Proteomic profiling of urinary small extracellular vesicles in children with pneumonia: a pilot study.

BACKGROUND: Small extracellular vesicles (sEV) play a crucial role in immune responses to viral infection. However, the composition of sEV derived from children with viral pneumonia remains ill defined. METHODS: First, we performed mass spectrometry-based label-free proteomic analysis of urinary sEV in 7 children with viral pneumonia, 4 children with Mycoplasma pneumoniae pneumonia and 20 healthy children. Then a total of 33 proteins were selected to validate by multiple reaction monitoring analysis in an independent cohort of 20 healthy children and 29 children with pneumonia. RESULTS: In the discovery phase, a total of 1621 proteins were identified, while 260 proteins have differential expression in children with viral pneumonia compared to healthy children. Biological pathways primarily associated with neutrophil degranulation, carbohydrate metabolism and endocytosis were enriched in children with viral pneumonia. Finally, the abundance of eight proteins was verified to be significantly higher in children with viral pneumonia than in healthy children. CONCLUSIONS: This pilot study with proteomic profiles of urinary sEV provided insights to the host response to viral pathogen exposure and potential diagnostic biomarkers for children with viral pneumonia, and served as the basis for understanding the fundamental biology of infection. IMPACT: There were significant differences in the proteomic features of urinary sEV between children with viral pneumonia and those with Mycoplasma pneumoniae pneumonia. Many viral infection-related proteins were identified in urinary sEV and overrepresented in children with viral pneumonia, which facilitates our understanding of the fundamental biology of viral infection. A total of eight proteins (ANPEP, ASAH1, COL11A1, EHD4, HEXB, LGALS3BP, SERPINA1 and SERPING1) were verified as potential biomarkers for the diagnosis of viral pneumonia in children.

Proteomic profiling of serum small extracellular vesicles reveals immune signatures of children with pneumonia.

Background: Pneumonia is the leading cause of death in young children globally. However, the underlying pathological mechanism of pediatric pneumonia remains unclear. In infection disease contexts, small extracellular vesicles (sEVs) have been shown to be a useful source of markers for pathogenesis and immune response. We hypothesized that functional molecules such as protein harbored by sEVs would provide mechanistic insights into the immune response in children with pneumonia. Methods: We isolated sEVs from serum collected from children with and without pneumonia, performed proteomic analysis of the sEVs with label-free mass spectrometry, and then conducted functional enrichment analysis of proteomic data. Results: We identified fifteen differentially expressed proteins and ten unique proteins in children with pneumonia as compared to healthy children. In the pneumonia group, immune-related processes and pathways were positively enriched as upregulated proteins were involved in neutrophil activation, complement regulation, defense against bacteria, humoral immune response and regulation of immune effector processes However, pathways associated with tissue development and extracellular matrix remodeling were negatively enriched, as downregulated proteins were linked to extracellular matrix structure and cell adhesions. Conclusions: Our findings provided insights into host responses to pathogen infection, which has contributed to understanding the pathogenesis of children with pneumonia. Furthermore, our studies suggested that serum sEVs proteins could be considered a potential source of biomarkers for diagnosing pediatric pneumonia.

ClC-7 Regulates the Pattern and Early Development of Craniofacial Bone and Tooth.

