Cullin 3 Is Crucial for Pro-B Cell Proliferation, Interacts with CD22, and Controls CD22 Internalization on B Cells.

B lymphocytes are important players of the adaptive immune system. However, not just activation of B cells but also regulation of B cell signaling is important to prevent hyperactivity and dysregulation of the immune response. Different mechanisms and proteins contribute to this balance. One of these is CD22, a member of the Siglec family. It is an inhibitory coreceptor of the BCR and inhibits B cell activation. Upon BCR stimulation, CD22-dependent inhibition of BCR signaling results in a decreased calcium mobilization. Although some CD22 binding partners have already been identified, the knowledge about the CD22 interactome is still incomplete. In this study, quantitative affinity purification-mass spectrometry enabled the delineation of the CD22 interactome in the B cell line DT40. These data will clarify molecular mechanisms and CD22 signaling events after BCR activation and revealed several new CD22-associated proteins. One new identified interaction partner is the E3 ubiquitin ligase cullin 3, which was revealed to regulate CD22 surface expression and clathrin-dependent CD22 internalization after BCR stimulation. Furthermore cullin 3 was identified to be important for B lymphocytes in general. B cell-specific cullin 3-deficient mice show reduced developing B cells in the bone marrow and a severe pro-B cell proliferation defect. Mature B cells in the periphery are also reduced and characterized by increased CD22 expression and additionally by preactivated and apoptotic phenotypes. The findings reveal novel functions of cullin 3 in B lymphocytes, namely regulating CD22 surface expression and internalization after B cell activation, as well as promoting proliferation of pro-B cells.

Author Correction: Marrying chemistry with biology by combining on-chip solution-based combinatorial synthesis and cellular screening.

An amendment to this paper has been published and can be accessed via a link at the top of the paper.

Marrying chemistry with biology by combining on-chip solution-based combinatorial synthesis and cellular screening.

Drug development often relies on high-throughput cell-based screening of large compound libraries. However, the lack of miniaturized and parallelized methodologies in chemistry as well as strict separation and incompatibility of the synthesis of bioactive compounds from their biological screenings makes this process expensive and inefficient. Here, we demonstrate an on-chip platform that combines solution-based synthesis of compound libraries with high-throughput biological screenings (chemBIOS). The chemBIOS platform is compatible with both organic solvents required for the synthesis and aqueous solutions necessary for biological screenings. We use the chemBIOS platform to perform 75 parallel, three-component reactions to synthesize a library of lipidoids, followed by characterization via MALDI-MS, on-chip formation of lipoplexes, and on-chip cell screening. The entire process from the library synthesis to cell screening takes only 3 days and about 1 mL of total solutions, demonstrating the potential of the chemBIOS technology to increase efficiency and accelerate screenings and drug development.

Tissue Extracts for Quantitative Mass Spectrometry of Planarian Proteins Using SILAC.

SILAC (stable isotope labeling by amino acids in cell culture) proteomics enables the relative quantification of proteins in one or more biological samples by mass spectrometry. This technology is based on the metabolic incorporation of heavy isotope-labeled essential amino acids into nascent proteins in vivo. Here, we describe the preparation of SILAC protein samples from planarians, flatworms with high regenerative potential and tissue plasticity. Applications for SILAC proteomics of planarians include the analysis of protein abundances, protein-protein interactions and turnover rates during stem cell-based regeneration and tissue homeostasis.

One-Pot Parallel Synthesis of Lipid Library via Thiolactone Ring Opening and Screening for Gene Delivery.

