Pullulanase is a starch-debranching enzyme produced by the gram-negative bacterium Klebsiella pneumoniae. In this organism, the enzyme is first exported to the outer membrane and is subsequently released into the growth medium, Evidence reported here indicates that pullulanase is a lipoprotein. It is apparently synthesized as a precursor with a 19-residue-long signal sequence and modified by the covalent attachment of palmitate to the cysteine residue which becomes the amino terminus after cleavage of the signal sequence. In this respect, pullulanase is similar to some penicillinases produced by gram-positive bacteria which are initially exported to the cell surface and subsequently released into the medium. However, pullulanase and the penicillinases differ in one important aspect, namely, that the extraceliular pullulanase still carries the covalently attached fatty acyls, whereas extracellular pepicillinases lack the modified amino-terminal cysteine together with a limited number of other residues from the amino terminus.
We have determined the stoichiometry of CRP binding to various DNA fragments carrying the lac, malT or gal promoters in the presence of cAMP, using a gel electrophoresis method. In each case, one dimer of CRP binds to the functional CRP site upstream of the transcription start. At the lac promoter, a second CRP dimer can bind to the operator region. Direct binding analysis and competition experiments performed at 200 microM cAMP allow us to measure the affinity of CRP for these different sites and to correlate them with variations in the consensus sequences, already proposed. The order is lac greater than malT greater than gal greater than lac operator greater than lac L8 much greater than non specific sites. No strong coupling exists between the two lac sites when on the same fragment. Conversely, we have studied, at constant CRP concentrations, the cAMP levels required to obtain half maximal binding to a particular DNA site : the required cAMP level increases inversely as the affinity for CRP. These variations may account for the differential activation of various cAMP sensitive operons in vivo. Anomalies in the migrations of the 1:1 complexes between CRP and DNA have been analysed and related to the size and to the position of the CRP site in the fragment. The electrophoretic mobility of the complexes depends not only on the size of the fragment but on the position of the CRP site : the mobility is lower when CRP binds near the center of the fragment. This effect is due to a clear change in the persistence length of the DNA induced by CRP binding. We suggest that, upon binding, the protein introduces a local bend (or a kink) in the DNA structure.
Six mutations, which lead to an increase in malT expression, were mapped by sequencing techniques. All of them had one or other of two base changes. Determination of the transcription start point by reverse transcriptase mapping localised the two base changes with respect to the elements that control malT expression. One of the base changes (malTp1) is located in the Pribnow box of the promoter, and presumably results in an increase in the rate of transcription initiation. The other (malTp7) is located in the Shine and Dalgarno sequence, which precedes the malT cistron. It probably created a more favourable ribosome binding site on malT mRNA. A correlate of these observations is that the promoter and the ribosome binding site are both inefficient in a wild‐type malT gene. A malTp1 malTp7 double mutant was constructed, which produced equivalent to 30 times more MalT protein than the wild‐type strain.
Several proteins are involved in the early steps of the spliceosome assembly pathway. Protein-protein interactions have been identified between two Saccharomyces cerevisiae yeast splicing factors, PRP9 and SPP91. Here it is demonstrated that protein-protein interactions occur between SPP91 and PRP11. The combination of the prp9-1 mutant and a truncated prp11 mutant exhibits a synthetic lethal phenotype, suggestive of a common biochemical defect. The PRP9 and PRP11 proteins do not interact directly, but the PRP9 and PRP11 molecules can simultaneously bind SPP91 to form a three-molecule complex. Structurally and functionally related proteins are found in mammalian cells and are associated in a single biochemical fraction. This strongly suggests that the PRP9-SPP91-PRP11 complex is a key element of the splicing machinery.
The PRP9 protein is a yeast splicing factor implicated in the early steps of spliceosome assembly whose sequence contains an amino-terminal putative leucine zipper structure and two carboxy-terminal motifs reminiscent of zinc fingers. Here, we show that the deletion of the second carboxy-terminal motif results in a dominant lethal phenotype. This observation, combined with an in vivo-binding assay for protein-protein interactions, reveals the presence of two distinct binding sites on the PRP9 protein. The carboxy-terminal region contributes to the PRP9 homodimerization, whereas the amino-terminal region binds the SPP91 splicing [actor. Further experiments suggest that other factors bind to PRP9 and SPP91 proteins. Finally, we demonstrate that the PRP9 protein acts after the formation of the U1 snRNP-pre-mRNA complex. The existence of a protein complex including the PRP9 factor is discussed.[Key Words: PRP; yeast; GAL4 fusion protein; pre-mRNA splicing]
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