L-asparaginase de Erwinia chrysanthemi: expressão proteica livre de células e bioconjugação a bacteriófagos / L-asparaginase from Erwinia chrysanthemi: cell-free protein expression and bioconjugation to bacteriophages

A L-Asparaginase (L-ASNase) de Erwinia chrysathemi (ErA) é uma enzima amplamente utilizada para o tratamento da leucemia linfoblástica aguda (LLA). Embora o seu uso como segunda linha de tratamento para a LLA tenha proporcionado consideráveis benefícios clínicos, reações de hipersensibilidade e rápida depuração plasmática ainda são problemas recorrentes. Ademais, extensivos e custosos processos de produção da ErA são necessários para a obtenção da enzima pura. Com base nesses problemas, o presente trabalho propõe (1) o estudo de viabilidade de expressão da ErA em um sistema de síntese proteica livre de células (SPLC) e (2) a conjugação da proteína em bacteriófagos como ferramenta alternativa para o isolamento e monitoramento da depuração plasmática da ErA. Foram utilizados extratos celulares de Escherichia coli suplementados com solução energética contendo creatina fosfato (CP) como fonte de energia para síntese in vitro de ErA. Para conjugação da ErA a bacteriófagos, o sistema SpyTag/SpyCatcher foi implementado: SpyCatcher foi fusionado à porção N-terminal da ErA e bacteriófagos filamentosos da linhagem M13 e fd foram modificados de modo a expressar SpyTag nas proteínas de capsídeo pIII e pVIII, respectivamente. Em relação ao primeiro objetivo, o sistema de SPLC foi capaz de expressar a ErA com atividade. A proteína foi expressa na fração solúvel e apresentou atividade enzimática significativamente superior em relação à reação controle (7,07 ± 0,68 U/mL vs. 1,83 ± 0,14 U/mL). Tempo necessário para obtenção do extrato celular foi reduzido de 45 para 26 hrs, e sete componentes da solução energética foram removidos da composição original sem implicações negativas na eficiência de expressão da ErA, simplificando desta forma o processo de SPLC. Em relação ao segundo objetivo, ErA fusionada à SpyCatcher (SpyCatcher_ErA) foi conjugada com êxito em bacteriófagos capazes de expressar SpyTag fusionadas na porção N-terminal das proteínas pIII (SpyTag_pIII) e pVIII (SpyTag_pVIII). A porcentagem de formação dos conjugados entre SpyCatcher_ErA e SpyTag_pIII ((ErA)5-pIII) foi de 6% enquanto formação dos conjugados entre SpyCatcher_ErA e SpyTag_pVIII ((ErA)50-pVIII) foi de 46%, valores estes confirmados por atividade enzimática. Solução contendo conjugados foram injetados em camundongos e sequenciados/titulados com êxito. Não houve diferença de depuração plasmática entre (ErA)5-pIII e bacteriófago controle, mas houve maior taxa de eliminação de (ErA)50-pVIII em relação ao mesmo bacteriófago não conjugado à SpyCatcher_ErA. Os resultados aqui apresentados confirmam ser possível expressar ErA com atividade biológica em sistemas de SPLC. Além disso, o sistema de conjugação da ErA a bacteriófagos aqui desenvolvido foi capaz de monitorar a concentração de ErA presente na circulação em função do tempo, tornando-se uma potencial plataforma de desenvolvimento de novas proteoformas da ErA com características clínicas melhoradas

