Antiviral Activity of Ctn[15-34], A Cathelicidin-Derived Eicosapeptide, Against Infectious Myonecrosis Virus in Litopenaeus vannamei Primary Hemocyte Cultures.

The shrimp farming has been converted into a mature aquaculture industry dealing with over millions of metric tonnes of processed commodities. Nevertheless, the global shrimp productions are constantly threatened by disease outbreaks, mainly triggered by rapidly disseminating viruses. Infectious myonecrosis virus (IMNV) is one of these epizootic agents affecting shrimp production in Brazil, of which no treatment exists. Herein, the antiviral activity against IMNV of an eicosapeptide, named Ctn[15-34], derived from a member of the cathelicidin family of antimicrobial peptides, was demonstrated. Cultures of hemocytes from Litopenaeus vannamei were established that support IMNV replication and infectivity titration. The cytotoxic effect of IMNV in culture and the in vitro anti-IMNV activity of Ctn[15-34] were assessed using a high-sensitive fluorescent-based method in combination with quantitative PCR. The Ctn[15-34] (<12.5 µM) neutralized the toxic effects of IMNV at loads sufficient to kill 50% of shrimp hemocytes. This study reported for the first time the replication of IMNV in vitro and the employment of a straightforward methodology to assess cell viability and viral/antiviral activities. In addition, it provided the basis for the development of the anti-infective multi-effector Ctn[15-34] eicosapeptide and analogs as components of antiviral formulations against shrimp viral diseases.

Cloning and molecular modeling of Litopenaeus vannamei (Penaeidae) C-type lectin homologs with mutated mannose binding domain-2.

C-type lectins are animal proteins that contain at least one carbohydrate recognition domain (CRD) capable of mediating sugar and calcium binding. Carbohydrate recognition is directly required for some biological functions, including the innate immune response. We cloned two novel C-type lectin (CTL) precursors from the commercial marine shrimp Litopenaeus vannamei. The cloned cDNAs encompass ORFs of 1044 nucleotides and encode highly similar two-domain polypeptides of 347 residues. The predicted proteins, LvCTL-br1 and -br2, contain the consensus triad that recognizes galactose (-GlnProAsp-) in CRD1 but also contain a mutated mannose-binding site (-GluProAsn-) in the second domain (CRD2). Phylogenetic analysis of LvCTL-br1 and -br2 and hundreds of CTL-like domain-containing proteins have allowed grouping of penaeid shrimp CTLs into three functional clusters. Reverse transcription coupled to PCR indicated that LvCTL-br1 expression is induced in shrimp gills upon IHHNV infection. Computational molecular modeling of LvCTL-br1 and -br2 revealed that three amino acid substitutions in CRD1 occur near the sugar binding site. Also, the 3-D models show a long loop of LvCTL-br1 CRD2 that might accommodate complex sugars. The structural data, evolutionary history and functional analysis support the hypothesis that gene duplication and accelerated evolution have caused functional diversification of penaeid shrimp C-type lectins.

Cloning and molecular modeling of Litopenaeus vannamei (Penaeidae) C-type lectin homologs with mutated mannose binding domain-2

C-type lectins are animal proteins that contain at least one carbohydrate recognition domain (CRD) capable of mediating sugar and calcium binding. Carbohydrate recognition is directly required for some biological functions, including the innate immune response. We cloned two novel C-type lectin (CTL) precursors from the commercial marine shrimp Litopenaeus vannamei. The cloned cDNAs encompass ORFs of 1044 nucleotides and encode highly similar two- domain polypeptides of 347 residues. The predicted proteins, LvCTL-br1 and -br2, contain the consensus triad that recognizes galactose (-GlnProAsp-) in CRD1 but also contain a mutated mannose-binding site (-GluProAsn-) in the second domain (CRD2). Phylogenetic analysis of LvCTL-br1 and -br2 and hundreds of CTL-like domain-containing proteins have allowed grouping of penaeid shrimp CTLs into three functional clusters. Reverse transcription coupled to PCR indicated that LvCTL-br1 expression is induced in shrimp gills upon IHHNV infection. Computational molecular modeling of LvCTL-br1 and -br2 revealed that three amino acid substitutions in CRD1 occur near the sugar binding site. Also, the 3-D models show a long loop of LvCTL-br1 CRD2 that might accommodate complex sugars. The structural data, evolutionary history and functional analysis support the hypothesis that gene duplication and accelerated evolution have caused functional diversification of penaeid shrimp C-type lectins.

Differential diagnosis of active hypodermal and hematopoietic necrosis virus based on gene choice and reverse transcription coupled with PCR.

The Pacific whiteleg shrimp Litopenaeus vannamei (Penaeidae) is one of the most important cultivated species in world aquaculture. In Brazil, the northeastern states are home to the main shrimp producers. As shrimp aquaculture has expanded and intensified, diseases have progressively become one of the most serious threats to this industry. Infectious hypodermal and hematopoietic necrosis virus (IHHNV) is an enzootic viral agent in Brazilian shrimp farms. Its is usually diagnosed by histological methods. However, to detect sub-clinical or acute IHHNV infection, more refined methods based on molecular techniques have been utilized. We found that by using "universal" primers and a single-step PCR diagnostic test, it was difficult to distinguish between non-infective forms of the virus and active IHHNV. Detection of IHHNV was more accurate when we used two alternative molecular strategies, namely 1) single-step PCR amplification based on gene choice and 2) reverse transcription coupled with PCR.