Efficient delivery of nucleic acids into cells is of great interest in the field of cell biology and gene therapy. Despite a lot of research, transfection efficiency and structural diversity of gene-delivery vectors are still limited. A better understanding of the structure-function relationship of gene delivery vectors is also essential for the design of novel and intelligent delivery vectors, efficient in "difficult-to-transfect" cells and in vivo clinical applications. Most of the existing strategies for the synthesis of gene-delivery vectors require multiple steps and lengthy procedures. Here, we demonstrate a facile, three-component one-pot synthesis of a combinatorial library of 288 structurally diverse lipid-like molecules termed "lipidoids" via a thiolactone ring opening reaction. This strategy introduces the possibility to synthesize lipidoids with hydrophobic tails containing both unsaturated bonds and reducible disulfide groups. The whole synthesis and purification are convenient, extremely fast, and can be accomplished within a few hours. Screening of the produced lipidoids using HEK293T cells without addition of helper lipids resulted in identification of highly stable liposomes demonstrating ∼95% transfection efficiency with low toxicity.

Quantitative proteomics identifies redox switches for global translation modulation by mitochondrially produced reactive oxygen species.

The generation of reactive oxygen species (ROS) is inevitably linked to life. However, the precise role of ROS in signalling and specific targets is largely unknown. We perform a global proteomic analysis to delineate the yeast redoxome to a depth of more than 4,300 unique cysteine residues in over 2,200 proteins. Mapping of redox-active thiols in proteins exposed to exogenous or endogenous mitochondria-derived oxidative stress reveals ROS-sensitive sites in several components of the translation apparatus. Mitochondria are the major source of cellular ROS. We demonstrate that increased levels of intracellular ROS caused by dysfunctional mitochondria serve as a signal to attenuate global protein synthesis. Hence, we propose a universal mechanism that controls protein synthesis by inducing reversible changes in the translation machinery upon modulating the redox status of proteins involved in translation. This crosstalk between mitochondria and protein synthesis may have an important contribution to pathologies caused by dysfunctional mitochondria.

Quantitative Analysis of Protein-DNA Interaction by qDPI-ELISA.

The specific binding of DNA-binding proteins to their cognate DNA motifs is a crucial step for gene expression control and chromatin organization in vivo. The development of methods for the identification of in vivo binding regions by, e.g. chromatin immunoprecipitation (ChIP) or DNA adenine methyltransferase identification (Dam-ID) added an additional level of qualitative information for data mining in systems biology or applications in synthetic biology. In this respect, the in vivo techniques outpaced methods for thorough characterization of protein-DNA interaction and, especially, of the binding motifs at single base-pair resolution. The elucidation of DNA-binding capacities of proteins is frequently done with methods such as yeast one-hybrid, electrophoretic mobility shift assay (EMSA) or systematic evolution of ligands by exponential enrichment (SELEX) that provide only qualitative binding information and are not suited for automation or high-throughput screening of several DNA motifs. Here, we describe the quantitative DNA-protein-Interaction-ELISA (qDPI-ELISA) protocol, which makes use of fluorescent fusion proteins and, hence, is faster and easier to handle than the classical DPI-ELISA. Although every DPI-ELISA experiment delivers quantitative information, the qDPI-ELISA has an increased consistency, as it does not depend on immunological detection. We demonstrate the high comparability between probes and different protein extracts in qDPI-ELISA experiments.

SILAC proteomics of planarians identifies Ncoa5 as a conserved component of pluripotent stem cells.

Planarian regeneration depends on the presence of pluripotent stem cells in the adult. We developed an in vivo stable isotope labeling by amino acids in cell culture (SILAC) protocol in planarians to identify proteins that are enriched in planarian stem cells. Through a comparison of SILAC proteomes of normal and stem cell-depleted planarians and of a stem cell-enriched population of sorted cells, we identified hundreds of stem cell proteins. One of these is an ortholog of nuclear receptor coactivator-5 (Ncoa5/CIA), which is known to regulate estrogen-receptor-mediated transcription in human cells. We show that Ncoa5 is essential for the maintenance of the pluripotent stem cell population in planarians and that a putative mouse ortholog is expressed in pluripotent cells of the embryo. Our study thus identifies a conserved component of pluripotent stem cells, demonstrating that planarians, in particular, when combined with in vivo SILAC, are a powerful model in stem cell research.