Human CLCN7 encodes voltage-gated chloride channel 7 (ClC-7); mutations of CLCN7 lead to osteopetrosis which is characterized by increased bone mass and impaired osteoclast function. In our previous clinical practice, we noticed that osteopetrosis patients with CLCN7 mutations had some special deformities in craniofacial morphology and tooth dysplasia. It is unclear whether these phenotypes are the typical features of CLCN7 involved osteopetrosis and whether ClC-7 could regulate the development of craniofacial bone and tooth in some signaling pathways. Methods: First, we collected 80 osteopetrosis cases from the literature and compared their craniofacial and dental phenotypes. Second, four osteopetrosis pedigrees with CLCN7 mutations were recruited from our clinic for gene testing and clinical analysis of their craniofacial and dental phenotypes. Third, we used a zebrafish model with clcn7 morpholino treatment to detect the effects of ClC-7 deficiency on the development of craniofacial and dental phenotypes. General observation, whole mount alcian blue and alizarin red staining, whole mount in situ hybridization, scanning electron microscope observation, lysoSensor staining, Q-PCR and western blotting were performed to observe the in vivo characteristics of craniofacial bone and tooth changes. Fourth, mouse marrow stromal cells were further primarily cultured to detect ClC-7 related mRNA and protein changes using siRNA, Q-PCR and western blotting. Results: Over 84% of osteopetrosis patients in the literature had some typical craniofacial and tooth phenotypes, including macrocephaly, frontal bossing, and changes in shape and proportions of facial skeleton, and these unique features are more severe and frequent in autosomal recessive osteopetrosis than in autosomal dominant osteopetrosis patients. Our four pedigrees with CLCN7 mutations confirmed the aforementioned clinical features. clcn7 knockdown in zebrafish reproduced the craniofacial cartilage defects and various dental malformations combined the decreased levels of col10a1, sp7, dlx2b, eve1, and cx43. Loss of clcn7 function resulted in lysosomal storage in the brain and jaw as well as downregulated cathepsin K (CTSK). The craniofacial phenotype severity also presented a dose-dependent relationship with the levels of ClC-7 and CTSK. ClC-7/CTSK further altered the balance of TGF-ß/BMP signaling pathway, causing elevated TGF-ß-like Smad2 signals and reduced BMP-like Smad1/5/8 signals in clcn7 morphants. SB431542 inhibitor of TGF-ß pathway partially rescued the aforementioned craniofacial bone and tooth defects of clcn7 morphants. The ClC-7 involved CTSK/BMP and SMAD changes were also confirmed in mouse bone marrow stromal cells. Conclusion: These findings highlighted the vital role of clcn7 in zebrafish craniofacial bone and tooth development and mineralization, revealing novel insights for the causation of osteopetrosis with CLCN7 mutations. The mechanism chain of ClC-7/CTSK/ TGF-ß/BMP/SMAD might explain the typical craniofacial bone and tooth changes in osteopetrosis as well as pycnodysostosis patients.

NEFLb impairs early nervous system development via regulation of neuron apoptosis in zebrafish.

Neurofilament light chain (NEFL), a subunit of neurofilament, has been shown to play an important role in pathogenic neurodegenerative disease and in radial axonal growth. However, information remains largely lacking regarding the function of NEFL in early development to date. In this study, we demonstrated the presence of two nefl genes, nefla and neflb, in zebrafish, generated by fish-specific third round genome duplication. These duplicated nefl genes were predominantly expressed in the nervous system with an overlapping and distinct expression pattern. Both gene knockdown and rescue experiments show that it was neflb rather than nefla that played an indispensable role in nervous system development. It was also found that neflb knockdown resulted in striking apoptosis of the neurons in the brain and spinal cord, leading to morphological defects such as brain structure disorder and trunk bending. Thus, we report a previously uncharacterized role of NEFL that NEFLb impairs the early development of zebrafish nervous system via regulation of the neuron apoptosis in the brain and spinal cord.

ATP6V1H regulates the growth and differentiation of bone marrow stromal cells.

ATP6V1H encodes subunit H of vacuolar ATPase (V-ATPase) and may regulate osteoclastic function. The deficiency of ATP6V1H caused bone loss in human, mouse and zebrafish. In this report, we identified the mechanisms by which ATP6V1H regulates proliferation and differentiation of bone marrow stromal cells (BMSCs). We found that ATP6V1H was expressed in BMSCs, and Atp6v1h+/- BMSCs exhibited the lower proliferation rate, cell cycle arrest and reduced osteogenic differentiation capacity, as well as the increased adipogenic potentials. Histologic analysis confirmed less bone formation and more fatty degeneration in Atp6v1h+/- mice in the different age groups. Q-PCR analysis revealed that loss of ATP6V1H function downregulated the mRNA level of TGF-ß1 receptor, and its binding molecule, subunit ß of adaptor protein complex 2 (AP-2), suggesting ATP6V1H regulates the proliferation and differentiation of BMSCs by interacting with TGF-ß receptor I and AP-2 complex.

Involvement of Lypge in the formation of eye and pineal gland in zebrafish.

