Substrate specificity determinants for casein kinase II as deduced from studies with synthetic peptides

The specificity of casein kinase II has been further defined by analyzing the kinetics of phosphorylation reactions using a number of different synthetic peptides as substrates. The best peptide substrates are those in which multiple acidic amino acids are present on both sides of the phosphorylatable serine or threonine. Acidic residues on the NH2-terminal side of the serine (threonine) greatly enhance the kinetic constants but are not absolutely required. Acidic residues on the COOH-terminal side of the serine (threonine) are absolutely required. One position for which the occupation of an acidic residue is especially critical is the position located 3 residues to the COOH terminus of the phosphate acceptor site, although the presence of an acidic amino acid in the positions that are 4 or 5 residues removed may also provide an appropriate structure that will serve as a substrate for the kinase. Aspartate serves as a better amino acid determinant than glutamate. A relatively short sequence of amino acids surrounding the phosphate acceptor site appears to serve as the basis for the specificity of casein kinase II. The peptides in this study were also assayed with casein kinase I and the casein kinase from the mammary gland so that the specificities of these kinases could be compared to that of casein kinase II.     

PCR mutagenesis identifies a polymerase-binding sequence of sigma 54 that includes a sigma 70 homology region.

Sigma 54 is a minor bacterial sigma factor that is not a member of the sigma 70 family of proteins but binds the same core RNA polymerase. Previously, we identified a region of sigma 54 that is important for binding core polymerase. In this work, PCR mutagenesis was used to identify specific amino acids important for this binding. The results show that important residues are clustered most closely in a short sequence that was previously speculated to be potentially homologous to a sequence in sigma 70. The mutagenesis also identifies important residues in the flanking hydrophobic-acidic region of sigma 54, which is absent in sigma 70. Overall, the data indicate that sigma 54 binds core polymerase through a sequence homologous to that of sigma 70 but in addition uses unique motifs to modify this interaction.     

The flgE gene of Campylobacter coli is under the control of the alternative sigma factor sigma54.

The flgE gene encoding the flagellar hook protein of Campylobacter coli VC167-T1 was cloned by immunoscreening of a genomic library constructed in lambdaZAP Express. The flgE DNA sequence was 2,553 bp in length and encoded a protein with a deduced molecular mass of 90,639 Da. The sequence had significant homology to the 5' and 3' sequences of the flgE genes of Helicobacter pylori, Treponema phagedenis, and Salmonella typhimurium. Primer extension analysis indicated that the VC167 flgE gene is controlled by a sigma54 promoter. PCR analysis showed that the flgE gene size and the 5' and 3' DNA sequences were conserved among C. coli and C. jejuni strains. Southern hybridization analyses confirmed that there is considerable sequence identity among the hook genes of C. coli and C. jejuni but that there are also regions within the genes which differ. Mutants of C. coli defective in hook production were generated by allele replacement. These mutants were nonmotile and lacked flagellar filaments. Analyses of flgE mutants indicated that the carboxy terminus of FlgE is necessary for assembly of the hook structure but not for secretion of FlgE and that, unlike salmonellae, the lack of flgE expression does not result in repression of flagellin expression.     

Putative mechanism of natural transformation as deduced from genome data.

Genetic transformation is widely utilized in molecular biology as a tool for gene cloning in Escherichia coli and for gene mapping in Bacillus subtilis. Several strains of eubacteria can naturally take up exogenous DNA and integrate the DNA into their own genomes. Molecular details of natural transformation, however, remained to be elucidated. The complete genome of a cyanobacterium, Synechocystis sp. PCC6803, has been sequenced. This bacterium has been used to examine functions of a particular gene. The genome is considered to carry information on natural transformable characteristics of Synechocystis. The first step in genetic transformation is the uptake of exogenous DNA. Proteins with non-specific DNA binding features are required, because specificity in the exogenous DNA has not been demonstrated. Such proteins have modules interacting with the phosphate backbone of DNA, including helix-turn-helix modules. Using a consensus pattern of the phosphate-binding helix-turn-helix module, we searched through the genome data of Synechocystis for genes or open reading frame (ORF) products with the pattern in primary structures. We found that an ORF, slr0197, has the pattern in duplicate at the C-terminal region. We also found that the ORF product has a hydrophobic segment at the N-terminal region, which is followed by two internal repeats of the endonuclease domain. Based on these observations, we propose a model for the initial stage of genetic transformation. This is apparently the first report on molecular mechanisms of natural transformation.     

Enzymatic mechanism of creatine amidinohydrolase as deduced from crystal structures.

Crystal structures of the enzyme creatine amidinohydrolase (creatinase, EC 3.5.3.3) with two different inhibitors, the reaction product sarcosine and the substrate creatine, bound have been analyzed by X-ray diffraction methods. With the inhibitor carbamoyl sarcosine, two different crystal forms at different pH values have been determined. An enzymatic mechanism is proposed on the basis of the eight structures analyzed. The enzyme binds substrate and inhibitor in a distorted geometry where the urea resonance is broken. His232 is the general base and acid, and acts as a proton shuttle. It withdraws a proton from water 377 and donates it to the N(3) atom of the guanidinium group. OH- 377 adds to the C(1) atom of the guanidinium group to form a urea hydrate. Proton withdrawal by His232 leads to products. The reaction product sarcosine binds to the active site in a reverse orientation. The free enzyme was found to have a bicarbonate bound to the active site.     

Isolation and properties of enhancer-bypass mutants of sigma 54

The N-terminal activation domain of Escherichia coli sigma 54 was randomly mutated to provide a library of changes that might allow the required enhancer function to be bypassed. Five clones harbouring mutant sigma factors were obtained that exhibited this property in that they enhanced growth under nitrogen-limiting conditions in cells lacking NtrC. DNA sequence analysis located all mutations to four leucines in a small region between amino acids 25 and 31. No mutant sigma factors retained the hydrophobic character of the leucine residues. Mutant sigma factors were shown to transcribe in vitro without the need for enhancer binding activator or ATP hydrolysis, confirming the in vivo phenotype. These and other data suggest that a very small set of leucines is critical for keeping polymerase function in check, allowing high responsiveness to physiological induction via enhancer proteins such as NtrC.     

Two chemosensory operons of Rhodobacter sphaeroides are regulated independently by sigma 28 and sigma 54

Rhodobacter sphaeroides has a complex chemosensory system, with several loci encoding multiple homologues of the components required for chemosensing in Escherichia coli. The operons cheOp2 and cheOp3 each encode complete pathways, and both are essential for chemosensing. The components of cheOp2 are predominantly localized to the cell pole, whereas those encoded by cheOp3 are predominantly targeted to a discrete cluster in the cytoplasm. Here we show that the expression of the two pathways is regulated independently. Overlapping promoters recognized by sigma(28) and sigma(70) RNAP holoenzyme transcribe cheOp2, whereas cheOp3 is regulated by one of the four sigma(54) homologues, RpoN3. The different regulation of these operons may reflect the need for balancing responses to extra- and intracellular signals under different growth conditions.