The wingless-related integration site(WNT)proteins are a family of secreted glycoproteins that are evolutionarily conserved and are believed to be involved in evolution in vertebrates and invertebrates.WNT signaling p...The wingless-related integration site(WNT)proteins are a family of secreted glycoproteins that are evolutionarily conserved and are believed to be involved in evolution in vertebrates and invertebrates.WNT signaling pathways may be associated with limb regeneration and development in crustaceans.However,the detail mechanisms remain unclear.Therefore,the distribution of WNT4 in the hepatopancreas,muscle,hemocyte,ganglion,heart,eyestalk,gill tissue,and diff erent larvae development stages of the swimming crab(Portunus trituberculatus)were characterized using immunofl uorescence,real-time PCR,and Western blotting.Signifi cant PtWNT4 expression was detected in heart and eyestalk.In addition,PtWNT4 was expressed in all larval stages of P.trituberculatus with a dynamic expression pattern,especially in the eyestalk and other organs in the carapace area.The injection of WNT4 dsRNA into regenerative limbs signifi cantly decreased PtWNT4 mRNA levels in the eyestalk,heart,and muscle,resulting in 1.9-fold,2.2-fold,and 2.7-fold decreases compared with those detected in the group injected with crab saline(P<0.05),respectively,indicating successful gene silencing.Overall,expression analysis on the WNT4 using RNAi provides an insight to its functional mechanism during limb regeneration in P.trituberculatus.The results not only demonstrated the requirement for WNT4 in limb regeneration of Crustaceans,but also suggested its ability to promote larval development at specifi c stages.展开更多
Background:Keloid scarring is a fibroproliferative disease caused by aberrant genetic activation with an unclear underlying mechanism.Genetic predisposition,aberrant cellular responses to environmental factors,increas...Background:Keloid scarring is a fibroproliferative disease caused by aberrant genetic activation with an unclear underlying mechanism.Genetic predisposition,aberrant cellular responses to environmental factors,increased inflammatory cytokines and epithelial-mesenchymal transition(EMT)phenomena are known as major contributors.In this study,we aimed to identify the molecular drivers that initiate keloid pathogenesis.Methods:Bulk tissue RNA sequencing analyses of keloid and normal tissues along with ex vivo and in vitro tests were performed to identify the contributing genes to keloid pathogenesis.An animal model of inflammatory keloid scarring was reproduced by replication of a skin fibrosis model with intradermal bleomycin injection in C57BL/6 mice.Results:Gene set enrichment analysis revealed upregulation of Wnt family member 5A(WNT5A)expression and genes associated with EMT in keloid tissues.Consistently,human keloid tissues and the bleomycin-induced skin fibrosis animal model showed significantly increased expression ofWNT5A and EMT markers.Increased activation of the interleukin(IL)-6/Janus kinase(JAK)/signal transducer and activator of transcription(STAT)pathway and subsequent elevation of EMT markerswas also observed in keratinocytes co-cultured withWNT5A-activated fibroblasts or keloid fibroblasts.Furthermore,WNT5A silencing and the blockage of IL-6 secretion via neutralizing IL-6 antibody reversed hyperactivation of the STAT pathway and EMT markers in keratinocytes.Lastly,STAT3 silencing significantly reduced the EMT-like phenotypes in both keratinocytes and IL-6-stimulated keratinocytes.Conclusions:Intercellular communication via the WNT5A and STAT pathways possibly underlies a partial mechanism of EMT-like phenomena in keloid pathogenesis.IL-6 secreted from WNT5A-activated fibroblasts or keloid fibroblasts activates the JAK/STAT signaling pathway in adjacent keratinocytes which in turn express EMT markers.A better understanding of keloid development and the role of WNT5A in EMT will promote the development of next-generation targeted treatments for keloid scars.展开更多
Seahorses are a hallmark of specialized morphological features due to their elongated prehensile tail.However,the underlying genomic grounds of seahorse tail development remain elusive.Herein,we evaluated the roles of...Seahorses are a hallmark of specialized morphological features due to their elongated prehensile tail.However,the underlying genomic grounds of seahorse tail development remain elusive.Herein,we evaluated the roles of essential genes from the Wnt gene family for the tail developmental process in the lined seahorse(Hippocampus erectus).Comparative genomic analysis revealed that the Wnt gene family is conserved in seahorses.The expression profiles and in situ hybridization suggested that Wnt5a,Wnt8a,and Wnt11 may participate in seahorse tail development.Like in other teleosts,Wnt5a and Wntll were found to regulate the development of the tail axial mesoderm and tail somitic mesoderm,respectively.However,a significantly extended expression period of Wnt8a during seahorse tail development was observed.Signaling pathway analysis further showed that Wnt5a up-regulated the expression of the tail axial mesoderm gene(Shh),while interaction analysis indicated that Wnt8a could promote the expression of Wntll.In summary,our results indicate that the special extended expression period of Wnt8a might promote caudal tail axis formation,which contributes to the formation of the elongated tail of the seahorse.展开更多
