii major histocompatability antigens in normal and transplanted human heart. Transplantation 41, 776–780 (1986).
Fleming, K., McMichael, A., Morton, J., Woods, J. & McGee, J. Distribution of HLA class 1 antigens in normal human tissue and in mammary cancer. J. Clin. Pathol. 34, 779–784 (1981).
Fukusato, T., Gerber, M., Thung, S., Ferrone, S. & Schaffner, F. Expression of HLA class I antigens on hepatocytes in liver disease. The American journal of pathology 123, 264 (1986).
Barbatis, C. et al. Immunohistochemical analysis of HLA (A, B, C) antigens in liver disease using a monoclonal antibody. Gut 22, 985–991 (1981).
Lautenschlager, I. & Häyry, P. Expression of the major histocompatibility complex antigens on different liver cellular components in rat and man. Scand. J. Immunol. 14, 421–426 (1981).
Lautenschlager, I. et al. Distribution of the major histocompatibility complex antigens on different cellular components of human liver. Cell. Immunol. 85, 191–200 (1984).
Franco, A. et al. Expression of class I and class II major histocompatibility complex antigens on human hepatocytes. Hepatology 8, 449–454 (1988).
Senaldi, G., Lobo-Yeo, A., Mowat, A., Mieli-Vergani, G. & Vergani, D. Class I and class II major histocompatibility complex antigens on hepatocytes: importance of the method of detection and expression in histologically normal and diseased livers. J. Clin. Pathol. 44, 107–114 (1991).
Montānto, L. et al. Hepatitis B virus and HLA antigen display in the liver during chronic hepatitis B virus infection. Hepatology 2 (1982).
Daar, A., Fuggle, S., Fabre, J., Ting, A. & Morris, P. The detailed distribution of HLA-A, B, C antigens in normal human organs. Transplantation 38, 287–292 (1984).
Rouger, P. et al. Expression of blood group antigens including HLA markers in human adult liver. Tissue Antigens 27, 78–86 (1986).
Grinnemo, K.-H., Sylvén, C., Hovatta, O., Dellgren, G. & Corbascio, M. Immunogenicity of human embryonic stem cells. Cell Tissue Res. 331, 67–78 (2008).
Mölne, J. et al. Blood group ABO antigen expression in human embryonic stem cells and in differentiated hepatocyte-and cardiomyocyte-like cells. Transplantation 86, 1407–1413 (2008).
Thorpe, S. J., HUNT, B. & YACOUB, M. Expression of ABH blood group antigens in human heart tissue and its relevance to cardiac transplantation. Transplantation 51, 1290–1295 (1991).
Ravn, V. & Dabelsteen, E. Tissue distribution of histo‐blood group antigens. APMIS 108, 1–28 (2000).
Solter, D. & Knowles, B. B. Monoclonal antibody defining a stage-specific mouse embryonic antigen (SSEA-1). Proceedings of the National Academy of Sciences 75, 5565–5569 (1978).
Shevinsky, L. H., Knowles, B. B., Damjanov, I. & Solter, D. Monoclonal antibody to murine embryos defines a stage-specific embryonic antigen expressed on mouse embryos and human teratocarcinoma cells. Cell 30, 697–705 (1982).
Szulman, A. E. The histological distribution of blood group substances A and B in man. The Journal of experimental medicine 111, 785–800 (1960).
Szulman, A. E. The histological distribution of the blood group substances in man as disclosed by immunofluorescence II. The H antigen and its relation to A and B antigens. The Journal of experimental medicine 115, 977–996 (1962).
Szulman, A. E. The histological distribution of the blood group substances in man as disclosed by immunofluorescence III. The A, B, and H antigens in embryos and fetuses from 18 mm in length. The Journal of experimental medicine 119, 503–516 (1964).
Heins, N. et al. Derivation, characterization, and differentiation of human embryonic stem cells. Stem Cells 22, 367–376 (2004).
Ellerström, C. et al. Derivation of a xeno‐free human embryonic stem cell line. Stem Cells 24, 2170–2176 (2006).
Aguilar-Gallardo, C. et al. Derivation, characterization, differentiation, and registration of seven human embryonic stem cell lines (VAL-3,-4,-5,-6M,-7,-8, and-9) on human feeder. In Vitro Cellular & Developmental Biology-Animal 46, 317–326 (2010).
Asplund, A. et al. One standardized differentiation procedure robustly generates homogenous hepatocyte cultures displaying metabolic diversity from a large panel of human pluripotent stem cells. Stem Cell Reviews and Reports 12, 90–104 (2016).
Ulvestad, M. et al. Drug metabolizing enzyme and transporter protein profiles of hepatocytes derived from human embryonic and induced pluripotent stem cells. Biochem. Pharmacol. 86, 691–702 (2013).
Brolen, G. et al. Hepatocyte-like cells derived from human embryonic stem cells specifically via definitive endoderm and a progenitor stage. J. Biotechnol. 145, 284–294, https://doi.org/10.1016/j.jbiotec.2009.11.007 (2010).
Downing, J. & Darke, C. A modified PCR SSP method for the identification of ABO blood group antigens. Eur. JImmunogenet. 30, 295–298 (2003).
Vartdal, F. et al. HLA class I and II typing using cells positively selected from blood by immunomagnetic isolation‐a fast and reliable technique. HLA 28, 301–312 (1986).
Holgersson, J., Jovall, P.-Å. & Breimer, M. E. Glycosphingolipids of human large intestine: detailed structural characterization with special reference to blood group compounds and bacterial receptor structures. J. Biochem. (Tokyo). 110, 120–131 (1991).
