Ammoniacal silver staining of proteins: mechanism of glutaraldehyde enhancement

When the conditions for detecting proteins by ammoniacal silver staining (B. R. Oakley, D. R. Kirsch, and N. R. Morris (1980) Anal. Biochem. 105, 361-363.) following gel electrophoresis were varied, it was noted that glutaraldehyde pretreatment was necessary for maximal staining, which could not be explained simply as the result of "fixation." Further studies indicated that glutaraldehyde enhancement of protein staining with this silver reagent was probably due to oxidation of the aldehyde groups by silver ions, resulting in metallic silver depositions within the gel which act as nucleation sites for additional metallic silver localization in the protein bands upon the addition of formaldehyde developer. This proposed mechanism is consistent with the Tollen's reaction, as well as some aspects of the photographic process. Consistent with this notion, silver-staining intensities are directly related to mole percentage lysine of various standard proteins.     

Interaction of an artificial antimicrobial peptide with lipid membranes

Antimicrobial peptides constitute an important part of the innate immune defense and are promising new candidates for antibiotics. Naturally occurring antimicrobial peptides often possess hemolytic activity and are not suitable as drugs. Therefore, a range of new synthetic antimicrobial peptides have been developed in recent years with promising properties. But their mechanism of action is in most cases not fully understood. One of these peptides, called V4, is a cyclized 19 amino acid peptide whose amino acid sequence has been modeled upon the hydrophobic/cationic binding pattern found in Factor C of the horseshoe crab (Carcinoscorpius rotundicauda). In this work we used a combination of biophysical techniques to elucidate the mechanism of action of V4. Langmuir-Blodgett trough, atomic force microscopy, Fluorescence Correlation Spectroscopy, Dual Polarization Interference, and confocal microscopy experiments show how the hydrophobic and cationic properties of V4 lead to a) selective binding of the peptide to anionic lipids (POPG) versus zwitterionic lipids (POPC), b) aggregation of vesicles, and above a certain concentration threshold to c) integration of the peptide into the bilayer and finally d) to the disruption of the bilayer structure. The understanding of the mechanism of action of this peptide in relation to the properties of its constituent amino acids is a first step in designing better peptides in the future.     

A comparison of the enzymatic responses of the DNA polymerases from four RNA tumor viruses.

DNA polymerases from avian, feline, murine and simian RNA tumor viruses exhibit substantial differences in optimal assay conditions and vary widely in their template-primer preferences. Avian DNA polymerase utilizes both natural and synthetic template-primers efficiently in the presence of Mg⁺⁺ as well as Mn⁺⁺. By contrast, the mammalian viral DNA polymerases are much more responsive to poly(A)·oligo(dT) than to other template-primers, and exhibit up to 20-fold greater activity with Mn⁺⁺ than with Mg⁺⁺. In addition, simian sarcoma virus DNA polymerase shows no detectable response to poly(C)·oligo(dG) over a wide variety of conditions stimulatory to the other viral enzymes.     

Thyrotropin releasing hormone receptors in regulation of prolactin gene expression in GH cells

Calf thymus DNA polymerase β and mammalian type C retroviral DNA polymerases are strongly inhibited by low concentrations (1–2mM) of inorganic phosphate (Pi). A detailed analysis of this phenomenon revealed that Pi-mediated inhibition: a) requires the presence of Mn²⁺ (Mg²⁺ neither supports nor relieves this inhibition; b) is strongly affected by the stoichiometric relationship between Mn²⁺ and Pi concentrations; c) is competitive with respect to deoxynucleoside triphosphate (dNTP) concentration, and d) increasing the concentration of substrate or non-substrate dNTPs in reaction mixtures raised the concentration of Mn²⁺ at which significant inhibition by a fixed concentration of Pi was first seen. These findings suggested that Mn²⁺, dNTPs, and Pi may interact in Pi-mediated inhibition. Thin-layer chromatographic analysis revealed the formation of an Mn-dNTP-Pi complex, while Mg²⁺ did not participate in such complex formation. We propose that it is this tripartite complex which is responsible for the Pi-mediated inhibition of sensitive DNA polymerases.