Evaluation of the elastinolytic activity and protective effect of Leptallo I, a protein composed by metalloprotease and FA5/8C domains, from Leptospira interrogans Copenhageni.

Leptospirosis is a re-emergent zoonosis, caused by pathogenic spirochetes from the genus Lepstospira. To date, there is no protein described to be involved in leptospiral hemorrhagic manifestations, although several proteases have been reported for other bacterial infections. In this study we identified 12 putative metalloproteases from the genome of Leptospira interrogans, and characterized for the first time a putative metalloprotease, here named Leptallo I, as a potential Zn(2+) dependent glycylglycine protease belonging to the M23 metalloendopeptidase family. The native protein was detected in extracts from several pathogenic Leptospira species and further shown to be secreted to the culture medium. We expressed the recombinant protein and its C-terminal fragment containing the metalloprotease domain, and both presented regular secondary structures. The sera of humans with leptospirosis were able to recognize rLeptallo I, indicating that the native protein is expressed and presented to the immune system during infection. The recombinant proteins displayed a significant, though relatively low, elastinolytic activity, and the challenge of hamsters immunized with rLeptallo I conferred 33% protection, suggesting a significant importance of this protein in the pathogenesis. The elastinolytic activity may be important for leptospires-host interaction, because elastin constitutes a significant proportion of total lung and blood vessel proteins.

Evaluation of the expression and protective potential of leptospiral sphingomyelinases

Leptospirosis is a zoonotic disease of global distribution, which affects both animals and humans. Pathogenic leptospires, the bacteria that cause this disease, require iron for their growth, and these spirochetes probably use their hemolysins, such as the sphingomyelinases, as a way to obtain this important nutrient from host red blood cells during infection. We expressed and purified the leptospiral sphingomyelinases Sph1, Sph2, Sph4, and SphH in a heterologous system. However, the recombinant proteins were not able to lyse sheep erythrocytes, despite having regular secondary structures. Transcripts for all sphingomyelinases tested were detected by RT-PCR analyses, but only Sph2 and SphH native proteins could be detected in Western blot assays using Leptospira whole extracts as well as in renal tubules of infected hamsters. Moreover, antibodies present in the serum of a human patient with laboratory-confirmed leptospirosis recognized Sph2, indicating that this sphingomyelinase is expressed and exposed to the immune system during infection in humans. However, in an animal challenge model, none of the sphingomyelinases tested conferred protection against leptospirosis.

Leptospiral TlyC is an extracellular matrix-binding protein and does not present hemolysin activity

The role of TlyA, TlyB and TlyC proteins in the biology of Leptospira is still uncertain. Although these proteins have been considered as putative hemolysins, we demonstrate that leptospiral recombinant TlyB and TlyC do not possess hemolytic activity. However, further experiments showed that TlyC is a surface-exposed protein that seems to bind to laminin, collagen IV and fibronectin. The expression of both proteins was detected both in vitro and in vivo. Our findings suggest that TlyB and TlyC are not directly involved in hemolysis, and that TlyC may contribute to Leptospira binding to extracellular matrix (ECM) during host infection.