L-Asparaginase (L-ASNase) from Erwinia chrysanthemi (ErA) is a widely used enzyme for treatment of acute lymphoblastic leukemia (ALL). Although its use as a second-line treatment has provided significant clinical benefits, hypersensitivity reactions and a fast clearance rate are recurring L-ASNase-related problems. In addition, extensive and costly production processes are required for the manufacturing of pure ErA. Based on these drawbacks, this current work proposes (1) the study of the use of a cell-free protein synthesis (CFPS) system as a viable platform for the synthesis of ErA and (2) the conjugation of the protein on bacteriophages as an alternative tool for the isolation and monitoring of ErA clearance. Escherichia coli-derived cell extracts supplemented with a creatine phosphate-based energy solution were used to synthesize ErA in vitro. To conjugate ErA on bacteriophages, the SpyTag/SpyCatcher system was implemented: SpyCatcher was fused to the N-terminus of the ErA while filamentous phage strains M13 and fd were engineered in order to display SpyTag on their pIII and pVIII capsid proteins, respectively. Regarding the first goal, the CFPS system was able to express an active ErA. The protein was expressed in the soluble fraction and there presented a significant higher enzymatic activity compared to the control reaction (7.07 ± 0.68 U/mL vs. 1.83 ± 0.14 U/mL). Time required to obtain the cell extract was reduced from 45 to 26 hours, and seven energy solution reagents were removed from the original solution without compromising the efficiency of ErA expression, thus simplifying the CFPS process. With respect to the second goal, ErA fused to SpyCatcher (SpyCatcher_ErA) was sucessfully conjugated on bacteriophages capable of displaying SpyTag fused to the Nterminus of the pIII (SpyTag_pIII) or pVIII (SpyTag_pVIII) proteins. Percentage of conjugate formation between SpyCatcher_ErA and SpyTag_pIII (ErA)5-pIII was 6% whereas conjugate formation between SpyCatcher_ErA and SpyTag_pVIII (ErA)50-pVIII was 46%, values that were confirmed by enzymatic activity. Sample containing conjugates were injected into mice and sucessfully sequenced/titrated. No clearance differences were observed between (ErA)5- pIII and a control bacteriophage, but a higher clearance rate was observed for (ErA)50-pVIII compared to SpyTag_VIII non conjugated to SpyCatcher_ErA. The results here presented confirm the expression of a biologically active ErA from a CFPS system. Besides, the development of a conjugation system capable of linking ErA to bacteriophages could be used as a means to monitor the ErA concentration in the blood as a function of time and also as a potential platform to be used in the development of novel ErA proteoforms with improved clinical properties

Analysis of the bacterial communities associated with two ant-plant symbioses.

Insect fungiculture is practiced by ants, termites, beetles, and gall midges and it has been suggested to be widespread among plant-ants. Some of the insects engaged in fungiculture, including attine ants and bark beetles, are known to use symbiotic antibiotic-producing actinobacteria to protect themselves and their fungal cultivars against infection. In this study, we analyze the bacterial communities on the cuticles of the plant-ant genera Allomerus and Tetraponera using deep sequencing of 16S rRNA. Allomerus ants cultivate fungus as a building material to strengthen traps for prey, while Tetraponera ants cultivate fungus as a food source. We report that Allomerus and Tetraponera microbiomes contain >75% Proteobacteria and remarkably the bacterial phyla that dominate their cuticular microbiomes are very similar despite their geographic separation (South America and Africa, respectively). Notably, antibiotic-producing actinomycete bacteria represent a tiny fraction of the cuticular microbiomes of both Allomerus and Tetraponera spp. and instead they are dominated by γ-proteobacteria Erwinia and Serratia spp. Both these phyla are known to contain antibiotic-producing species which might therefore play a protective role in these ant-plant systems.

Phenotypic and phylogenetic characterization of ruminal tannin-tolerant bacteria.

The 16S rRNA sequences and selected phenotypic characteristics were determined for six recently isolated bacteria that can tolerate high levels of hydrolyzable and condensed tannins. Bacteria were isolated from the ruminal contents of animals in different geographic locations, including Sardinian sheep (Ovis aries), Honduran and Colombian goats (Capra hircus), white-tail deer (Odocoileus virginianus) from upstate New York, and Rocky Mountain elk (Cervus elaphus nelsoni) from Oregon. Nearly complete sequences of the small-subunit rRNA genes, which were obtained by PCR amplification, cloning, and sequencing, were used for phylogenetic characterization. Comparisons of the 16S rRNA of the six isolates showed that four of the isolates were members of the genus Streptococcus and were most closely related to ruminal strains of Streptococcus bovis and the recently described organism Streptococcus gallolyticus. One of the other isolates, a gram-positive rod, clustered with the clostridia in the low-G+C-content group of gram-positive bacteria. The sixth isolate, a gram-negative rod, was a member of the family Enterobacteriaceae in the gamma subdivision of the class Proteobacteria. None of the 16S rRNA sequences of the tannin-tolerant bacteria examined was identical to the sequence of any previously described microorganism or to the sequence of any of the other organisms examined in this study. Three phylogenetically distinct groups of ruminal bacteria were isolated from four species of ruminants in Europe, North America, and South America. The presence of tannin-tolerant bacteria is not restricted by climate, geography, or host animal, although attempts to isolate tannin-tolerant bacteria from cows on low-tannin diets failed.