Structure and Function of the Borrelia burgdorferi Porins, P13 and P66

Abstract: Borrelia burgdorferi is an elongated and helically shaped bacterium that is the causal agent of the tick-borne illness Lyme disease. The disease manifests with initial flu-like symptoms and, in many cases, the appearance of a skin rash called erythema migrans at the site of the tick bite. If left untreated the disease might cause impairment of various organs such as the skin, heart, joints and the nervous system. The bacteria have a parasitic lifestyle and are always present within a host. Hosts are usually ticks or different animals and birds that serve as reservoirs for infection. B. burgdorferi are unable to synthesize building blocks for many vital cellular processes and are therefore highly dependent on their surroundings to obtain nutrients. Because of this, porins situated in the outer membrane, involved in nutrient uptake, are believed to be very important for B. burgdorferi. Except for a role in nutrient acquisition, porins can also have a function in binding extracellular matrix proteins, such as integrins, and have also been implicated in bacterial adaptation to new environments with variations in osmotic pressure.P13 and P66 are two integral outer membrane proteins in B. burgdorferi previously shown to have porin activities. In addition to its porin function, P66 also has integrin binding activity. In this thesis, oligomeric structures formed by the P13 and P66 protein complexes were studied using the Black lipid bilayer technique in combination with nonelectrolytes. Initial attempts were also made to study the structure of P13 in Nanodiscs, whereby membrane proteins can insert into artificial lipid bilayers in their native state and the structure can be analyzed by electron microscopy. In addition, the role of P13 and P66 in B. burgdorferi osmotic stress adaptation was examined and also the importance and role of the integrin-binding activity of P66 in B. burgdorferi infections in mice.Using Black lipid bilayer studies, the pore forming activity of P13 was shown to be much smaller than previously thought, exhibiting activity at 0.6 nS. The complex formed by P13 was approximately 300 kDa and solely composed of P13 monomers. The channel size was calculated to be roughly 1.4 nm. Initial Nanodisc experiments showed a pore size of 1.3 nm, confirming the pore size determined by Black lipid bilayer experiments. P66 form pores with a single channel conductance of 11 nS and a channel size of 1.9 nm. The porin assembles in the outer membrane into a large protein complex of 420 kDa, containing exclusively P66 monomers. The integrin-binding function of P66 was found to be important for efficient bacterial dissemination in the murine host but was not essential for B. burgdorferi infectivity. Neither P13 nor P66 had an active role in osmotic stress adaptation. Instead, two p13 paralogs were up-regulated at the transcript level in B. burgdorferi cultured under glycerol-induced osmotic stress.