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The protocol described above allows for an objective semiquantitative evaluation of collagen deposition in murine lung tissue. Fibrotic remodeling is the pathophysiological hallmark of chronic rejection after lung transplantation. Therefore, Picrosirius Red staining was applied in chronic lung allograft rejection models using left-sided murine orthotopic lung transplantation. The major MHC-mismatched lung transplantation from a BALB/c donor to a C57BL/6 recipient under mild immunosuppression results in fibrotic changes comparable to human chronic lung allograft dysfunction5. In contrast, minor MHC-mismatched transplantation from a C57BL/10 donor to a C57BL/6 recipient primarily results in lymphocytic bronchiolitis6. Figure 1 depicts the experimental setup in detail.
Figure 2 provides an overview of representative images from transplanted left lungs of the two models as well as a C57BL/6J isograft. Masson's Trichrome16, Herovici's17, and Picrosirius Red18 staining illustrates the extensive peribronchial and perivascular collagen deposition in the major MHC-mismatched model (Model 1, Figure 2B,D). In contrast, the minor mismatched model (Model 2) primarily shows dense lymphocytic infiltrates as reflected by Hematoxylin and Eosin staining (Figure 2F) and less intense collagen deposition (Figure 2G-J). In Picrosirius Red staining, the addition of the polarization filter reveals a primarily green appearance of the deposited fibers across both models (Figure 2E,J). In isograft controls, the presence of collagen is restricted to the direct peribronchial and perivascular borders (Figure 2K-O), similar to the structure of naïve murine lungs (Figure 3).
Both naïve left-sided lungs from BALB/c animals and right-sided lungs from C57BL/6J recipients show only a thin lining of collagen along the peribronchial and perivascular borders (Figure 3).
Digital image analysis of whole lung sections stained with Picrosirius Red revealed an increased presence of total collagen in the lung grafts in the major MHC-mismatched model when compared to the grafts from the minor mismatched model (p=0.0038), right-sided naïve lung tissue (p=0.0006) or naïve BALB/c left lungs (p=0.0003,One-way ANOVA, Tukey's multiple comparisons test, Figure 4A). For thick collagen fibers, which appear red under polarized light, differences between the groups could not be demonstrated (p=0.5512, One-way ANOVA, Figure 4B). However, the analysis of thin collagen fibers with a green appearance under polarized light revealed an increased presence in the major mismatched model when compared to the minor mismatched model (p=0.0005), naïve right-sided lung tissue (p<0.0001) or naïve left-sided BALB/c lungs (p<0.0001, One-way ANOVA, Tukey's multiple comparisons test, Figure 4C).

Figure 1: Overview of the experimental design. Orthotopic left lung transplantation was performed using a major (Model 1) and a minor mismatched strain combination (Model 2). Recipients of an MHC major mismatched graft received daily immunosuppression with 10 mg/kg Cyclosporine and 1.6 mg/kg Methylprednisolone by subcutaneous injection. All recipient animals were euthanized at eight weeks (day 56) postoperatively. Lung tissue was processed by formalin fixation, paraffin embedding, and sectioning. Consecutive sections were stained with Hematoxylin and Eosin (H&E), Masson's Trichrome (MTC), Herovici's, and Picrosirius Red (PSR) staining. Please click here to view a larger version of this figure.

Figure 2: Representative images of the peribronchiovascular region in transplanted lungs. (A-E) The major MHC-mismatched Model 1 results in peribronchial and perivascular fibrosis, as evidenced by Masson's Trichrome (MTC), Herovici's, and Picrosirius Red staining (PSR). This is also reflected by adding the polarization filter (PSR (pol)). (F-J) The minor MHC-mismatched Model 2 presents with prominent peribronchiovascular lymphocytic infiltrates, as demonstrated by Hematoxylin and Eosin staining (H&E). MTC and PSR staining only show a limited extent of collagen deposition in this model. (K-O) In isograft controls, collagen deposition is restricted to the direct peribronchiovascular regions. Lymphocytic infiltrates are scarce. Please click here to view a larger version of this figure.

Figure 3: Physiological extent of peribronchiovascular collagen presence in murine lungs. (A-E) Collagen presence in murine lung tissue is physiological to a certain extent without major strain dependence. In left-sided naïve BALB/c lungs, as used for the major mismatched model (Model 1), a thin lining of collagen can be seen in the peribronchiovascular area as evidenced by Masson's Trichrome (MTC), Herovici's and Picrosirius Red staining (PSR). (F-J) Similarly, a collagen lining restricted to the direct peribronchiovascular border is seen in the contralateral right lungs of recipient C57BL/6J origin. Abbreviations: H&E = Hematoxylin and Eosin staining; PSR (pol) = Picrosirius Red staining after adding the polarization filter. Please click here to view a larger version of this figure.

Figure 4: Picrosirius Red staining under polarized light reveals increased deposition of thin collagen fibers in the major MHC-mismatched murine transplantation model. Image analysis of polarized Picrosirius Red staining over the whole area of transversal lung sections. (A) Analysis of total collagen deposition reveals increased collagen deposition in the major mismatched model compared to minor mismatched allografts, contralateral recipient lungs, or naïve BALB/c left lung grafts. (B) No significant differences were found between the groups regarding thick collagen fibers. (C) Analysis of thin collagen fiber presence reveals increased deposition in major mismatched allografts compared to the minor mismatched group, contralateral recipient lungs, or naïve BALB/c left lung grafts. Graphs show mean ± standard error of the mean, One-way ANOVA, Tukey's multiple comparisons used for significance, * p < 0.05, ** p < 0.005, *** p < 0.0005, **** p < 0.0001, ns not significant. Please click here to view a larger version of this figure.