Tissue Modeling in Systemic Sclerosis Using Induced Pluripotent Stem Cells (iPSCs) (hiPSSS)

実験的：Participants with Systemic Sclerosis and Healthy Controls

Participants undergo blood sample collection for generation of induced pluripotent stem cells (iPSCs) and in vitro cellular and tissue modeling.

手順：Blood Sample Collection

Collection of approximately 28 mL of blood from each participant to generate induced pluripotent stem cell (iPSC) lines for in vitro cellular and tissue modeling analyses.

Rate of successful iPSC line generation from PBMCs in diffuse/severe systemic sclerosis patients

Percentage of participants with diffuse/severe systemic sclerosis (anti-Scl-70 positive) from whom at least one iPSC line is successfully generated via Sendai virus reprogramming of peripheral blood mononuclear cells (PBMCs).

Unit of Measure:

% of participants with at least one validated iPSC line

Rate of successful differentiation of iPSCs into at least one target functional cell type in localized/non-complicated systemic sclerosis patients

Among validated iPSC lines from localized/non-complicated SSc patients, the percentage of lines achieving successful directed differentiation into at least one target cell type (cardiomyocytes, macrophages, bronchial epithelial cells, immune cells, or fibroblasts). Success is confirmed by cell-type-specific marker expression assessed by immunofluorescence and flow cytometry.

Unit of Measure:

% of validated iPSC lines successfully differentiated into ≥1 target cell type

Rate of successful iPSC line generation from PBMCs in localized/non-complicated systemic sclerosis patients

Percentage of participants with localized/non-complicated systemic sclerosis (anti-Scl-70 negative, other SSc-specific antibody positive) from whom at least one iPSC line is successfully generated via Sendai virus reprogramming of PBMCs.

Unit of Measure:

% of participants with at least one validated iPSC line

Rate of successful differentiation of iPSCs into at least one target functional cell type in diffuse/severe systemic sclerosis patients

Among validated iPSC lines from diffuse/severe SSc patients, the percentage of lines achieving successful directed differentiation into at least one target cell type (cardiomyocytes, macrophages, bronchial epithelial cells, immune cells, or fibroblasts). Success is confirmed by cell-type-specific marker expression assessed by immunofluorescence and flow cytometry (e.g., cTnT for cardiomyocytes; CD68/CSFR1 for macrophages; NKX2.1/MUC5AC for bronchial epithelium).

Unit of Measure:

% of validated iPSC lines successfully differentiated into ≥1 target cell type

Change in cardiomyocyte differentiation efficiency following autologous autoantibody exposure

Comparison of ventricular cardiomyocyte differentiation efficiency, expressed as percentage of cardiac troponin T-positive (cTnT+) cells by flow cytometry, in iPSC-derived cardiomyocytes cultured with vs. without addition of autologous serum containing patient-specific autoantibodies. Serum is collected at Day 0 blood draw and stored at -80°C until use.

Unit of Measure:

% cTnT-positive cells (flow cytometry) - with vs. without autologous serum

Change in macrophage differentiation and inflammatory cytokine secretion following autologous autoantibody exposure

Assessment of iPSC-derived macrophage phenotype (% CD68+, CSFR1+, CD163+ cells by flow cytometry) and inflammatory response (secretion of CCL2, IL-6, CXCL1, CXCL8 measured by ELISA in pg/mL) under baseline conditions and following addition of autologous autoantibody-containing serum, compared between SSc patient-derived and healthy control-derived macrophages.

Unit of Measure:

Cytokine concentration (pg/mL) by ELISA; % CD68+/CSFR1+ cells by flow cytometry

Functional characterization of iPSC-derived cardiomyocytes - spontaneous beating activity

Proportion of iPSC-derived ventricular cardiomyocyte clusters exhibiting spontaneous contractile activity, assessed by video microscopy, as a measure of functional maturation following 2D differentiation and 3D spheroid formation using Matrigel. Maturation is further assessed after small molecule treatment with triiodothyronine (T3) and lipid-soluble cyclic AMP.

