DNA Structure Modulates the Oligomerization Properties of the AAV Initiator Protein Rep68

Rep68 is a multifunctional protein of the adeno-associated virus (AAV), a parvovirus that is mostly known for its promise as a gene therapy vector. In addition to its role as initiator in viral DNA replication, Rep68 is essential for site-specific integration of the AAV genome into human chromosome 19. Rep68 is a member of the superfamily 3 (SF3) helicases, along with the well-studied initiator proteins simian virus 40 large T antigen (SV40-LTag) and bovine papillomavirus (BPV) E1. Structurally, SF3 helicases share two domains, a DNA origin interaction domain (OID) and an AAA+ motor domain. The AAA+ motor domain is also a structural feature of cellular initiators and it functions as a platform for initiator oligomerization. Here, we studied Rep68 oligomerization in vitro in the presence of different DNA substrates using a variety of biophysical techniques and cryo-EM. We found that a dsDNA region of the AAV origin promotes the formation of a complex containing five Rep68 subunits. Interestingly, non-specific ssDNA promotes the formation of a double-ring Rep68, a known structure formed by the LTag and E1 initiator proteins. The Rep68 ring symmetry is 8-fold, thus differing from the hexameric rings formed by the other SF3 helicases. However, similiar to LTag and E1, Rep68 rings are oriented head-to-head, suggesting that DNA unwinding by the complex proceeds bidirectionally. This novel Rep68 quaternary structure requires both the DNA binding and AAA+ domains, indicating cooperativity between these regions during oligomerization in vitro. Our study clearly demonstrates that Rep68 can oligomerize through two distinct oligomerization pathways, which depend on both the DNA structure and cooperativity of Rep68 domains. These findings provide insight into the dynamics and oligomeric adaptability of Rep68 and serve as a step towards understanding the role of this multifunctional protein during AAV DNA replication and site-specific integration

A voltammetric study of interdomain electron transfer within sulfite oxidase.

Protein film voltammetry of chicken liver sulfite oxidase (SO) bound at the pyrolytic graphite "edge" or modified gold electrodes shows that catalytic electron transport is controlled by the inherent electrochemical characteristics of the heme b domain and conformational changes that allow intramolecular electron transfer with the molybdenum active site. In the absence of sulfite, a single nonturnover electrochemical signal is observed at +90 mV (vs SHE) that is assigned to heme b. In the presence of sulfite, this signal transforms into a catalytic wave at similar potential. The shape and negligible pH dependence of this wave indicate that catalytic turnover is controlled by the one-electron transfers through heme b. The smaller turnover numbers obtained in this experiment (k(cat) approximately 2-4 s(-1), as compared to 100 s(-1) in solution) suggest that only a small fraction of SO is bound at the electrode in a manner that permits the conformational change necessary for fast interdomain electron transfer

Syntheses, characterisation, infrared and Mo-95 NMR spectroscopy of some coordinated oxo-molybdenum(VI) complexes

Adducts with MoO42- tetrahedra coordinated to Cr(III) or Co(III) complexes have been synthesised and studied by IR and high resolution 95Mo NMR spectroscopy. The 95Mo chemical shifts of the adducts with cobalt(III) lie in the range -33.2 to +49.4 ppm. This may be compared with an overall known chemical shift range in excess of 7000 ppm and implies a similarity in the molybdenum environment in all cases. For adducts with chelated cobalt(IH) complexes several rather broad 95Mo signals are obtained with linewidths up to 260 Hz