Zone-interference gel electrophoresis: a new method for studying weak protein-nucleic acid complexes under native equilibrium conditions

A new and general electrophoresis method is described for the determination of dissociation constants of weak macromolecular complexes in the range of 10(-6) to 10(-4) M. The method is based on the measurement of the migration distance of a macromolecular complex in rapid dynamic equilibrium as a function of the interacting ligand concentration in a surrounding zone. Special advantages of the method are: its high sensitivity (dependent on the autoradiography, immunoblotting or staining technique used), its speed (electrophoresis time 20 min), and the independence of the Kd determination on the sample concentration of macromolecules. The latter is of great value for labile macromolecules: unknown partial inactivation does not influence the measurement. Studying the interactions between elongation factor EF-Tu and tRNA from E. coli we found for EF-Tu.GTP.aurodox.aminocyl-tRNA a Kd of 3 microM and for EF-Tu.GDP.aurodox.aminoacyl-tRNA a Kd of 11 microM at 9 degrees C

The Unique tuf2 Gene from the Kirromycin Producer Streptomyces ramocissimus Encodes a Minor and Kirromycin-Sensitive Elongation Factor Tu

Streptomyces ramocissimus, the producer of elongation factor Tu (EF-Tu)-targeted antibiotic kirromycin, contains three divergent tuf-like genes, with tuf1 encoding regular kirromycin-sensitive EF-Tu1; the functions of tuf2 and tuf3 are unknown. Analysis of the tuf gene organization in nine producers of kirromycin-type antibiotics revealed that they all contain homologues of tuf1 and sometimes of tuf3 but that tuf2 was found in S. ramocissimus only. The tuf2-flanking regions were sequenced, and the two tuf2-surrounding open reading frames were shown to be oriented in opposite directions. In vivo transcription analysis of the tuf2 gene displayed an upstream region with bidirectional promoter activity. The transcription start site of tuf2 was located approximately 290 nucleotides upstream of the coding sequence. Very small amounts of tuf2 transcripts were detected in both liquid- and surface-grown cultures of S. ramocissimus, consistent with the apparent absence of EF-Tu2 in total protein extracts. The tuf2 transcript level was not influenced by the addition of kirromycin to exponentially growing cultures. To assess the function of S. ramocissimus EF-Tu2, the protein was overexpressed in Streptomyces coelicolor LT2. This strain is a J1501 derivative containing His(6)-tagged EF-Tu1 as the sole EF-Tu species, which facilitated the separation of EF-Tu2 from the interfering EF-Tu1. S. ramocissimus EF-Tu1 and EF-Tu2 were indistinguishable in their ability to stimulate protein synthesis in vitro and exhibited the same kirromycin sensitivity, which excludes the possibility that EF-Tu2 is directly involved in the kirromycin resistance mechanism of S. ramocissimus