Caracterização funcional de proteínas hipotéticas de Leptospira interrogans como adesinas e potenciais antígenos vacinais e para diagnóstico / Functional characterization of hypothetical proteins in Leptospira interrogans as adhesins and potential vaccine and diagnostic antigens

Leptospira spp. constitui um grupo de bactérias espiroquetas gram-negativas englobando espécies saprofíticas, intermediárias e patogênicas, sendo as últimas agentes causadores da leptospirose, doença zoonótica de alcance mundial e endêmica em regiões tropicais em desenvolvimento. O crescente número de espécies identificadas de leptospiras destaca ainda mais sua diversidade genética e mecanismos de virulência únicos, muitos deles com função ainda desconhecida. Esforços para o desenvolvimento de novas vacinas com proteção cruzada e efeito duradouro revelaram possíveis candidatos vacinais que necessitam ser adequadamente validados, sendo assim, há ainda uma urgente necessidade de uma vacina universal contra a leptospirose capaz de controlar e reduzir os surtos cada vez mais frequentes da doença. Adesinas são importantes fatores de virulência em diversos patógenos, constituindo antígenos promissores para o desenvolvimento de vacinas contra a leptospirose, assim como para o desenvolvimento de métodos diagnósticos mais rápidos e precisos. Previamente, foram identificadas três proteínas hipotéticas conservadas em L. interrogans pela técnica de phage display, denominadas arbitrariamente como LepA069, LepA962 e LepA388. A expressão do gene codificador da proteína LepA069 apresentou aumento de aproximadamente 70 % em animais infectados por leptospiras virulentas, representando a primeira evidência funcional desta proteína ainda desconhecida. Porções recombinantes da lipoproteína hipotética LepA962 (LepA962_Nt e LepA962_Phg) foram obtidos, sendo demonstrada a forte interação da proteína LepA962_Phg, contendo a sequência identificada por phage display, com laminina, fibronectina plasmática, colágeno I e fibrinogênio de maneira dose-dependente. Adicionalmente, LepA962_Phg apresentou ligação às células VERO e à sua matriz extracelular secretada, e o soro obtido a partir desta proteína recombinante foi capaz de se ligar à superfície de leptospiras virulentas, indicando que LepA962_Phg pode representar um importante domínio de interação entre as leptospiras e seu hospedeiro. Finalmente, a proteína LepA388 pertencente a uma extensa família de proteínas modificadoras de virulência com função desconhecida (DUF_61), presente apenas nas leptospiras patogênicas mais virulentas, apresentou aumento na expressão de seu gene codificador em animais infectados por leptospiras virulentas de acordo com dados na literatura. Além disso, porções recombinantes da região Nterminal desta proteína apresentaram ligação a laminina, colágenos I e IV, vitronectina e fibronectinas plasmática e celular, principalmente considerando a sequência identificada por phage display. Estes dados reforçam as predições de modelos tridimensionais da proteína LepA388 e de outros membros da família DUF_61, as quais identificam domínios semelhantes a toxinas (como abrina e CARDS) responsáveis pela ligação e internalização celulares nos hospedeiros. Dados recentes sugerem um possível papel citotóxico desempenhado pelas proteínas desta família em leptospiras, as quais podem também ser consideradas potenciais candidatas vacinais e para diagnóstico da leptospirose, devido à sua distribuição restrita em espécies e cepas patogênicas de importância para saúde humana.

Leptospira spp. constitutes a group of gram-negative spirochete bacteria comprising saprophytic, intermediate and pathogenic species, the last being causative agents of leptospirosis, a zoonotic disease of worldwide extent and endemic in developing tropical regions. The growing number of identified leptospiral species further highlights their genetic diversity and unique virulence mechanisms, many of them with unknown function. Efforts to develop new vaccines with cross-protection and long-lasting effect have revealed possible vaccine candidates that need to be properly validated. Therefore, there is still an urgent need for a universal vaccine against leptospirosis capable of controlling and reducing the increasing outbreaks of the disease. Adhesins are important virulence factors in several pathogens, constituting promising antigens for the development of vaccines against leptospirosis, as well as for the development of faster and more accurate diagnostic methods. Previously, three conserved hypothetical proteins in L. interrogans were identified by phage display technique, arbitrarily named as LepA069, LepA962 and LepA388. Expression of the LepA069 encoding gene showed an increase of approximately 70 % in animals infected by virulent leptospires, representing the first functional evidence of this still unknown protein. Recombinant portions of the hypothetical lipoprotein LepA962 (LepA962_Nt and LepA962_Phg) were obtained, demonstrating the strong interaction of the LepA962_Phg protein, containing the sequence identified by phage display, with laminin, plasma fibronectin, collagen I and fibrinogen in a dose-dependent manner. Furthermore, LepA962_Phg showed binding to VERO cells and its secreted extracellular matrix, and the serum obtained from this recombinant protein was able to bind to the surface of virulent leptospires, indicating that LepA962_Phg may represent an important domain of interaction between leptospires and its host. Finally, LepA388 protein belonging to an extensive family of virulence modifying proteins with unknown function (DUF_61), present only in the most virulent pathogenic leptospires, showed an increase in the expression of its encoding gene in animals infected by virulent leptospires according to data in literature. Moreover, recombinant portions of the N-terminal region of this protein showed binding to laminin, collagens I and IV, vitronectin and plasma and cell fibronectins, especially considering the sequence identified by phage display. These data support the predictions of three-dimensional models of the LepA388 protein and other members of the DUF_61 family, which identify toxin-like domains (such as abrin and CARDS) responsible for cellular binding and internalization in hosts. Recent data suggest a possible cytotoxic role played by proteins of this family in leptospires, which can also be considered potential vaccine candidates and antigens for diagnosis, due to their restricted distribution in pathogenic species and strains of importance to human health

Bioinformatic analysis of non-VP1 capsid protein of coxsackievirus A6 / 华中科技大学学报（医学）（英德文版）

This study bioinformatically analyzed the non-VP1 capsid proteins (VP2-VP4) of Coxasckievirus A6 (CVA6), with an attempt to predict their basic physicochemical properties, structural/functional features and linear B cell eiptopes. The online tools SubLoc, TargetP and the others from ExPASy Bioinformatics Resource Portal, and SWISS-MODEL (an online protein structure modeling server), were utilized to analyze the amino acid (AA) sequences of VP2-VP4 proteins of CVA6. Our results showed that the VP proteins of CVA6 were all of hydrophilic nature, contained phosphorylation and glycosylation sites and harbored no signal peptide sequences and acetylation sites. Except VP3, the other proteins did not have transmembrane helix structure and nuclear localization signal sequences. Random coils were the major conformation of the secondary structure of the capsid proteins. Analysis of the linear B cell epitopes by employing Bepipred showed that the average antigenic indices (AI) of individual VP proteins were all greater than 0 and the average AI of VP4 was substantially higher than that of VP2 and VP3. The VP proteins all contained a number of potential B cell epitopes and some eiptopes were located at the internal side of the viral capsid or were buried. We successfully predicted the fundamental physicochemical properties, structural/functional features and the linear B cell eiptopes and found that different VP proteins share some common features and each has its unique attributes. These findings will help us understand the pathogenicity of CVA6 and develop related vaccines and immunodiagnostic reagents.