Your search keyword '"Lin, Shin-Jen"' showing total 5 results

1. The opportunistic marine pathogen Vibrio parahaemolyticus becomes virulent by acquiring a plasmid that expresses a deadly toxin

Author

Lee, Chung-Te, Chen, I-Tung, Yang, Yi-Ting, Ko, Tzu-Ping, Huang, Yun-Tzu, Huang, Jiun-Yan, Huang, Ming-Fen, Lin, Shin-Jen, Chen, Chien-Yu, Lin, Shih-Shun, Lightner, Donald V., Wang, Han-Ching, Wang, Andrew H.-J., Wang, Hao-Ching, Hor, Lien-I, and Lo, Chu-Fang

Published

2015

2. Expression of the AHPND Toxins PirA vp and PirB vp Is Regulated by Components of the Vibrio parahaemolyticus Quorum Sensing (QS) System.

Author

Lin, Shin-Jen, Huang, Jiun-Yan, Le, Phuoc-Thien, Lee, Chung-Te, Chang, Che-Chang, Yang, Yi-Yuan, Su, Emily Chia-Yu, Lo, Chu-Fang, and Wang, Hao-Ching

Subjects

*TOXINS, *BINDING sites, *VIRULENCE of bacteria, *PROMOTERS (Genetics), *VIBRIO parahaemolyticus, *GENETIC regulation

Abstract

Acute hepatopancreatic necrosis disease (AHPND) in shrimp is caused by Vibrio strains that harbor a pVA1-like plasmid containing the pirA and pirB genes. It is also known that the production of the PirA and PirB proteins, which are the key factors that drive the observed symptoms of AHPND, can be influenced by environmental conditions and that this leads to changes in the virulence of the bacteria. However, to our knowledge, the mechanisms involved in regulating the expression of the pirA/pirB genes have not previously been investigated. In this study, we show that in the AHPND-causing Vibrio parahaemolyticus 3HP strain, the pirAvp and pirBvp genes are highly expressed in the early log phase of the growth curve. Subsequently, the expression of the PirAvp and PirBvp proteins continues throughout the log phase. When we compared mutant strains with a deletion or substitution in two of the quorum sensing (QS) master regulators, luxO and/or opaR (luxOD47E, ΔopaR, ΔluxO, and ΔopaRΔluxO), our results suggested that expression of the pirAvp and pirBvp genes was related to the QS system, with luxO acting as a negative regulator of pirAvp and pirBvp without any mediation by opaRvp. In the promoter region of the pirAvp/pirBvp operon, we also identified a putative consensus binding site for the QS transcriptional regulator AphB. Real-time PCR further showed that aphBvp was negatively controlled by LuxOvp, and that its expression paralleled the expression patterns of pirAvp and pirBvp. An electrophoretic mobility shift assay (EMSA) showed that AphBvp could bind to this predicted region, even though another QS transcriptional regulator, AphAvp, could not. Taken together, these findings suggest that the QS system may regulate pirAvp/pirBvp expression through AphBvp. [ABSTRACT FROM AUTHOR]

Published

2022

3. A model for apoptotic interaction between white spot syndrome virus and shrimp

Author

Leu, Jiann-Horng, Lin, Shin-Jen, Huang, Jiun-Yan, Chen, Tsan-Chi, and Lo, Chu-Fang

Subjects

*WHITE spot syndrome virus, *APOPTOSIS, *DNA viruses, *SHRIMP diseases, *VIRAL envelopes, *SHRIMP culture, *ANTIVIRAL agents, *IMMUNITY, *INVERTEBRATES, *CRUSTACEA

Abstract

Abstract: White spot syndrome virus (WSSV) is an enveloped, large dsDNA virus that mainly infects penaeid shrimp, causing serious damage to the shrimp aquaculture industry. Like other animal viruses, WSSV infection induces apoptosis. Although this occurs even in by-stander cells that are free of WSSV virions, apoptosis is generally regarded as a kind of antiviral immune response. To counter this response, WSSV has evolved several different strategies. From the presently available literature, we construct a model of how the host and virus both attempt to regulate apoptosis to their respective advantage. The basic sequence of events is as follows: first, when a WSSV infection occurs, cellular sensors detect the invading virus, and activate signaling pathways that lead to (1) the expression of pro-apoptosis proteins, including PmCasp (an effecter caspase), MjCaspase (an initiator caspase) and voltage-dependent anion channel (VDAC); and (2) mitochondrial changes, including the induction of mitochondrial membrane permeabilization and increased oxidative stress. These events initiate the apoptosis program. Meanwhile, WSSV begins to express its genes, including two anti-apoptosis proteins: AAP-1, which is a direct caspase inhibitor, and WSV222, which is an E3 ubiquitin ligase that blocks apoptosis through the ubiquitin-mediated degradation of shrimp TSL protein (an apoptosis inducer). WSSV also induces the expression of a shrimp anti-apoptosis protein, Pm-fortilin, which can act on Bax to inhibit mitochondria-triggered apoptosis. This is a life and death struggle because the virus needs to prevent apoptosis in order to replicate. If WSSV succeeds in replicating in sufficient numbers, this will result in the death of the infected penaeid shrimp host. [Copyright &y& Elsevier]