The proteins of Ly-6 (lymphocyte antigen-6) family are involved in the regulation of immunoreaction, cell migration and adhesion, and neuronal excitability. However, little is known about the function of Ly-6 proteins in embryogenesis. Herein, we identified a GPI anchored Ly-6 member named ly6 expressed in pineal gland and eye (lypge). Dynamic expression pattern of lypge was revealed by whole mount in situ hybridization. It was strikingly expressed in the pineal gland and cone photoreceptor, and its expression was regulated by orthodenticle homolog 5 (otx5) which has been shown to control the expression of many pineal genes. In addition, we demonstrated that lypge was rhythmically expressed in larvae from 4dpf on. Moreover, knockdown of lypge resulted in small head and small eye formed in zebrafish embryos. These suggest that Lypge is involved in the formation of the eye and pineal gland in early development of zebrafish.

Evolutionary and Expression Analyses Show Co-option of khdrbs Genes for Origin of Vertebrate Brain.

Genes generated by whole genome duplications (WGD) can be co-opted by changing their regulation process or altering their coding proteins, which has been shown contributable to the emergence of vertebrate morphological novelties such as vertebrate cartilage. Mouse khdrbs genes, differing from its invertebrate orthologs, were mainly expressed in brain, hinting that khdrbs gene family as a member of genetic toolkit may be linked to vertebrate brain development. However, the evolutionary relationship between khdrbs gene family and vertebrate brain development is unclear. First, we analyzed the evolutionary history of khdrbs gene family in metazoans, and then investigated their expression patterns during early development and in adulthood of zebrafish. We found that the duplication of khdrbs gene family by WGD took place in zebrafish, and all zebrafish khdrbs genes were predominantly expressed in the substructures of brain during early development. Given the expression of invertebrate khdrbs gene in germ line, the distinct expression domains of zebrafish khdrbs genes in brain suggested that the duplicated khdrbs genes are co-opted for promoting the evolutionary origin of vertebrate brain.

Identification and expression of a new Ly6 gene cluster in zebrafish Danio rerio, with implications of being involved in embryonic immunity.

Lymphocyte antigen-6 (Ly6) superfamily is a large family of proteins and characterized by precisely spaced cysteine motifs, termed the three-finger fold. To date, a large number of members of the Ly6/uPAR family were identified among many species. In this study, we first report the identification and characterization of the secreted Ly2.1-3 proteins on the chromosome 2 in zebrafish and determine the expression pattern. Ly2.1-3 all possess a conserved LU domain and adopt similar three-finger structure with human CD59, SLURP1 and other Ly6 family members. Ly2.1-3 cluster on chromosome 2 and share high homology, possibly originated from chromosomal gene duplication. Ly2.1-3 exhibit distinct expression pattern in the endoderm, they were found abundantly and specifically in the digestive tract, liver and pancreas respectively. The differential expression pattern may suggest Ly2.1-3 acquire new function during gene duplication. The expression level of Ly2.1-3 were up-regulating challenged with LPS indicated that they have a role in innate immune responses of the digestive system during endotoxin challenge in early stage.

Identification and expression of lypc, a novel dark-inducible member of Ly6 superfamily in zebrafish Danio rerio.

Snake venom neurotoxins and lymphocyte antigen-6 (Ly6) family members identified in many metazoans possess conserved LU domain containing eight or ten conserved cysteine residues which form 4 to 5 conserved disulfide bonds. They are found to execute a wide variety of biological effects, but information regarding Ly6 superfamily in zebrafish remains rather limited. Here we identified a novel Ly6 gene located on the chromosome 15 in zebrafish, and named it lypc highlighting its predominant expression in the pigment cells. Both homology modeling and sequence comparison revealed that lypc has features typical of Ly6 family members. Whole mount in situ hybridization showed that lypc was expressed in the trunk pigment cells and retinal pigment cells. Moreover, real-time quantitative PCR demonstrated that the expression of lypc was subjected to diurnal variation regulation, i.e. the expression of lypc displays a clear rhythmic pattern, and dark exposure apparently stimulated its expression. Collectively, these data indicate that lypc is a novel dark-inducible Ly6 member with a predominant expression in the pigment cells of zebrafish, laying a foundation for further elucidation of its functions.

Identification and expression of an uncharacterized Ly-6 gene cluster in zebrafish Danio rerio.

