Green fluorescent protein tagging Drosophila proteins at their native genomic loci with small P elements

We describe a technique to tag Drosophila proteins with GFP at their native genomic loci. This technique uses a new, small P transposable element (the Wee-P) that is composed primarily of the green fluorescent protein (GFP) sequence flanked by consensus splice acceptor and splice donor sequences. We demonstrate that insertion of the Wee-P can generate GFP fusions with native proteins. We further demonstrate that GFP-tagged proteins have correct subcellular localization and can be expressed at near-normal levels. We have used the Wee-P to tag genes with a wide variety of functions, including transmembrane proteins. A genetic analysis of 12 representative fusion lines demonstrates that loss-of-function phenotypes are not caused by the Wee-P insertion. This technology allows the generation of GFP-tagged reagents on a genome-wide scale with diverse potential applications.     

Catabolic transposons

The structure and function of transposable elements that code for catabolic pathways involved in the biodegradation of organic compounds are reviewed. Seven of these catabolic transposons have structural features that place them in the Class I (composite) or Class II (Tn3-family) bacterial elements. One is a conjugative transposon. Another three have been found to have properties of transposable elements but have not been characterized sufficiently to assign to a known class. Structural features of the toluene (Tn4651/Tn4653) and naphthalene (Tn4655) elements that illustrate the enormous potential for acquisition, deletion and rearrangement of DNA within catabolic transposons are discussed. The recently characterized chlorobenzoate (Tn5271) and chlorobenzene (Tn5280) catabolic transposons encode different aromatic ring dioxygenases, however they both illustrate the constraints that must be overcome when recipients of catabolic transposons assemble and regulate complete metabolic pathways for environmental pollutants. The structures of the chlorobenzoate catabolic transposon Tn5271 and the related haloacetate dehalogenase catabolic element of plasmid pUO1 are compared and a hypothesis for their formation is discussed. The structures and activities of catabolic transposons of unknown class coding for the catabolism of halogenated alkanoic acids (DEH) and chlorobiphenyl (Tn4371) are also reviewed.     

Assessing genome-wide dynamic changes in enhancer activity during early mESC differentiation by FAIRE-STARR-seq

Embryonic stem cells (ESCs) can differentiate into any given cell type and therefore represent a versatile model to study the link between gene regulation and differentiation. To quantitatively assess the dynamics of enhancer activity during the early stages of murine ESC differentiation, we analyzed accessible genomic regions using STARR-seq, a massively parallel reporter assay. This resulted in a genome-wide quantitative map of active mESC enhancers, in pluripotency and during the early stages of differentiation. We find that only a minority of accessible regions is active and that such regions are enriched near promoters, characterized by specific chromatin marks, enriched for distinct sequence motifs, and modeling shows that active regions can be predicted from sequence alone. Regions that change their activity upon retinoic acid-induced differentiation are more prevalent at distal intergenic regions when compared to constitutively active enhancers. Further, analysis of differentially active enhancers verified the contribution of individual TF motifs toward activity and inducibility as well as their role in regulating endogenous genes. Notably, the activity of retinoic acid receptor alpha (RARα) occupied regions can either increase or decrease upon the addition of its ligand, retinoic acid, with the direction of the change correlating with spacing and orientation of the RARα consensus motif and the co-occurrence of additional sequence motifs. Together, our genome-wide enhancer activity map elucidates features associated with enhancer activity levels, identifies regulatory regions disregarded by computational prediction tools, and provides a resource for future studies into regulatory elements in mESCs.     

Identification and localization of the carboxysome peptide Csos3 and its corresponding gene in Thiobacillus neapolitanus

Four genes encoding carboxysome shell peptides (csoS1A, csoS1B, csoS1C, csoS2), the genes encoding the large and small subunits of RuBisCO (cbbL, cbbS), and three unidentified ORFs constitute an operon in Thiobacillus neapolitanus. An unidentified ORF 1.54 kb in size is predicted from sequence analysis to encode a protein with a molecular mass of approximately 57 kDa. When this ORF was expressed in Escherichia coli under the control of its endogenous ribosome-binding site, no peptide product was observed. In order to correlate this ORF with a carboxysome peptide, the ORF was overexpressed in E. coli by cloning it into pProExHTb, a prokaryotic expression vector containing an E. coli ribosome binding site. When antibodies raised against the recombinant protein were used to probe an immunoblot containing carboxysome peptides, a 60-kDa peptide was recognized. The peptide was subsequently named CsoS3. CsoS3 is a minor component of the carboxysome; a peptide of this size is commonly not observed or is very faint on Coomassie blue-stained SDS-polyacrylamide gels of purified carboxysomes. Immunogold labeling established CsoS3 to be a component of the carboxysome shell.