A competing salt-bridge suppresses helix formation by the isolated C-peptide carboxylate of ribonuclease A

The C-peptide of ribonuclease A (residues 1 to 13) is obtained by cyanogen bromide cleavage at Met13, which converts methionine to a mixture of homoserine lactone (giving C-peptide lactone) and homoserine carboxylate (giving C-peptide carboxylate). The helix-forming properties of C-peptide lactone have been reported. The helix is formed intramolecularly in aqueous solution, is stabilized at low temperatures (0 to 20 °C) and also by a pH-dependent interaction between sidechains. The C-peptide lactone helix is about 1000-fold more stable than expected from “host-guest” data for helix formation in synthetic polypeptides.Here we report the failure of C-peptide carboxylate to form an α-helix in comparable conditions. Formation of a salt-bridge between the α-COO^? group and the imidazolium ring of His12⁺ appears to be responsible for the suppression of helix formation. The presence of the Hse13-COO^? … His12⁺ salt-bridge in C-peptide carboxylate is shown by ¹H nuclear magnetic resonance titration of the amide proton resonances of His12 and Hse13, and is expected from model peptide studies. The most probable reason why C-peptide carboxylate does not form an α-helix is that the Hse13-COO^? … His12⁺ salt-bridge competes successfully with a helix stabilizing salt-bridge (Glu9^? … His12⁺).S-peptide (residues 1 to 20 of ribonuclease A) does form an α-helix with properties similar to those of the C-peptide (lactone) helix, which shows that the lactone ring of C-peptide lactone is not needed for helix formation.These results support the hypothesis that a Glu9^? … His12⁺ salt-bridge stabilizes the C-peptide (lactone) helix, and they show that specific interactions between side-chains can be important in preventing as well as in promoting α-helix formation.     

HineI is an isoschizomer of HinfIII restriction endonuclease

HineI is a restriction enzyme isolated from Haemophilus influenzae strain Re. Like other type III restriction endonucleases it requires ATP for cleavage and S-adenosyl-methionine for methylation of DNA. This enzyme recognises the same sequence as HinfIII (Piekarowicz et al., 1981) and cleaves and methylates DNA in a manner similar to all type III restriction enzymes.     

Adenosylhomocysteinase:Adenosine complex

Adenosylhomocysteinase from yellow lupin seeds forms a specific complex with adenosine. The complex can be isolated either by nonequilibrium or equilibrium gel filtration. It is also adsorbed on nitrocellulose disks. Dissociation constant of the complex determined by nitrocellulose filter assay is 5 × 10^?8M.     

An Haemophilus influenzae mutant which inhibits the growth of HP1c1 phage

Summary A strain of Haemophilus influenzae, called hpm ^- inhibits the growth of phage HP1c1 but not S2. This inhibition is overcome by HP1c1ph mutants. Phage HP1c1 adsorbs normally to hpm ^- cells but only a small fraction of infected cells produce phage with a normal burst size or become lysogenic. When hpm ^- strains lysogenic for HP1c1 are induced, 100% of the cells yield phage. There is no degradation of phage DNA after infection of hpm ^- cells and HP1c1 can normally grow when its DNA is introduced into hpm ^- by transfection. The most probable explanation is that in hpm ^- cells the penetration of phage DNA is blocked. The hpm ^- property behaves as as unstable mutation.     

Relationship between polycomb‐group protein BMI‐1 and phosphatases regulating AKT phosphorylation level in endometrial cancer

The PI3K/AKT pathway is frequently activated in endometrial carcinoma. BMI‐1 (B‐lymphoma Mo‐MLV insertion region 1) protein affects expression of PTEN (phosphatase and tensin homolog) in some cancers, but its significance for endometrial tumorigenesis is not known. The objective of this study was to determine the relationship between BMI‐1 and expression of factors affecting AKT (protein kinase B) phosphorylation level in endometrial cancer. The expression of proteins and mRNAs was investigated in endometrial cancer specimens and samples of non‐neoplastic endometrial tissue by Western blot and RT‐PCR, respectively. The impact of BMI‐1 down‐regulation on AKT phosphorylation and expression of genes coding for several phosphatases were studied in HEC1A cells. The results showed that BMI‐1 depletion caused increase in PHLPP1 and PHLPP2 (PH domain and leucine‐rich repeat protein phosphatases 1/2) expression and decrease in phospho‐AKT (pAKT) level. In more advanced tumours with higher metastatic potential, the expression of BMI‐1 was lower compared to tumours less advanced and without lymph node metastasis. There were significant inverse correlations between BMI‐1 and PHLPPs, especially PHLPP1 in normal endometrial samples. The inverse correlation between BMI‐1 and PHLPP1/PHLPP2 expression was observed in PTEN positive but not PTEN negative cancers. Low PHLPP2 expression in tumours predicted poorer overall survival. BMI‐1 impacts on AKT phosphorylation level in endometrial cells by regulation of PHLPP expression.