Han Liu scite author profile

The microsporidian Nosema bombycis is an obligate intracellular pathogen of the silkworm Bombyx mori, causing the epidemic disease Pebrine and extensive economic losses in sericulture. Although N. bombycis forms spores with rigid spore walls that protect against various environmental pressures, ingested spores germinate immediately under the extremely alkaline host gut condition (Lepidoptera gut pH > 10.5), which is a key developmental turning point from dormant state to infected state. However, to date this process remains poorly understood due to the complexity of the animal digestive tract and the lack of genetic tools for microsporidia. Here we show, using an in vitro spore germination model, how the proteome of N. bombycis changes during germination, analyse specific metabolic pathways employed in detail, and validate key functional proteins in vivo in silkworms. By a label-free quantitative proteomics approach that is directly based on high-resolution mass spectrometry (MS) data, a total of 1136 proteins were identified with high confidence, with 127 proteins being significantly changed in comparison to non-germinated spores. Among them, structural proteins including polar tube protein 1 and 3 and spore wall protein (SWP) 4 and 30 were found to be significantly down-regulated, but SWP9 significantly up-regulated. Some nucleases like polynucleotide kinase/phosphatase and flap endonucleases 1, together with a panel of hydrolases involved in protein degradation and RNA cleavage were overrepresented too upon germination, which implied that they might play important roles during spore germination. The differentially regulated trends of these genes were validated, respectively, by quantitative RT-PCR and 3 proteins of interest were confirmed by Western blotting analyses in vitro and in vivo. Furthermore, the pathway analysis showed that abundant up- and down-regulations appear involved in the glycolysis, pentose phosphate pathway, purine, and pyrimidine metabolism, suggesting preparations of energy generation and substance synthesis for the following invasion and proliferation inside the host. This report, to our knowledge, provides the first proteomic landscape of N. bombycis spores, and also a stepping stone on the way to further study of the unique infection mode of this economically important pathogen and other microsporidia in general.

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Transcriptome sequencing and characterization of ungerminated and germinated spores of <italic>Nosema bombycis</italic>

Liu

et al. 2016

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Nosema bombycis is an obligate intracellular parasitic fungus that utilizes a distinctive mechanism to infect Bombyx mori. Germination, an indispensible process through which microsporidia infect the host cells, is regarded as a key developmental turning point for microsporidia from dormant state to reproduction state. Thus, elucidating the transcriptome changes before and after germination is crucial for parasite control. However, the molecular basis of germination of microsporidia remains unknown. To investigate this germination process, the transcriptome of N. bombycis ungerminated spores and germinated spores were sequenced and analyzed. More than 60 million high-quality transcript reads were generated from these two groups using RNA-Seq technology. After assembly, 2756 and 2690 unigenes were identified, respectively, and subsequently annotated based on known proteins. After analysis of differentially expressed genes, 66 genes were identified to be differentially expressed (P ≤ 0.05) between these two groups. A protein phosphatase-associated gene was first identified to be significantly up-regulated as determined by RNA-Seq and immunoblot analysis, indicating that dephosphorylation might potentially contribute to microsporidia germination. The DEGs that encode proteins involved in glycometabolism, spore wall proteins and ricin B lectin of N. bombycis were also analyzed. Gene Ontology and Kyoto Encyclopedia of Genes and Genomes analyses revealed genes responsible for some specific biological functions and processes. The datasets generated in this study provide a basic characterization of the transcriptome changes in N. bombycis during germination. The analysis of transcriptome data and identification of certain functional genes which are robust candidate genes related to germination will help to provide a deep understanding of spore germination and invasion.

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Ricin-B-lectin enhances microsporidia <italic>Nosema bombycis</italic> infection in <italic>Bm</italic>N cells from silkworm <italic>Bombyx mori</italic>

Liu¹,

Li²,

Cai³

et al. 2016

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Nosema bombycis is an obligate intracellular parasitic fungus that utilizes a distinctive mechanism to infect Bombyx mori Spore germination can be used for host cell invasion; however, the detailed mechanism remains to be elucidated. The ricin-B-lectin (RBL) gene is significantly differentially regulated after N. bombycis spore germination, and NbRBL might play roles in spore germination and infection. In this study, the biological function of NbRBL was examined. Protein sequence analysis showed that NbRBL is a secreted protein that attaches to carbohydrates. The relative expression level of the NbRBL gene was low during the first 30 h post-infection (hpi) in BmN cells, and high expression was detected from 42 hpi. Gene cloning, prokaryotic expression, and antibody preparation for NbRBL were performed. NbRBL was detected in total and secreted proteins using western blot analysis. Subcellular localization analysis showed that NbRBL is an intracellular protein. Spore adherence and infection assays showed that NbRBL could enhance spore adhesion to BmN cells; the proliferative activities of BmN cells incubated with anti-NbRBL were higher than those in negative control groups after N. bombycis infection; and the treatment groups showed less damage from spore invasion. We therefore, propose that NbRBL is released during spore germination, enhances spore adhesion to BmN cells, and contributes to spore invasion.

