A Method for Structure–Activity Analysis of Quorum-Sensing Signaling Peptides from Naturally Transformable Streptococci

Many species of streptococci secrete and use a competence-stimulating peptide (CSP) to initiate quorum sensing for induction of genetic competence, bacteriocin production, and other activities. These signaling molecules are small, unmodified peptides that induce powerful strain-specific activity at nano-molar concentrations. This feature has provided an excellent opportunity to explore their structure–function relationships. However, CSP variants have also been identified in many species, and each specifically activates its cognate receptor. How such minor changes dramatically affect the specificity of these peptides remains unclear. Structure–activity analysis of these peptides may provide clues for understanding the specificity of signaling peptide–receptor interactions. Here, we use the Streptococcus mutans CSP as an example to describe methods of analyzing its structure–activity relationship. The methods described here may provide a platform for studying quorum-sensing signaling peptides of other naturally transformable streptococci

Early anthropogenic transformation of the Danube-Black Sea system

© The Author(s), 2012. This article is distributed under the terms of the Creative Commons Attribution License. The definitive version was published in Scientific Reports 2 (2012): 582, doi:10.1038/srep00582.Over the last century humans have altered the export of fluvial materials leading to significant changes in morphology, chemistry, and biology of the coastal ocean. Here we present sedimentary, paleoenvironmental and paleogenetic evidence to show that the Black Sea, a nearly enclosed marine basin, was affected by land use long before the changes of the Industrial Era. Although watershed hydroclimate was spatially and temporally variable over the last ~3000 years, surface salinity dropped systematically in the Black Sea. Sediment loads delivered by Danube River, the main tributary of the Black Sea, significantly increased as land use intensified in the last two millennia, which led to a rapid expansion of its delta. Lastly, proliferation of diatoms and dinoflagellates over the last five to six centuries, when intensive deforestation occurred in Eastern Europe, points to an anthropogenic pulse of river-borne nutrients that radically transformed the food web structure in the Black Sea.This study was supported by grants OISE 0637108, EAR 0952146, OCE 0602423 and OCE 0825020 from the National Science Foundation and grants from the Woods Hole Oceanographic Institution

The changing carbon cycle of the coastal ocean

The carbon cycle of the coastal ocean is a dynamic component of the global carbon budget. But the diverse sources and sinks of carbon and their complex interactions in these waters remain poorly understood. Here we discuss the sources, exchanges and fates of carbon in the coastal ocean and how anthropogenic activities have altered the carbon cycle. Recent evidence suggests that the coastal ocean may have become a net sink for atmospheric carbon dioxide during post-industrial times. Continued human pressures in coastal zones will probably have an important impact on the future evolution of the coastal ocean's carbon budget

Profiling whole microalgal cells by high-resolution magic angle spinning (HR-MAS) magnetic resonance spectroscopy

Microalgae are a rich source of high value compounds such as carbohydrates, lipids, proteins and bioactive compounds. In particular, microalgae have been identified as a potentially important resource for carboncapture and as a feedstock for green biofuels. Successful cultivation of microalgae can occur under a variety of nutrient and environmental conditions with each condition producing a unique distribution of compounds. In order to steer the cultivation towards a particular distribution of compounds, rapid and accurate methods for compound identification are required. Current methods for determining the absolute quantity of each component are time consuming and arduous making cultivation optimization impractical. High-resolution magic angle spinning (HR-MAS) nuclear magnetic resonance (NMR) spectroscopy offers a robust and rapid screening method capable of ascertaining the absolute quantity of each component with minimal sample manipulation. Sample preparation consists of harvested, centrifuged and freeze-dried whole-cell Nannochloropsis granulata from large-scale photobioreactors being accurately weighed and rehydrated with deuterium oxide and placed in an HR-MAS rotor. One-dimensional HR-MAS NMR spectra were recorded under quantitative conditions to determine the lipid and carbohydrate profile of the microalgae. The total time per sample for preparation, data acquisition and analysis was approximately 1 h. Changes in resonance profiles corresponding to varying proportions of saturated and polyunsaturated fatty acids were correlated to the time of harvest. In addition, standard two dimensional experiments were used to identify the major carbohydrate components. HR-MAS NMR spectroscopy has been used to profile the lipid and carbohydrate content of N. granulata and we have begun to establish methodologies for quality analysis/quality control for cultivation of various microalgal strains.Peer reviewed: YesNRC publication: Ye

Biomolecular sample considerations essential for optimal performance from cryogenic probes

For compounds dissolved in non-polar solvents, nuclear magnetic resonance spectroscopic investigations have benefited greatly from the advent of cryogenically cooled probes. Unfortunately the allure of significant increases in sensitivity may not be realized for compounds such as metabolites that are dissolved in solvents with high ionic-strengths such as solutions typically utilized for metabolomic or biomolecular investigations. In some cases there is little benefit from a cryogenically cooled probe over a conventional room temperature probe. Various sample preparation methods have been developed to minimize the detrimental effects of salt; for large numbers of metabolomic samples these preparation methods tend to be onerous and impractical. An alternative to manipulating the sample, is to utilize a probe that is designed to have a higher tolerance for solutions with high ionic-strengths. In order to acquire high-quality optimal data and choose the appropriate probe configuration (especially important for comparative quantitative investigations) the effects of salts and buffers on cryogenic probe performance must be understood. Herein we detail sample considerations for two cryogenic probes, a standard 5 mm and a narrow diameter 1.7 mm, in an effort to identify via integrals, intensities and noise levels the optimal choice for biomolecular investigations.Peer reviewed: YesNRC publication: Ye