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Abstract:
Conjugative DNA transfer in mycelial Streptomyces is a unique process involving the transfer of a double-stranded plasmid from the donor into the recipient and the subsequent spreading of the transferred plasmid within the recipient mycelium. This process is associated with growth retardation of the recipient and manifested by the formation of circular inhibition zones, named pocks. To characterize the unique Streptomyces DNA transfer machinery, we replaced each gene of the conjugative 12.1-kbp Streptomyces venezuelae plasmid pSVH1, with the exception of the rep gene required for plasmid replication, with a hexanucleotide sequence. Only deletion of traB, encoding the FtsK-like DNA translocase, affected efficiency of the transfer dramatically and abolished pock formation. Deletion of spdB3, spd79, or spdB2 had a minor effect on transfer but prevented pock formation and intramycelial plasmid spreading. Biochemical characterization of the encoded proteins revealed that the GntR-type regulator TraR recognizes a specific sequence upstream of spdB3, while Orf108, SpdB2, and TraR bind to peptidoglycan. SpdB2 promoted spheroplast formation by T7 lysozyme and formed pores in artificial membranes. Bacterial two-hybrid analyses and chemical cross-linking revealed that most of the pSVH1-encoded proteins interacted with each other, suggesting a multiprotein DNA translocation complex of TraB and Spd proteins which directs intramycelial plasmid spreading.