A peptide model for proline isomerism in the unfolded state of staphylococcal nuclease.

Nuclear magnetic resonance spectroscopy has been used to investigate a synthetic peptide (YVYKPNNTHE) corresponding to residues 113 to 122 of staphylococcal nuclease. In the major folded state of the protein this region forms a type VIa beta-turn containing a cis Lys116-Pro117 peptide bond. There is, however, no evidence for any significant population of such a turn in the peptide in aqueous solution and the X-Pro bond is predominantly in the trans configuration. The peptide exhibits several well-resolved minor resonances due to the presence of a small fraction (4 +/- 2%) of the cis-proline isomer. The ratio of cis to trans isomer populations was found to be independent of temperature between 5 degrees C and 70 degrees C, indicating that delta H for the isomerism is close to zero. Using magnetization transfer techniques the rate of trans to cis interconversion was found to be 0.025(+/- 0.013) s-1 at 50 degrees C. The thermodynamics and kinetics of isomerism in the peptide are very similar to those estimated for the Lys116-Pro117 peptide bond in unfolded nuclease, suggesting that the cis-trans equilibrium in the unfolded protein is largely determined by the residues adjacent to Pro117 in the sequence. These results are consistent with previous suggestions that the cis-proline bond is stabilized late in the folding process and that the predominance of the cis form in folded nuclease is due to stabilizing interactions within the protein that give rise to a favorable enthalpy term.     

Extrapair mating between relatives in the barn swallow: a role for kin selection?

Why do females of many species mate with more than one male? One of the main hypotheses suggests that female promiscuity is an insurance mechanism against the potential detrimental effects of inbreeding. Accordingly, females should preferably mate with less related males in multiple or extrapair mating. Here we analyse paternity, relatedness among mating partners, and relatedness between parents and offspring, in the socially monogamous North American barn swallow (Hirundo rustica erythrogaster). In contrast to the inbreeding avoidance hypothesis, we found that extrapair mating partners were more related than expected by random choice, and tended to be more related than social partners. Furthermore, extrapair mating resulted in genetic parents being more related to their extrapair young than to their withinpair young. We propose a new hypothesis for extrapair mating based on kin selection theory as a possible explanation to these findings.     

Cassette-like variation of restriction enzyme genes in Escherichia coli C and relatives

A surprising result of comparative bacterial genomics has been the large amount of DNA found to be present in one strain but not in another of the same species. We examine in detail one location where gene content varies extensively, the restriction cluster in Escherichia coli. This region is designated the Immigration Control Region (ICR) for the density and variability of restriction functions found there. To better define the boundaries of this variable locus, we determined the sequence of the region from a restrictionless strain, E.coli C. Here we compare the 13.7 kb E.coli C sequence spanning the site of the ICR with corresponding sequences from five E.coli strains and Salmonella typhimurium LT2. To discuss this variation, we adopt the term ‘framework’ to refer to genes that are stable components of genomes within related lineages, while ‘migratory’ genes are transient inhabitants of the genome. Strikingly, seven different migratory DNA segments, encoding different sets of genes and gene fragments, alternatively occupy a single well-defined location in the seven strains examined. The flanking framework genes, yjiS and yjiA, display approximately normal patterns of conservation. The patterns observed are consistent with the action of a site-specific recombinase. Since no nearby gene codes for a likely recombinase of known families, such a recombinase must be of a new family or unlinked.     