Barone, A. et al. Structural complexity of non-acid glycosphingolipids in human embryonic stem cells grown under feeder-free conditions. J. Biol. Chem. 288, 10035–10050 (2013).
Barone, A. et al. Sialyl-lactotetra, a novel cell surface marker of undifferentiated human pluripotent stem cells. J. Biol. Chem. 289, 18846–18859 (2014).
Tang, C. et al. An antibody against SSEA-5 glycan on human pluripotent stem cells enables removal of teratoma-forming cells. Nat. Biotechnol. 29, 829–834 (2011).
Kannagi, R. et al. Stage-specific embryonic antigens (SSEA-3 and-4) are epitopes of a unique globo-series ganglioside isolated from human teratocarcinoma cells. The embo journal 2, 2355 (1983).
Svensson, L. et al. Forssman expression on human erythrocytes: biochemical and genetic evidence of a new histo-blood group system. Blood 121, 1459–1468 (2013).
Lee, J. E. et al. Evaluation of 28 human embryonic stem cell lines for use as unrelated donors in stem cell therapy: implications of HLA and ABO genotypes. Cell Transplant. 19, 1383–1395 (2010).
Suárez-Álvarez, B. et al. Epigenetic mechanisms regulate MHC and antigen processing molecules in human embryonic and induced pluripotent stem cells. PloS one 5, e10192 (2010).
Klein, H. G. & Anstee, D. J. (John Wiley and Sons, Inc., 2014).
Clausen, H. & Hakomori, S.i. ABH and Related Histo‐Blood Group Antigens; Immunochemical Differences in Carrier Isotypes and Their Distribution. Vox Sang. 56, 1–20 (1989).
Dunphy, C. H. Applications of flow cytometry and immunohistochemistry to diagnostic hematopathology. Arch. Pathol. Lab. Med. 128, 1004–1022 (2004).
Ramirez, J. M. et al. Brief report: benchmarking human pluripotent stem cell markers during differentiation into the three germ layers unveils a striking heterogeneity: all markers are not equal. Stem Cells 29, 1469–1474 (2011).
Sandstedt, J. et al. SSEA-4+CD34-Cells in the Adult Human Heart Show the Molecular Characteristics of a Novel Cardiomyocyte Progenitor Population. Cells Tissues Organs 199, 103–116 (2014).
Säljö, K. et al. Comparison of the glycosphingolipids of human-induced pluripotent stem cells and human embryonic stem cells. Glycobiology, cww125 (2016).
Kannagi, R., Nudelman, E. & Levery, S. B. & Hakomori, S.-i. A series of human erythrocyte glycosphingolipids reacting to the monoclonal antibody directed to a developmentally regulated antigen SSEA-1. J. Biol. Chem. 257, 14865–14874 (1982).
Gooi, H. et al. Stage-specific embryonic antigen involves αl→3 fucosylated type 2 blood group chains. (1981).
Andrews, P. W. Human teratocarcinoma stem cells: Glycolipid antigen expression and modulation during differentiation. J. Cell. Biochem. 35, 321–332 (1987).
Irollo, E. & Pirozzi, G. CD133: to be or not to be, is this the real question. Am J Transl Res 5, 563–581 (2013).
Robinton, D. A. & Daley, G. Q. The promise of induced pluripotent stem cells in research and therapy. Nature 481, 295–305 (2012).
Svensson, L. et al. The structural basis of blood group A-related glycolipids in an A3 red cell phenotype and a potential explanation to a serological phenomenon. Glycobiology 21, 162–174 (2011).
Breimer, M. E. & Joval, P.-Å. Structural characterization of a blood group A heptaglycosylceramide with globo-series structure: The major glycolipid based blood group A antigen of human kidney. FEBS Lett. 179, 165–172 (1985).
Acknowledgements
The authors are indebted to Takara Bio Europe AB for generously providing all cell lines and derivatives included in this study. We thank Iolanda Oancea, Division of Clinical Immunology at Sahlgrenska University Hospital, for preforming the blood group genotyping, and PhD Maria Blomqvist, Department of Clinical Chemistry and Transfusion Medicine, the Sahlgrenska Academy, Gothenburg, Sweden for the kind gift of anti-sialyl-lactotetra, anti-GM1 and anti-GM2 antibodies. Furthermore, we thank Professor Anders Lindahl, Department of Clinical Chemistry and Transfusion Medicine, the Sahlgrenska Academy and Sahlgrenska University Hospital, for constructive and insightful comments on the manuscript. This study was supported by the Swedish Medical Research Council (Grant No. 12628), the Swedish Cancer Foundation and governmental grants to the Sahlgrenska University Hospital.
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Karin Säljö: Conception and design, collection and assembly of data, data analysis and interpretation, manuscript writing. Angela Barone: Collection and assembly of data, data analysis and interpretation, manuscript writing Johan Mölne: Conception and design, data analysis and interpretation, manuscript writing. Lennart Rydberg: Conception and design, data analysis and interpretation, manuscript writing. Susann Teneberg: Data analysis and interpretation, manuscript writing. Michael E. Breimer: Conception and design, financial support, data analysis and interpretation, manuscript writing.
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Säljö, K., Barone, A., Mölne, J. et al. HLA and Histo-Blood Group Antigen Expression in Human Pluripotent Stem Cells and their Derivatives. Sci Rep 7, 13072 (2017). https://doi.org/10.1038/s41598-017-12231-8
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DOI: https://doi.org/10.1038/s41598-017-12231-8
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