Published

2013

4. Spawning stress triggers WSSV replication in brooders via the activation of shrimp STAT

Author

Lin, Shin-Jen, Hsia, Hui-Lan, Liu, Wang-Jing, Huang, Jiun-Yan, Liu, Kuan-Fu, Chen, Wei-Yu, Yeh, Ying-Chun, Huang, Yun-Tzu, Lo, Chu-Fang, Kou, Guang-Hsiung, and Wang, Han-Ching

Subjects

*WHITE spot syndrome virus, *VIRAL replication, *INCUBATORS, *FISH spawning, *SHRIMP culture, *EPIDEMICS, *FISH diseases

Abstract

Abstract: In the early days of shrimp aquaculture, wild-captured brooders usually spawned repeatedly once every 2–4days. However, since the first outbreaks of white spot disease (WSD) nearly 20years ago, captured female brooders often died soon after a single spawning. Although these deaths were clearly attributable to WSD, it has always been unclear how spawning stress could lead to an outbreak of the disease. Using real-time qPCR, we show here that while replication of the white spot syndrome virus (WSSV; the causative agent of WSD) is triggered by spawning, there was no such increase in the levels of another shrimp DNA virus, IHHNV (infectious hypodermal and hematopoietic necrosis virus). We also show that levels of activated STAT are increased in brooders during and after spawning, which is important because shrimp STAT is known to transactivate the expression of the WSSV immediate early gene ie1. Lastly, we used dsRNA silencing experiment to show that both WSSV ie1 gene expression and WSSV genome copy number were reduced significantly after shrimp STAT was knocked-down. This is the first report to demonstrate in vivo that shrimp STAT is important for WSSV replication and that spawning stress increases activated STAT, which in turn triggers WSSV replication in WSSV-infected brooders. [Copyright &y& Elsevier]

Published

2012

5. A shrimp glycosylase protein, PmENGase, interacts with WSSV envelope protein VP41B and is involved in WSSV pathogenesis.

Author

Huang, Jiun-Yan, Wang, Hao-Ching, Chen, Yu-Chun, Wang, Po-Sue, Lin, Shin-Jen, Chang, Yun-Shiang, Liu, Kuan-Fu, and Lo, Chu-Fang

Subjects

*WHITE spot syndrome virus, *PENAEUS monodon, *SHRIMPS, *CYTOSKELETAL proteins, *MEMBRANE fusion, *COAT proteins (Viruses)

Abstract

Viral glycoproteins are expressed by many viruses, and during infection they usually play very important roles, such as receptor attachment or membrane fusion. The mature virion of the white spot syndrome virus (WSSV) is unusual in that it contains no glycosylated proteins, and there are currently no reports of any glycosylation mechanisms in the pathogenesis of this virus. In this study, we cloned a glycosylase, mannosyl-glycoprotein endo-β-N-acetylglucosaminidase (ENGase, EC 3.2.1.96), from Penaeus monodon and found that it was significantly up-regulated in WSSV-infected shrimp. A yeast two-hybrid assay showed that PmENGase interacted with both structural and non-structural proteins, and GST-pull down and co-immunoprecipitation (Co-IP) assays confirmed its interaction with the envelope protein VP41B. In the WSSV challenge tests, the cumulative mortality and viral copy number were significantly decreased in the PmEngase -silenced shrimp, from which we conclude that shrimp glycosylase interacts with WSSV in a way that benefits the virus. Lastly, we speculate that the deglycosylation activity of PmENGase might account for the absence of glycosylated proteins in the WSSV virion. • PmENGase was up-regulated after WSSV infection. • PmENGase interacted with several WSSV structural and non-structural proteins in a yeast two-hybrid system. • PmENGase interacted with WSSV VP41B in a GST-pull down assay and in an S2 cell system. • WSSV activity was significantly decreased in PmENGase -silenced shrimp. • We confirmed the WSSV virion has no glycosylated proteins and also found shrimp ENGase acts as a glycosidase enzyme. [ABSTRACT FROM AUTHOR]

Published

2020