ABSTRACT
Objective To measure the expression of indoleamine 2, 3-dioxygenase(IDO)in condy-loma acuminatum (CA) lesions, and to evaluate its ability to locally metabolize tryptophan. Methods Immunohistochemical study was performed to observe the protein expression of IDO in skin lesions of patients with CA, and count the number of IDO-positive cells. Immunofluorescence assay was conducted to estimate the relationship between IDO-positive cells and dendritic cells. Epidermal cells and keratinocytes were isolated from warts of 30 patients with CA and prepuces of 11 healthy controls respectively, and both in vitro incubated with tryptophan solution for 4 hours. Then, high-performance liquid chromatography (HPLC)was performed to detect the level of tryptophan metabolite, kynurenine, in the culture supernatant of the above cells, which could reflect the ability of epidermal cells to metabolize tryptophan. Results Rare IDO-positive cells were found in the normal skin, but a lot of IDO-positive cells gathered in the epidermis of the wart tissues. The IDO-positive cell/total cell ratio was significantly higher in the wart tissues than in the normal skin(48.3%± 15.4%vs. 5.2%± 2.4%, P<0.05). The fluorescence signals of IDO-positive cells and CD1a-positive Langerhans cells were not overlapped with each other, suggesting that IDO-positive cells were derived from epidermal cells of the wart tissues. Compared with the keratinocytes from the healthy skin, the epidermal cells from warts had a stronger ability to metabolize tryptophan in vitro. Conclusion A large number of IDO-positive cells exist in CA warts, and may be involved in occurrence of CA.
ABSTRACT
To report a case of cutaneous and subcutaneous coinfection caused by Lichtheimia corymbifera and Candida parapsilosis.A 67-year-old female peasant consulted about proliferative granuloma developing on her left forearm after topical application of a Chinese herbal drug and splint fixation for the treatment of suspected fracture of the wrist.Direct microscopic examination showed gram positive budding yeast cells in lesion secretions.Pathological study with periodic acid-Schiff (PAS) and gormori methenamine silver (GMS) staining revealed broad non-separate hyphae in the corneum and dermis.Fungal culture of lesional tissue at 35℃ grew both mould and yeast.The mould was identified as Lichtheimia corymbifera based on morphological findings and sequences of the internal transcribed space (ITS) 1-4 regions.Thermal tolerance study revealed that the isolate grew fast at 37℃ but slowly at 40℃.Under a scanning electron microscope,the acrogenous sporangia were pear-shaped with conical sporangiophores originating from the top of stolon,which were among but not opposite to the rhizoids.The yeast was identified as Candida parapsilosis by Chromagar test and D1/D2 region sequencing.As antimicrobial susceptibility test indicated,the Lichtheimia corymbifera isolate was most sensitive to terbinafine and itraconazole.The proteolytic activity of Lichtheimia corymbifera was higher than that of Candida parapsilosis.The granuloma completely subsided after surgical resection and 6-week treatment with oral itraconazole 200 mg twice a day.No recurrence was observed during a 4-year follow-up.
ABSTRACT
Objective To partially purify the toxic factor secreted by A. corymbifera and to analyze the mechanism of A. corymbifera-induced human umbilical vein endothelial cell (HUVEC) apoptosis. Methods Glycoprotein secreted by A. corymbifera was purified by Con A Lectin chromatography. The influence of different protein fractions on HUVEC apoptosis was determined by flow eytometer. Both denaturing and nondenaturing deglycosylation of purified glycoprotein was performed and the ability of the protein moiety and carbohydrate moiety to induce HUVEC apoptosis was evaluated respectively. Activation of related caspases during A. corymbifera-induced apoptosis was analyzed by Western blot. The role of caspase-8 and -9 in HUVEC apoptosis was investigated using caspase inhibitors. Caspase inhibitors were used to stop the suppression of HUVEC viability by XTT assay. Results Flow cytometric analysis shows the total protein as well as the glycoprotein fraction of A. corymbifera may induce HUVEC apoptosis in a dose dependent manner. In contrast, similar activity was not observed in the non-glycoprotein fraction. Neither deglycosylated protein nor carbohydrate moiety is able to induce HUVEC apoptosis alone. In the apoptotic signaling pathway, caspase9, caspase-3 and cytochrome C were activated significantly, except caspase-8. Moreover, caspase-9 inhibitor, instead of caspase-8 inhibitor, completely abrogates A. corymbifera-induced HUVEC apoptosis. Caspase9 and caspase-3 inhibitors completely waived the suppression of HUVEC viability by A. corymbifera. Conclusion Glycoprotein secreted by A. corymbifera is associated with HUVEC apoptosis. Intact glycoprotein is essential for the apoptotic progress. Intrinsic apoptotic signaling pathway mediates A. corymbifera-induced HUVEC apoptosis.
ABSTRACT
Objective To analyze the influence of Absidia corymbifera on cell activity of human umbilical vein endothelial cells (HUVEC) as well as the related mechanism. Methods Time course analy sis of the influence of A. corymbifera on cell viability of HUVEC was determined by cell counting after Trypan blue staining. Apoptosis of HUVEC induced by A. corymbifera was observed under fluorescence microscope after treatment with apoptosis detection kit. Time course analysis of HUVEC apoptosis induced by A. corymbifera was detected by flow cytometry quantitatively. Effect of caspase-3 inhibitor on A. corymbifera associated apoptosis was also evaluated at the same time. Activation of caspase-3 inside HUVEC was detected by Western blot. Results A. corymbifera inhibited cell viability of HUVEC in a time-dependent manner by Trypan blue staining. After 12 hours' co-culture, A. corymbifera began to show suppression on cell viability (P =0. 001 ). Fluorescence microscope observation revealed A. corymbifera induced apoptosis of HUVEC instead of necrosis. Flow cytometry analysis showed A. corymbifera induced apoptosis of HUVEC in a time-dependent manner. A. corymbifera began to show obvious effect on apoptosis after 12 h co-culture (P =0.0036). Moreover, A. corymbifera-associated apoptosis was almost abrogated completely by caspase-3 inhibitor. Western blot analysis demonstrated that A. corymbifera triggered the activation of caspase-3 inside HUVEC in a timedependent fashion. Conclusion A. corymbifera induces apoptosis of HUVEC in vitro. Such apoptotic signal is transmitted through caspase cascade reaction.