The Ly-6/uPAR/CD59/neurotoxin superfamily (Ly-6SF) identified in most metazoan has been shown to play important roles in different biological processes including immunity, cellular adhesion, and cell signaling. Members of this superfamily contain one or more conserved domains known as Ly-6/uPAR (LU) domain, which harbors 8 or 10 conserved cysteine residues forming 4-5 disulfide bonds. In this study, we reported the identification of a novel zebrafish Ly-6 gene cluster on chromosome 21, which consists of seven genes ly21.1, ly21.2, ly21.3, ly21.4, ly21.5, ly21.6, and ly21.7 and their spatiotemporal expression pattern during development. All the seven genes possess features typical of the Ly-6/neurotoxin superfamily, and phylogenetic analysis shows that these genes form a single cluster branching form other members of Ly-6 family, suggesting that the seven genes evolved by an event of intra-chromosome gene duplication. However, deduced Ly21.1-7 proteins share little homology with Ly-6 family proteins from other species, no orthologs are identified in vertebrates, including teleosts, hinting that ly21.1-7 genes are evolutionarily a novel addition to zebrafish. Expression analyses show that maternal mRNAs of ly21.1-7 genes are detected during early developmental stages, but later in development, they exhibit tissue-specific expression. Except for ly21.2 which is expressed in the skin ionocytes, all the remaining six genes are mainly expressed in the developing brain.

Identification of a Ly-6 superfamily gene expressed in lateral line neuromasts in zebrafish.

Lymphocyte antigen-6 (Ly-6) superfamily members have been identified in zebrafish, but the expression and function of these Ly-6 genes remain largely unknown. Posterior lateral line (pLL) system is produced by migrating pLL primordium (pLLp). Chemokine signaling, Notch, Wnt, and fibroblast growth factor (FGF) signaling regulate migration of pLLp cells and formation of neuromasts. However, the mechanism of neuromast deposition remains to be explored. Identification of novel genes expressed in pLLp will certainly help the study of such a process. Here we identified a Ly-6 gene called neuromast-expressed gpi-anchored lymphocyte antigen-6 (negaly6), which was specifically expressed in neuromast. Quantitative real-time PCR (qRT-PCR) analysis showed that negaly6 started to be expressed at 24 hpf, and whole-mount in situ hybridization analysis indicated that negaly6 was highly expressed in the trailing zone of pLLp and mature neuromast. Furthermore, negaly6 expression was inhibited by FGF signaling antagonist but not by Wnt signaling agonist or antagonist. Collectively, these data indicate that negaly6 may be associated with the regulation of neuromast deposition via FGF signaling pathway.

Functional characterization of GH-like homolog in amphioxus reveals an ancient origin of GH/GH receptor system.

Amphioxus belongs to the subphylum cephalochordata, an extant representative of the most basal chordates. Despite many studies on the endocrine system of amphioxus, no evidence showed the presence of pituitary hormones. In this study, we clearly demonstrated the existence of a functional GH-like hormone in amphioxus, which is able to bind purified GH receptors, stimulate IGF-I expression, promote growth rate of fish, and rescue embryonic defects caused by a shortage of GH. We also showed the presence of a GH/prolactin-like-binding protein containing the entire hormone binding domain of GH/prolactin receptors in amphioxus, which is widely expressed among tissues, and interacts with the GH-like hormone. It is clear from these results that the GH/GH receptor-like system is present in amphioxus and, hence, in all classes of chordates. Notably, the GH-like hormone appears to be the only member of the vertebrate pituitary hormones family in amphioxus, suggesting that the hormone is the ancestral peptide that originated first in the molecular evolution of the pituitary hormones family in chordates. These data collectively suggest that a vertebrate-like neuroendocrine axis setting has already emerged in amphioxus, which lays a foundation for subsequent formation of hypothalamic-pituitary system in vertebrates.

Expression and functional analysis of properdin in zebrafish Danio rerio.

