Folding factors and partners for the intrinsically disordered protein Micro-Exon Gene 14 (MEG-14)

The micro-exon genes (MEG) of Schistosoma mansoni, a parasite responsible for the second most widely spread tropical disease, code for small secreted proteins with sequences unique to the Schistosoma genera. Bioinformatics analyses suggest the soluble domain of the MEG-14 protein will be largely disordered, and using synchrotron radiation circular dichroism spectroscopy, its secondary structure was shown to be essentially completely unfolded in aqueous solution. It does, however, show a strong propensity to fold into more ordered structures under a wide range of conditions. Partial folding was produced by increasing temperature (in a reversible process), contrary to the behavior of most soluble proteins. Furthermore, significant folding was observed in the presence of negatively charged lipids and detergents, but not in zwitterionic or neutral lipids or detergents. Absorption onto a surface followed by dehydration stimulated it to fold into a helical structure, as it did when the aqueous solution was replaced by nonaqueous solvents. Hydration of the dehydrated folded protein was accompanied by complete unfolding. These results support the identification of MEG-14 as a classic intrinsically disordered protein, and open the possibility of its interaction/folding with different partners and factors being related to multifunctional roles and states within the host

Interactions of amphipathic α-helical MEG proteins from Schistosoma mansoni with membranes

Micro Exon Gene (MEG) proteins are thought to play major roles in the infection and survival of parasitic Schistosoma mansoni worms in host organisms. Here, the physical chemical properties of two small MEG proteins found in the genome of S. mansoni, named MEG-24 and MEG-27, were examined by a combination of biophysical techniques such as differential scanning calorimetry, tensiometry, circular dichroism, fluorescence, and electron spin resonance spectroscopies. The proteins are surface active and structurally arranged as cationic amphipathic α-helices that can associate with lipid membranes and cause their disruption. Upon adsorption to lipid membranes, MEG-27 strongly affects the fluidity of erythrocyte ghost membranes, whereas MEG-24 forms pores in erythrocytes without modifying the ghost membrane fluidity. Whole–mount in situ hybridization experiments indicates that MEG-27 and MEG-24 transcripts are located in the parasite esophagus and subtegumental cells, respectively, suggesting a relevant role of these proteins in the host-parasite interface. Taken together, these characteristics lead us to propose that these MEG proteins may interact with host cell membranes and potentially modulate the immune process using a similar mechanism as that described for α-helical membrane–active peptides

Study of structure and protein partners of proteins coded by micro-exon genes of Schistosoma mansoni

