fumigatus disseminates rapidly in cyclophosphamide-treated mice At day one post-infection (Figure 12), histopathology revealed no significant histological lesion but rare neutrophils could be observed in bronchiolar spaces (Figure 12A, C). Non-germinating and rare early-germinating conidia were detected
throughout bronchiolar and alveolar spaces (Figure 12B, D). As in the cortisone acetate-treated mice, intrabronchiolar fungi (Figure 12F) were seen at a more advanced stage of maturation than intra-alveolar fungal cells (Figure 12E). However, hyphal branching was rarely observed at the early stage, even in intrabronchiolar regions (Table 1), confirming the data from the quantitative learn more analysis of the fungal DNA from infected lungs, which implied, despite the small animal group studied, that conidia germination is delayed under cyclophosphamide compared selleck chemicals to the cortisone acetate treatment (Figure 2). Figure 12 In the early stage, A. fumigatus germination was delayed after cyclophosphamide treatment. (A): At a low magnification, no significant
histological lesion was observed. B: Only small clusters of conidia were multifocally detected (arrowheads). C. At a high magnification, only small infiltrates of neutrophils were noted in bronchiolar and alveolar spaces. (D): Non-germinated and early germinating conidia were observed in these inflammatory infiltrates. (E): Intra-alveolar conidia at a very early stage of germination (swollen
conidia). Some conidia were observed in the cytoplasm of alveolar macrophages (arrowhead). (F): Intra-bronchiolar conidia were either swollen or started to form hyphae. Note that this stage of maturation is much less pronounced than Edoxaban observed in the early stage of cortisone acetate (Figure 6D) and RB6-8C5 treatment (Figure 9D). A, C: HE staining; B, D, E, F: GMS staining. In contrast, the late stage of pulmonary infection (Figure 13) was characterised by a severe and diffuse destruction of bronchoalveolar structures (Figure 13A), without any inflammatory cell infiltrate (Table 1). The parenchyma destruction was due to severe fungal parenchymal and vascular wall infiltration, leading to thrombosis and infarcts (Figure 13B). Bronchial, bronchiolar, and alveolar epithelial cells were necrotic (Figure 13C). Grocott methenamine silver staining showed a high number of mature septated fungal hyphae, spreading diffusely from bronchiolar spaces to alveoli and infiltrating blood vessels (Figure 13D), as already assumed from the increasing bioluminescent signal and the high amount of fungal DNA obtained from these tissues (Figure 2). Collectively these results demonstrate that immune effector cells recruitment is vital to limit hyphal growth and dissemination. Figure 13 In the late stage after cyclophosphamide treatment no inflammatory response was observed and A. fumigatus rapidly colonised the pulmonary parenchyma.