G. F. Hong

Two methods for increasing the length of DNA sequence data that can be read off a polyacrylamide gel are described. We have developed a rapid way to pour a buffer concentration gradient gel that, by altering the vertical band separation on an autoradiograph, allows more sequence to be obtained from a gel. We also show that the use of deoxyadenosine 5'-(alpha-[35S]thio)triphosphate as the label incorporated in dideoxynucleotide sequence reactions increases the sharpness of the bands on an autoradiograph and so increases the resolution achieved.

In Rhizobium leguminosarum biovar viciae, the regulatory nodulation nodD gene has at least two functions. It constitutively represses its own transcription and in the presence of inducer flavonoid molecules, it activates the expression of two other nod gene transcriptional units, nodABCIJ and nodFE. Upstream of nodA and nodF is a conserved sequence, the nod box, which has been implicated in nodD-mediated transcriptional activation of these genes. DNA fragments spanning the nod boxes that precede nodA and nodF were end-labelled and were exposed to cell-free extracts obtained from strains of Rhizobium. Using the gel retardation technique, it was shown that a complex between protein and these DNA fragments was formed, but only if the extract contained a functional nodD gene. Evidence that the protein that binds to the regulatory sequences is the nodD gene product came from the observation that a complex was formed between the nod box preceding nodA and protein from a cell-free extract isolated from Escherichia coli containing the cloned nodD gene. Extracts from Rhizobium strains containing mutant forms of nodD which were specifically affected in autoregulation or in flavonoid-dependent activation formed either no protein DNA complex or formed a complex with altered mobility compared to that obtained with extracts from wild-type strains.

A DNA sequencing method has been developed whereby DNA that has been cloned in a single-stranded bacteriophage vector can be sequenced from both ends. The method involves first making a minus-strand sense template from a single-stranded insert in the vector M13mp2 using a flanking primer, and then sequencing the synthesized template using the dideoxynucleotide termination method (Sanger et al., 1977, 1980) with a second primer. Special conditions are described under which the first primer is easily removed after making the template, and sequencing in the opposite direction can be done in the normal way (Sanger et al., 1980) without separating the double strands. This method renders it possible to read up to twice the amount of sequence data from a long insert and also to check short inserts by producing complementary sequence patterns.