The role of His-18 in amyloid formation by human islet amyloid polypeptide

The 37-residue islet amyloid polypeptide (IAPP) is the major protein component of the amyloid deposits found in type-II diabetes. IAPP is stored in a relatively low pH environment in the pancreatic secretory granules prior to its release to the extracellular environment. Human IAPP contains a single histidine at position 18. Aggregation of IAPP is considerably faster at a lower pH (4.0 +/- 0.3) than at high pH (8.8 +/- 0.3), as judged by turbidity and thioflavine-T fluorescence studies. The rate of aggregation at low pH increases drastically in the presence of salt. CD experiments show that the conversion of largely unstructured monomers to beta-sheet-rich structures is faster at high pH. TEM studies show that fibrils are formed at both pH values but are more prevalent at pH 8.8 (+/-0.3). Both the free N terminus of IAPP and His-18 will titrate over the pH range studied. An N-terminal acetylated fragment consisting of residues 8-37 of human IAPP was also studied to isolate contributions from the protonation of His-18. Previous studies have shown that this fragment forms protofibrils that are very similar to those formed by intact IAPP. The effects of varying the protonation state of His-18 in the 8-37 analogue indicate that the rate of aggregation and fibril formation is noticeably faster when His-18 is deprotonated, similar to the wild type. However, the pH-dependent effects are larger for full-length IAPP than for the disulfide-truncated, acetylated analogue. TEM studies indicate differences in the morphology of the deposits formed at high and low pH. These results are discussed in light of recent structural models of IAPP fibrils.     

pH-dependent interactions and the stability and folding kinetics of the N-terminal domain of L9. Electrostatic interactions are only weakly formed in the transition state for folding

The role of electrostatic interactions in the stability and the folding of the N-terminal domain of the ribosomal protein L9 (NTL9) was investigated by determining the effects of varying the pH conditions. Urea denaturations and thermal unfolding experiments were used to measure the free energy of folding, DeltaG degrees, at 18 different pH values, ranging from pH 1.1 to pH 10.5. Folding rates were measured at 19 pH values between pH 2.1 and pH 9.5, and unfolding rates were determined at 15 pH values in this range using stopped-flow fluorescence experiments. The protein is maximally stable between pH 5.5 and 7.5 with a value of DeltaG degrees =4.45 kcal mol(-1). The folding rate reaches a maximum at pH 5.5, however the change in folding rates with pH is relatively modest. Over the pH range of 2.1 to 5.5 there is a small increase in folding rates, ln (k(f)) changes from 5.1 to 6.8. However, the change in stability is more dramatic, with a difference of 2.6 kcal mol(-1) between pH 2.0 and pH 5.4. The change in stability is largely due to the smaller barrier for unfolding at low pH values. The natural log of the unfolding rates varies by approximately four units between pH 2.1 and pH 5.5. The stability of the protein decreases above pH 7.5 and again the change is largely due to changes in the unfolding rate. ln (k(f)) varies by less than one unit between pH 5.5 and pH 9.5 while DeltaG degrees decreases by 2.4 kcal mol(-1) over the range of pH 5. 4 to pH 10.0, which corresponds to a change in ln K(eq) of 4.0. These studies show that pH-dependent interactions contribute significantly to the overall stability of the protein but have only a small effect upon the folding kinetics, indicating that electrostatic interactions are weakly formed in the transition state for folding.     

Effects of artificial defoliation of pines on the structure and physiology of the soil fungal community of a mixed pine-spruce forest

Loss of photosynthetic area can affect soil microbial communities by altering the availability of fixed carbon. We used denaturing gradient gel electrophoresis (DGGE) and Biolog filamentous-fungus plates to determine the effects of artificial defoliation of pines in a mixed pine-spruce forest on the composition of the fungal community in a forest soil. As measured by DGGE, two fungal species were affected significantly by the defoliation of pines (P < 0.001); the frequency of members of the ectomycorrhizal fungus genus Cenococcum decreased significantly, while the frequency of organisms of an unidentified soil fungus increased. The decrease in the amount of Cenococcum organisms may have occurred because of the formation of extensive hyphal networks by species of this genus, which require more of the carbon fixed by their host, or because this fungus is dependent upon quantitative differences in spruce root exudates. The defoliation of pines did not affect the overall composition of the soil fungal community or fungal-species richness (number of species per core). Biolog filamentous-fungus plate assays indicated a significant increase (P < 0.001) in the number of carbon substrates utilized by the soil fungi and the rate at which these substrates were used, which could indicate an increase in fungal-species richness. Thus, either small changes in the soil fungal community give rise to significant increases in physiological capabilities or PCR bias limits the reliability of the DGGE results. These data indicate that combined genetic and physiological assessments of the soil fungal community are needed to accurately assess the effect of disturbance on indigenous microbial systems.