Evaluation of recombinant Cryptosporidium hominis GP60 protein and anti-GP60 chicken polyclonal IgY for research and diagnostic purposes / Avaliação da proteína recombinante GP60 de Cryptosporidium hominis e da IgY policlonal anti-GP60 recombinante para uso em pesquisa e diagnóstico

Abstract In this study, a method for expressing Cryptosporidium hominis GP60 glycoprotein in Escherichia coli for production of polyclonal anti-GP60 IgY in chickens was developed aiming future studies concerning the diagnosis, prevention and treatment of cryptosporidiosis. The full-length nucleotide sequence of the C. hominis gp60 gene was codon-optimized for expression in E. coli and was synthesized in pET28-a vector. Subcloning was performed on several different strains of BL21 E. coli. Temperature, time and inducer IPTG concentration assays were also performed and analyzed using SDS-PAGE. The optimal conditions were observed at a temperature of 37 °C, with overnight incubation and 1 mM of IPTG. Purification was performed by means of affinity chromatography using the AKTA Pure chromatography system and the Hi-Trap™ HP column (GE Healthcare). The recombinant protein GP60 (rGP60) thus generated was used to immunize laying hens owing the production of polyclonal IgY. Western blot and indirect immunofluorescence showed that the polyclonal antibody was capable of binding to rGP60 and to Cryptosporidium parvum sporozoites, respectively. The rGP60 and the IgY anti-rGP60 generated in this study may be used as templates for research and for the development of diagnostic methods for cryptosporidiosis.

Resumo Neste trabalho, foi desenvolvido um método de expressão da glicoproteína GP60 de Cryptosporidium hominis em Escherichia coli visando produzir anticorpos IgY anti-GP60 em galinhas para utilização em estudos futuros com os objetivos de diagnóstico, prevenção e tratamento da criptosporidiose. A sequência completa de nucleotídeos do gene gp60 de C. hominis foi códon-otimizada para expressão em E. coli e sintetizada no vetor pET28-a. A subclonagem foi realizada em várias estirpes diferentes de E. coli BL21. Os ensaios de concentração do indutor IPTG, temperatura e tempo foram realizados e analisados por SDS-PAGE. As condições ótimas de expressão foram observadas em temperatura de 37 °C, incubação durante a noite e 1 mM de IPTG. A purificação da proteína foi realizada por cromatografia de afinidade utilizando o sistema de cromatografia AKTA Pure e a coluna Hi-Trap™ HP (GE Healthcare). A proteína recombinante GP60 (rGP60) foi utilizada para imunizar galinhas poedeiras para produzir IgY policlonal anti-rGP60. Verificou-se por Western blot e por imunofluorescência indireta que o anticorpo policlonal apresentou reatividade com a rGP60 e com esporozoítos de Cryptosporidium parvum, respectivamente. A rGP60 e a IgY anti-rGP60 geradas neste estudo podem ser utilizadas como modelos para o desenvolvimento de ensaios para pesquisa e diagnóstico da criptosporidiose.

Differentially expressed genes in giant cell tumor of bone.

Giant cells tumors of bone (GCTB) are benign in nature but cause osteolytic destruction with a number of particular characteristics. These tumors can have uncertain biological behavior often contain a significant proportion of highly multinucleated cells, and may show aggressive behavior. We have studied differential gene expression in GCTB that may give a better understanding of their physiopathology, and might be helpful in prognosis and treatment. Rapid subtractive hybridization (RaSH) was used to identify and measure novel genes that appear to be differentially expressed, including KTN1, NEB, ROCK1, and ZAK using quantitative real-time polymerase chain reaction (qRT-PCR) and immunohistochemistry in the samples of GCTBs compared to normal bone tissue. Normal bone was used in the methodology RaSH for comparison with the GCTB in identification of differentially expressed genes. Functional annotation indicated that these genes are involved in cellular processes related to their tumor phenotype. The differential expression of KTN1, ROCK1, and ZAK was independently confirmed by qRT-PCR and immunohistochemistry. The expression of the KTN1 and ROCK1 genes were increased in samples by qRT-PCR and immunohistochemistry, and ZAK had reduced expression. Since ZAK have CpG islands in their promoter region and low expression in tumor tissue, their methylation pattern was analyzed by MSP-PCR. The genes identified KTN1, ROCK1, and ZAK may be responsible for loss of cellular homeostasis in GCTB since they are responsible for various functions related to tumorigenesis such as cell migration, cytoskeletal organization, apoptosis, and cell cycle control and thus may contribute at some stage in the process of formation and development of GCTB.