Unit of Measure:

% spontaneously beating clusters (video microscopy)

Molecular characterization of iPSC-derived cardiomyocytes - cardiac marker expression

Assessment of cardiomyocyte identity by flow cytometry (% cardiac troponin T-positive cells) and RT-qPCR quantification of cardiac-specific genes (MYH6, MYH7, TNNI3, KCNH2) in iPSC-derived cardiomyocytes from SSc patients compared to healthy matched controls.

Unit of Measure:

% cTnT-positive cells (flow cytometry); relative gene expression (RT-qPCR, arbitrary units normalized to housekeeping gene)

Phenotypic characterization of iPSC-derived macrophages - pan-macrophage surface marker expression

Quantification of pan-macrophage surface marker expression (CD68, CSFR1, CD163) by flow cytometry in iPSC-derived macrophages (iMACs) generated via embryoid body-based xeno-free protocol (Douthwaite et al., Bio Protoc. 2022). Pluripotency gene silencing is confirmed by RT-qPCR (SOX2, NANOG, OCT4 downregulation relative to parental iPSCs).

Unit of Measure:

% CD68+, % CSFR1+, % CD163+ cells (flow cytometry)

Transcriptomic characterization of iPSC-derived macrophages - inflammatory gene regulation

Single-cell RNA sequencing-based characterization of iPSC-derived macrophage transcriptional programs, including quantification of pro-inflammatory gene expression (CCL2, CCL8, FASN, LPIN1, IL-6) under baseline and autoantibody-stimulated conditions. Transcriptomic profiles are compared between SSc patient-derived and healthy control-derived iMAC lines.

Unit of Measure:

Normalized gene expression counts (single-cell RNA sequencing, scRNA-seq)

Characterization of iPSC-derived immune cells - antigen-presenting cell differentiation efficiency

Assessment of iPSC differentiation efficiency toward antigen-presenting cell lineages (dendritic cells and B/T lymphocyte precursors) using FLT3 overexpression-based differentiation protocol (Kitajima et al., Int. Immunol. 2023). Differentiation efficiency is quantified by flow cytometry using lineage-specific surface markers.

Unit of Measure:

% FLT3L-responsive antigen-presenting cell progenitors (flow cytometry)

Characterization of iPSC-derived bronchial epithelial cells - stepwise differentiation efficiency

Stepwise quantification of bronchial epithelial differentiation efficiency by immunofluorescence at three sequential stages: (1) definitive endoderm: % CXCR4+/SOX17+/FOXA2+ cells; (2) bronchial progenitor stage: % NKX2.1+ cells negative for thyroid marker TG and forebrain marker FOXG1; (3) final air-liquid interface epithelium (iALI): % mucus-secreting cells (MUC5AC+) and % ciliated cells (acetylated alpha-tubulin+).

Unit of Measure:

% CXCR4+/SOX17+/FOXA2+ cells at endoderm stage; % NKX2.1+/TG-/FOXG1- cells at progenitor stage; % MUC5AC+ and % acetylated alpha-tubulin+ cells at final iALI stage (immunofluorescence)

Functional characterization of iPSC-derived bronchial air-liquid interface epithelium (iALI) - barrier integrity and mucociliary function

Functional assessment of iPSC-derived air-liquid interface bronchial epithelium (iALI) obtained after 4-6 weeks of directed differentiation. Epithelial barrier integrity is quantified by transepithelial electrical resistance (TEER, ohm·cm²) on Transwell inserts. Mucociliary function is assessed by ciliary beat frequency measured by high-speed video microscopy (Hz). Results are compared between SSc patient-derived and healthy control-derived iALI cultures.

Unit of Measure:

Transepithelial electrical resistance (TEER, ohm·cm²); ciliary beat frequency (Hz, video microscopy)