Centrifugal partition chromatography as a tool for preparative purification of pea albumin with enhanced yields

A new procedure including the use of centrifugal partition chromatography (CPC) is proposed to purify PA1b and its isoforms. These pea (Pisum sativum L.) seed proteins are toxic against weevils and can be used as an environment-friendly insecticide. CPC was applied to a whole albumin fraction prepared from pea flour. The butanol:aqueous TFA system used in CPC allowed the separation of PA1b from other albumins and a degree of purification above 95%. Compared to analytical procedures based on methanol extraction, anion exchange and then reversed-phase chromatography (RPC), CPC recovered PA1b in much better yield, which is indispensable for large-scale purification of a biodegradable insecticide.     

A PQL (protein quantity loci) analysis of mature pea seed proteins identifies loci determining seed protein composition

Legume seeds are a major source of dietary proteins for humans and animals. Deciphering the genetic control of their accumulation is thus of primary significance towards their improvement. At first, we analysed the genetic variability of the pea seed proteome of three genotypes over 3 years of cultivation. This revealed that seed protein composition variability was under predominant genetic control, with as much as 60% of the spots varying quantitatively among the three genotypes. Then, by combining proteomic and quantitative trait loci (QTL) mapping approaches, we uncovered the genetic architecture of seed proteome variability. Protein quantity loci (PQL) were searched for 525 spots detected on 2-D gels obtained for 157 recombinant inbred lines. Most protein quantity loci mapped in clusters, suggesting that the accumulation of the major storage protein families was under the control of a limited number of loci. While convicilin accumulation was mainly under the control of cis-regulatory regions, vicilins and legumins were controlled by both cis- and trans-regulatory regions. Some loci controlled both seed protein composition and protein content and a locus on LGIIa appears to be a major regulator of protein composition and of protein in vitro digestibility.     

Association among growth, food consumption-related traits and amylase gene polymorphism in the Pacific oyster Crassostrea gigas

To examine further a previously reported association between amylase gene polymorphism and growth in the Pacific oyster Crassostrea gigas, ecophysiological parameters and biochemical and molecular expression levels of alpha-amylase were studied in Pacific oysters of different amylase genotypes. Genotypes that previously displayed significantly different growth were found to be significantly different for ingestion and absorption efficiency. These estimated parameters, used in a dynamic energy budget model, showed that observed ingestion rates (unlike absorption efficiencies) allowed an accurate prediction of growth potential in these genotypes. The observed association between growth and amylase gene polymorphism is therefore more likely to be related to ingestion than to absorption efficiency. Additionally, relative mRNA levels of the two amylase cDNAs were also strongly associated with amylase gene polymorphism, possibly reflecting variation in an undefined regulatory region, although no corresponding variation was observed in specific amylase activity. Amylase gene sequences were determined for each genotype, showing the existence of only synonymous or functionally equivalent non-synonymous polymorphisms. The observed associations among growth, food consumption-related traits and amylase gene polymorphism are therefore more likely to be related to variation in the level of amylase gene expression than to functional enzymatic variants.     

Biodistribution of 111indium-labeled macrophages infused intravenously in patients with renal carcinoma

PURPOSE: We have previously reported a clinical trial on the intravenous injection of autologous activated macrophages (AAM) in 15 patients with renal carcinoma. The present paper concerns scintigraphic investigations performed in 11 of these patients after injection of 111indium oxinate-radiolabeled AAM. METHODS: AAM were prepared from mononuclear cells (MNC) collected by apheresis from patients treated simultaneously with granulocyte-macrophage colony-stimulating factor (GM-CSF). MNC were cultured for 6 days in the presence of GM-CSF and exposed for 18 h to gamma-interferon, the AAM were then separated by elutriation and injected. RESULTS: After intravenous infusion, radiolabeled AAM were transiently retained in the lungs, where they predominated in the first hour. Later on, radioactivity accumulated in liver and spleen and then decreased from the first and second day, respectively. In one patient, two foci of radioactivity were detected in the lungs 1 h after injection, and persisted thereafter. Their association with tumor lesions was uncertain. This observation possibly resulted from the presence of granulocytes in the radiolabeled AAM populations of this patient. It seems that MNC collected from GM-CSF-treated patients and cultured in the presence of GM-CSF enables the differentiation of granulocytes. CONCLUSIONS: A series of 11 investigations confirms the previously reported distribution pattern of intravenously injected AAM. It is possible that in patients treated with hematopoietic cell-mobilizing agents, granulocytes develop in cultures designed to produce monocyte-derived antigen-presenting cells.     

3D Protein Dynamics in the Cell Nucleus

The three-dimensional (3D) architecture of the cell nucleus plays an important role in protein dynamics and in regulating gene expression. However, protein dynamics within the 3D nucleus are poorly understood. Here, we present, to our knowledge, a novel combination of 1) single-objective based light-sheet microscopy, 2) photoconvertible proteins, and 3) fluorescence correlation microscopy, to quantitatively measure 3D protein dynamics in the nucleus. We are able to acquire >3400 autocorrelation functions at multiple spatial positions within a nucleus, without significant photobleaching, allowing us to make reliable estimates of diffusion dynamics. Using this tool, we demonstrate spatial heterogeneity in Polymerase II dynamics in live U2OS cells. Further, we provide detailed measurements of human-Yes-associated protein diffusion dynamics in a human gastric cancer epithelial cell line.     

Psychological essentialism from first principles

Cognitive scientists have documented the existence of “essentialist” intuitions in humans: from a very early age, we assume that things have deep unobserved properties that make them what they are. I provide a sketch of an adaptationist explanation of psychological essentialism, arguing that these intuitions are the unsurprising output of adaptations for inductive inference. Variations on this insight have previously been used mostly as after-the-fact speculations, yet theories of adaptive function should ideally have a primary role in informing psychological research. Here I propose that viewing essentialist intuitions through an adaptationist lens has implications for some widespread assumptions about the phenomenon. Notably, researchers' focus on “higher-level” processes like categorization has led them to assume that essentialism is restricted to a few cognitive processes, but the ubiquity of inductive inference problems in cognition suggests otherwise. Additionally, because essentialist intuitions are the output of mechanisms solving related but distinct inference problems, it is unlikely that a single mechanistic theory can account for them all.     

Phototransformable fluorescent proteins: which one for which application?

In these last two decades , fluorescent proteins (FPs) have become highly valued imaging tools for cell biology, owing to their compatibility with living samples, their low levels of invasiveness and the possibility to specifically fuse them to a variety of proteins of interest. Remarkably, the recent development of phototransformable fluorescent proteins (PTFPs) has made it possible to conceive optical imaging experiments that were unimaginable only a few years ago. For example, it is nowadays possible to monitor intra- or intercellular trafficking, to optically individualize single cells in tissues or to observe single molecules in live cells. The tagging specificity brought by these genetically encoded highlighters leads to constant progress in the engineering of increasingly powerful, versatile and non-cytotoxic FPs. This review is focused on the recent developments of PTFPs and highlights their contribution to studies within cells, tissues and even living organisms. The aspects of single-molecule localization microscopy, intracellular tracking of photoactivated molecules, applications of PTFPs in biotechnology/optobiology and complementarities between PTFPs and other microscopy techniques are particularly discussed.