Properdin, an upregulator of the alternative complement pathway, has been thoroughly studied in the mammalian species, but its research in the lower vertebrates such as fish is rather limited. Additionally, information regarding the structure-activity relationship of properdin remains rather fragmentary. In this report, we showed that zebrafish properdin gene zfp was abundantly expressed in the liver of adult fish, while it was primarily expressed in the brain, neural plate, developing lens, and neutrophil in the early embryos/larvae. Recombinant TSR modules of zfP were demonstrated to be able to bind to C3b, LPS, LTA and both gram-negative and positive bacteria. Moreover, TSR5 of zfP was able to enhance the phagocytosis of microbes by macrophages. These results together support the notion that properdin is a pattern recognition molecule capable of identifying non-self antigens/structures, and indicate that TSR5 plays a central role in the capacity of properdin to promote phagocytosis. It is also suggested that properdin is associated with the pattern formation and immune defense of early developing embryos/larvae.

The DMRT gene family in amphioxus.

Doublesex and Mab-3-related transcription factor (DMRT) gene family is widely known for its involvement in sex determination and/or differentiation among different phyla. In this study, we identify eight DMRT genes in the cephalochordate amphioxus, a protochordate holding a key phylogenetic position. The eight DMRTs can be divided into two groups based on the conserved domain: BfDM044, BfDM045, BfDM55.1, BfDM115.1, and BfDM17.1 belong to the first group which have both DM and DMA domains, while BfDM246.1, BfDM084, and BfDM175 belong to the second group which have only DM domain. Most of the first group members have same genomic structure except BfDM17.1, while no regular pattern exists in the second group. Phylogenetic analysis of the DM domain sequences shows that DMRT genes in vertebrates form seven different independent clusters, and some even contain genes from invertebrates with high bootstrap. Notably, the first group members of amphioxus cluster with vertebrate DMRTs; while the second group members cluster into a single branch, which diverge from the vertebrate classes. The results suggest that several DMRT genes in vertebrates may evolve from homologous genes in invertebrates. As in nematode, drosophila, fish, and vertebrates, DMRT genes cluster is also found in amphioxus, which may be the result of gene duplication. Interspecific differences in the amphioxus DMRTs and sea squirt DMRTs may suggest post-speciation duplication of some DMRT genes.

Maternal transfer and protective role of antibodies in zebrafish Danio rerio.

Maternal transfer of antibodies from mother to eggs has been reported in various species of fishes, and these antibodies have been proposed to play immune roles in developing embryos and larvae. However, firm evidence supporting this remains lacking. In this study, we clearly demonstrated that immunization of female zebrafish with the hapten-carrier complex, trinitrophenylated bovine serum albumin (TNP-BSA), induced a significant increase in anti-TNP antibody production in the mothers, which in turn induced a marked increase in anti-TNP antibody level in their eggs. Microinjection of anti-zebrafish IgM antibody into early embryos (to neutralize endogenous antibody action) resulted in a remarkable decrease in the resistance of recipient embryos to pathogenic Aeromonas hydrophila, whereas injection of BSA or anti-ß-actin monoclonal antibody into the same stage embryos had little effect on their resistance to the pathogen. Moreover, the content of endogenous antibodies in eggs was clearly correlated with their antibacterial activity against A. hydrophila. This is the first report showing that maternally transferred antibodies in fish can protect early embyros/larvae from the attack of pathogens like A. hydrophila.

Identification and expression of a novel member of Ly-6 superfamily in zebrafish Denio rerio.

Ly-6 superfamily members are present in many metazoans and are divided into two groups: secreted proteins and glycosylphosphatidyl inositol (GPI)-anchored membrane proteins. They both contain one or more conserved domain identified as Ly-6/uPAR (LU) domain and play key roles in cellular adhesion and signaling. Here, we identify a novel member, lymphocyte antigen-6 epidermis (lye), of Ly-6 superfamily in zebrafish. In silico analyses revealed that lye codes for a predicted GPI-anchored membrane protein containing a conserved LU domain and 10 position-specific conserved cysteines typical of known Ly-6 proteins. Whole mount in situ hybridization showed that lye is predominantly expressed in epidermis. We thus named the gene lye, highlighting it is expressed in epidermis. Lye exhibits a dynamic expression pattern during development, which is initially expressed in enveloping layer at gastrula stage, then expressed in epidermis at later stages. It is also expressed in olfactory placode at 24 h post-fertilization. Subsequently, epidermal expression of lye becomes weaker gradually, whereas the expression in pharyngeal arch and pectoral fin increases at 2 and 3 days post-fertilization. Our study lays a foundation for further investigation of lye roles in early developmental stages.