基金Supported by the National Natural Science Foundation of China(No.31602152)the Major Agriculture Program of Ningbo(No.2017C110007)the K.C.Wong Magana Fund in Ningbo University.The funding body had no role in the study design,experimental implementation,interpretation of data,or writing of the manuscript。
文摘The wingless-related integration site(WNT)proteins are a family of secreted glycoproteins that are evolutionarily conserved and are believed to be involved in evolution in vertebrates and invertebrates.WNT signaling pathways may be associated with limb regeneration and development in crustaceans.However,the detail mechanisms remain unclear.Therefore,the distribution of WNT4 in the hepatopancreas,muscle,hemocyte,ganglion,heart,eyestalk,gill tissue,and diff erent larvae development stages of the swimming crab(Portunus trituberculatus)were characterized using immunofl uorescence,real-time PCR,and Western blotting.Signifi cant PtWNT4 expression was detected in heart and eyestalk.In addition,PtWNT4 was expressed in all larval stages of P.trituberculatus with a dynamic expression pattern,especially in the eyestalk and other organs in the carapace area.The injection of WNT4 dsRNA into regenerative limbs signifi cantly decreased PtWNT4 mRNA levels in the eyestalk,heart,and muscle,resulting in 1.9-fold,2.2-fold,and 2.7-fold decreases compared with those detected in the group injected with crab saline(P<0.05),respectively,indicating successful gene silencing.Overall,expression analysis on the WNT4 using RNAi provides an insight to its functional mechanism during limb regeneration in P.trituberculatus.The results not only demonstrated the requirement for WNT4 in limb regeneration of Crustaceans,but also suggested its ability to promote larval development at specifi c stages.
基金supported by the Health Fellowship Foundation,Seoul,Korea.
文摘Background:Keloid scarring is a fibroproliferative disease caused by aberrant genetic activation with an unclear underlying mechanism.Genetic predisposition,aberrant cellular responses to environmental factors,increased inflammatory cytokines and epithelial-mesenchymal transition(EMT)phenomena are known as major contributors.In this study,we aimed to identify the molecular drivers that initiate keloid pathogenesis.Methods:Bulk tissue RNA sequencing analyses of keloid and normal tissues along with ex vivo and in vitro tests were performed to identify the contributing genes to keloid pathogenesis.An animal model of inflammatory keloid scarring was reproduced by replication of a skin fibrosis model with intradermal bleomycin injection in C57BL/6 mice.Results:Gene set enrichment analysis revealed upregulation of Wnt family member 5A(WNT5A)expression and genes associated with EMT in keloid tissues.Consistently,human keloid tissues and the bleomycin-induced skin fibrosis animal model showed significantly increased expression ofWNT5A and EMT markers.Increased activation of the interleukin(IL)-6/Janus kinase(JAK)/signal transducer and activator of transcription(STAT)pathway and subsequent elevation of EMT markerswas also observed in keratinocytes co-cultured withWNT5A-activated fibroblasts or keloid fibroblasts.Furthermore,WNT5A silencing and the blockage of IL-6 secretion via neutralizing IL-6 antibody reversed hyperactivation of the STAT pathway and EMT markers in keratinocytes.Lastly,STAT3 silencing significantly reduced the EMT-like phenotypes in both keratinocytes and IL-6-stimulated keratinocytes.Conclusions:Intercellular communication via the WNT5A and STAT pathways possibly underlies a partial mechanism of EMT-like phenomena in keloid pathogenesis.IL-6 secreted from WNT5A-activated fibroblasts or keloid fibroblasts activates the JAK/STAT signaling pathway in adjacent keratinocytes which in turn express EMT markers.A better understanding of keloid development and the role of WNT5A in EMT will promote the development of next-generation targeted treatments for keloid scars.
基金This work was supported by the K.C.Wong Education Foundation,the National Natural Science Foundation of China(nos.41825013,41706178,41576145,41806189,32000350)the China postdoctoral science foundation grant(no.2019M663151),the Guangdong Special Support Program of Youth Scientific and Technological Innovation(2017TQ04Z269)We are also grateful to Wenqi Hu for help with cell culture.
文摘Seahorses are a hallmark of specialized morphological features due to their elongated prehensile tail.However,the underlying genomic grounds of seahorse tail development remain elusive.Herein,we evaluated the roles of essential genes from the Wnt gene family for the tail developmental process in the lined seahorse(Hippocampus erectus).Comparative genomic analysis revealed that the Wnt gene family is conserved in seahorses.The expression profiles and in situ hybridization suggested that Wnt5a,Wnt8a,and Wnt11 may participate in seahorse tail development.Like in other teleosts,Wnt5a and Wntll were found to regulate the development of the tail axial mesoderm and tail somitic mesoderm,respectively.However,a significantly extended expression period of Wnt8a during seahorse tail development was observed.Signaling pathway analysis further showed that Wnt5a up-regulated the expression of the tail axial mesoderm gene(Shh),while interaction analysis indicated that Wnt8a could promote the expression of Wntll.In summary,our results indicate that the special extended expression period of Wnt8a might promote caudal tail axis formation,which contributes to the formation of the elongated tail of the seahorse.