Os genes micro-exons (MEGs) foram recentemente identificados no genoma do Schistosoma mansoni, verme responsável pela esquistossomose, doença que afeta mais de 262 milhões de pessoas em mais de 78 países. Devido à capacidade de produção de proteínas variantes pelo splicing alternativo de MEGs, expressão preferencial em estágios do ciclo de vida em contato com o hospedeiro definitivo e a verificação de que várias proteínas codificadas por estes genes são secretadas para o meio externo ao parasito, acredita-se que estas proteínas possuam um papel importante na interação parasito-hospedeiro. O objetivo deste trabalho foi estudar e caracterizar a estrutura e dinâmica conformacional das proteínas codificadas por MEG-11 e MEG-14 e verificar a interação da proteína MEG-14 com proteínas humanas. A análise das proteínas MEG-11 e MEG-14 produzidas em sistema recombinante com a técnica de dicroísmo circular (CD) demonstrou que ambas as proteínas apresentavam estruturas secundárias majoritariamente desordenadas quando em solução aquosa. Entretanto, foi verificado que a presença de TFE, a desidratação das proteínas e o aumento de temperatura favoreciam o surgimento de estruturas ordenadas nestas proteínas. Um ganho de estrutura secundária também foi observado para a proteína MEG-14 na presença de vesículas de fosfolipídios e micelas de detergente carregadas negativamente. Estes resultados suportam a identificação destas proteínas como clássicas proteínas intrinsicamente desordenadas (IDPs) e abre a possibilidade de sua interação com diferentes parceiros e fatores a serem relacionados com os papéis multifuncionais e estados dentro do hospedeiro. Resultados prévios de experimentos de duplo-hibrido do nosso grupo apontavam uma possível interação de MEG-14 com a proteína humana S100A9. Através da técnica de pulldown foi possível confirmar uma interação dependente da presença de cálcio entre estas duas proteínas. Análises adicionais da interação MEG-14/S100A9 com as técnicas de ITC e SPR permitiram calcular a constante de dissociação entre as proteínas em aproximadamente 2 μM. Finalmente, experimentos ex vivo permitindo a ingestão da proteína S100A9 acoplada a uma molécula fluorescente pelo S. mansoni resultaram na acumulação da proteína na glândula do esôfago, local onde já foi localizada a proteína MEG-14 em S. japonicum, sugerindo que a interação observada nos experimentos in vitro está ocorrendo com a proteína MEG-14 nativa.The micro-exon genes (MEGs) were recently identified in Schistosoma mansoni’s genome, worm responsible for schistosomiasis, a disease that affects more than 262 million people in more than 78 countries. Due to the capacity of variant protein production by alternative splicing of MEGs, preferential expression in certain life stages in contact with the definitive host, and the confirmation that many proteins coded by these genes are secreted to the external environment, It’s believed that these proteins have an important role in parasite-host relationship. The objective of this work was to study and characterize the structure and conformational dynamics of proteins coded by MEG-11 and MEG-14 and verify the interaction of Meg-14 protein with human proteins. The analysis of MEG-11 and MEG-14 proteins produced in recombinant system with circular dichroism (CD) shows that both proteins present secondary structures mostly disordered in aqueous solution. However, It was found that in presence of TFE, the dehydration of proteins and the increasing of temperature favor the surging of ordered structures. An increase of secondary structure was observed too for MEG-14 protein in presence of phospholipid vesicles and negative charged detergent micelles. These results support the identification of these proteins as classical intrinsically disordered proteins (IDPs) and opens the possibility of its interaction with different partners and factors related with the multifunctional roles and states in the host. Previous results of double-hybrid experiments pointed a possible interaction between MEG-14 and the human protein S100A9. By pulldown technique was possible confirm an calcium dependent interaction between these proteins. Additional analysis of MEG-14/S100A9 interaction with ITC and SPR experiments were able to calculate the dissociation constant between proteins equals to 2 μM. Finally, ex vivo experiments permit the ingestion of S100A9 coupled to a fluorescent molecule by S. mansoni, resulting in the accumulation of protein in the esophageal gland, where was localized the MEG-14 in S. japonicum, suggesting that the interaction observed in the in vitro experiments are occurring with the native MEG-14

Interaction of an esophageal MEG protein from schistosomes with a human S100 protein involved in inflammatory response

BACKGROUND: The Micro-Exon Gene-14 (MEG-14) displays a remarkable structure that allows the generation of antigenic variation in Schistosomes. Previous studies showed that the soluble portion of the MEG-14 protein displays features of an intrinsically disordered protein and is expressed exclusively in the parasite esophageal gland. These features indicated a potential for interaction with host proteins present in the plasma and cells from ingested blood. METHODS: A yeast two-hybrid experiment using as bait the soluble domain of Schistosoma mansoni MEG-14 (sMEG-14) against a human leukocyte cDNA library was performed. Pull-down and surface plasmon resonance (SPR) experiments were used to validate the interaction between sMEG-14 and human S100A9. Synchrotron radiation circular dichroism (SRCD) were used to detect structural changes upon interaction between sMEG-14 and human S100A9. Feeding of live parasites with S100A9 attached to a fluorophore allowed the tracking of the fate of this protein in the parasite digestive system. RESULTS: S100A9 interacted with sMEG-14 consistently in yeast two-hybrid assay, pull-down and SPR experiments. SRCD suggested that MEG-14 acquired a more regular structure as a result of the interaction with S100A9. Accumulation of recombinant S100A9 in the parasite's esophageal gland, when ingested by live worms suggests that such interaction may occur in vivo. CONCLUSION: S100A9, a protein previously described to be involved in modulation of inflammatory response, was found to interact with sMEG-14. GENERAL SIGINFICANCE: Our results allow proposing a mechanism involving MEG-14 for the parasite to block inflammatory signaling, which would occur upon release of S100A9 when ingested blood cells are lysed