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Proteomic analysis of <italic>Bm</italic>N cells (<italic>Bombyx mori</italic>) in response to infection with <italic>Nosema bombycis</italic>

He¹,

He²,

Liu³

et al. 2014

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Nosema bombycis (N. bombycis, Nb) is an obligate intracellular parasite, which can cause pebrine disease in the silkworm. To investigate the effects of N. bombycis infection on the host cells, proteomes from BmN cells that had or had not been infected with N. bombycis at different infection stages were characterized with two-dimensional gel electrophoresis and MALDI-TOF/TOF mass spectrometry, which identified 24 differentially expressed host proteins with significant intensity differences (P < 0.05) at least at one time point in mock-and N. bombycis infected cells. Notably, gene ontology analyses showed that these proteins are involved in many important biological reactions. During the infection phase, proteins involved in energy metabolism and oxidative stress had up-regulated expression. Two proteins participated in ubiquitin-dependent protein catabolic process had down-regulated expression. Quantitative real-time polymerase chain reaction was used to analyze the transcriptional profiles of these identified proteins. Taken together, the abundance changes, putative functions, and participation in biological reactions for the identified proteins produce a host-responsive protein model in N. bombycisinfected BmN cells. These findings further our knowledge about the effect of energy defect parasites on the host cells.

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Proteomic analysis of silkworm midgut cellular proteins interacting with the 5′ end of infectious flacherie virus genomic RNA

Li¹,

He²,

Liu³

et al. 2015

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The flacherie disease in the silkworm is caused by the infectious flacherie virus (IFV). IFV relies on its 5' region of genomic RNA to recruit host-related factors to implement viral translation and replication. To identify host proteins bound to the 5'-region of IFV RNA and identify proteins important for its function, mass spectrometry was used to identify proteins from silkworm midgut extracts that were obtained using RNA aptamer-labeled 5' region of IFV RNA. We found 325 protein groups (unique peptide≥2) bound to the 5' region of IFV RNA including translation-related factors (16 ribosomal subunits, 3 eukaryotic initiation factor subunits, 1 elongation factor subunit and 6 potential internal ribosome entry site trans-acting factors), cytoskeleton-related proteins, membrane-related proteins, metabolism enzymes, and other proteins. These results can be used to study the translation and replication related factors of IFV interacting with host silkworm and to control flacherie disease in silkworm.

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Han Liu

Quantitative Proteomic Analysis of Germination of Nosema bombycis Spores under Extremely Alkaline Conditions

Transcriptome sequencing and characterization of ungerminated and germinated spores of <italic>Nosema bombycis</italic>

Ricin-B-lectin enhances microsporidia <italic>Nosema bombycis</italic> infection in <italic>Bm</italic>N cells from silkworm <italic>Bombyx mori</italic>

Proteomic analysis of <italic>Bm</italic>N cells (<italic>Bombyx mori</italic>) in response to infection with <italic>Nosema bombycis</italic>

Proteomic analysis of silkworm midgut cellular proteins interacting with the 5′ end of infectious flacherie virus genomic RNA

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Han Liu

Quantitative Proteomic Analysis of Germination of Nosema bombycis Spores under Extremely Alkaline Conditions

Transcriptome sequencing and characterization of ungerminated and germinated spores of &lt;italic&gt;Nosema bombycis&lt;/italic&gt;

Ricin-B-lectin enhances microsporidia &lt;italic&gt;Nosema bombycis&lt;/italic&gt; infection in &lt;italic&gt;Bm&lt;/italic&gt;N cells from silkworm &lt;italic&gt;Bombyx mori&lt;/italic&gt;

Proteomic analysis of &lt;italic&gt;Bm&lt;/italic&gt;N cells (&lt;italic&gt;Bombyx mori&lt;/italic&gt;) in response to infection with &lt;italic&gt;Nosema bombycis&lt;/italic&gt;

Proteomic analysis of silkworm midgut cellular proteins interacting with the 5&prime; end of infectious flacherie virus genomic RNA

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Transcriptome sequencing and characterization of ungerminated and germinated spores of <italic>Nosema bombycis</italic>

Ricin-B-lectin enhances microsporidia <italic>Nosema bombycis</italic> infection in <italic>Bm</italic>N cells from silkworm <italic>Bombyx mori</italic>

Proteomic analysis of <italic>Bm</italic>N cells (<italic>Bombyx mori</italic>) in response to infection with <italic>Nosema bombycis</italic>

Proteomic analysis of silkworm midgut cellular proteins interacting with the 5′ end of infectious flacherie virus genomic RNA