Determination of the structure of the DNA binding domain of gamma delta resolvase in solution.

The DNA binding domain (DBD) of gamma delta resolvase (residues 141-183) is responsible for the interaction of this site-specific DNA recombinase with consensus site DNA within the gamma delta transposable element in Escherichia coli. Based on chemical-shift comparisons, the proteolytically isolated DBD displays side-chain interactions within a hydrophobic core that are highly similar to those of this domain when part of the intact enzyme (Liu T, Liu DJ, DeRose EF, Mullen GP, 1993, J Biol Chem 268:16309-16315). The structure of the DBD in solution has been determined using restraints obtained from 2-dimensional proton NMR data and is represented by 17 conformers. Experimental restraints included 458 distances based on analysis of nuclear Overhauser effect connectivities, 17 phi and chi 1 torsion angles based on analysis of couplings, and 17 backbone hydrogen bonds determined from NH exchange data. With respect to the computed average structure, these conformers display an RMS deviation of 0.67 A for the heavy backbone atoms and 1.49 A for all heavy atoms within residues 149-180. The DBD consists of 3 alpha-helices comprising residues D149-Q157, S162-T167, and R172-N183. Helix-2 and helix-3 form a backbone fold, which is similar to the canonical helix-turn-helix motif. The conformation of the NH2-terminal residues, G141-R148, appears flexible in solution. A hydrophobic core is formed by side chains donated by essentially all hydrophobic residues within the helices and turns. Helix-1 and helix-3 cross with a right-handed folding topology. The structure is consistent with a mechanism of DNA binding in which contacts are made by the hydrophilic face of helix-3 in the major groove and the amino-terminal arm in the minor groove. This structure represents an important step toward analysis of the mechanism of DNA interaction by gamma delta resolvase and provides initial structure-function comparisons among the divergent DBDs of related resolvases and invertases.     

FLP-mediated site-specific recombination in microinjected murine zygotes

The FLP recombinase of yeast catalyses site-specific recombination between repeated FLP recombinase target (FRT) elements in yeast and in heterologous system (Escherichia coli, Drosophila, mosquito and cultured mammalian cells). In this report, it is shown that transient FLP recombinase expression can recombine and activate an extrachromosomal silent reporter gene following coinjection into fertilized one-cell mouse eggs. Furthermore, it is demonstrated that introduction of a FLP-recombinase expression vector into transgenic one-cell fertilized mouse eggs induces a recombination event at a chromosomal FRT target locus. The resulting event occured at the one-cell stage and deleted a chromosomal tandem array of a FRT containinglacZ expression cassette down to one or two copies. These results demonstrate that the FLP recombinase can be utilized to manipulate the genome of transgenic animals and suggest that FLP recombinase-mediated plasmid-to-chromosome targeting is feasible in microinjected eggs.     

Generation of an Fsp1 (fibroblast‐specific protein 1)‐Flpo transgenic mouse strain

Recombination systems represent a major breakthrough in the field of genetic model engineering. The Flp recombinases (Flp, Flpe, and Flpo) bind and cleave DNA Frt sites. We created a transgenic mouse strain ([Fsp1‐Flpo]) expressing the Flpo recombinase in fibroblasts. This strain was obtained by random insertion inside mouse zygotes after pronuclear injection. Flpo expression was placed under the control of the promoter of Fsp1 (fibroblast‐specific protein 1) gene, whose expression starts after gastrulation at Day 8.5 in cells of mesenchymal origin. We verified the correct expression and function of the Flpo enzyme by several ex vivo and in vivo approaches. The [Fsp1‐Flpo] strain represents a genuine tool to further target the recombination of transgenes with Frt sites specifically in cells of mesenchymal origin or with a fibroblastic phenotype.     

Mouse Sertoli cells isolation by lineage tracing and sorting

Sertoli cells play a key role in spermatogenesis by supporting the germ cells throughout differentiation. The isolation of Sertoli cells is essential to study their functions. However, the close contact of Sertoli cells with other testicular cell types and the high proliferation of contaminating cells are obstacles to obtain pure primary cultures. Current rodent Sertoli cell isolation protocols result in enriched, rather than pure Sertoli cells. Therefore, novel approaches are necessary to improve the purity of Sertoli cell primary cultures. The goal of this study is to obtain pure mouse Sertoli cells using lineage tracing and fluorescence‐activated cell sorting (FACS). We bred the Amh‐Cre mouse line with tdTomato line to generate mice constitutively expressing red fluorescence specifically in Sertoli cells. Primary cultures of Sertoli cells isolated from prepubertal mice showed that 79% of cells expressed tdTomato, as evaluated by fluorescence microscopy and flow cytometry; however, nearly all adherent cells were positive for vimentin. Most of the tomato‐negative cells expressed α‐smooth muscle actin (α‐SMA), a peritubular myoid cell marker, but double‐negative populations were also present. These findings suggest that vimentin lacks Sertoli cell‐specificity and that α‐SMA is not adequate to identify all of the contaminating cells. Upon FACS sorting; however, virtually 100% of the cells were tdTomato positive, expressed vimentin, but not α‐SMA. Prepubertal mice yielded a higher number of Sertoli cells compared to adults, but both could be adequately sorted. In conclusion, our study shows that lineage tracing and sorting is an efficient strategy for acquiring pure populations of murine Sertoli cells.     

Non‐parallel recombination limits cre‐loxP‐based reporters as precise indicators of conditional genetic manipulation

Cre/LoxP‐mediated recombination allows for conditional gene activation or inactivation. When combined with an independent lineage‐tracing reporter allele, this technique traces the lineage of presumptive genetically modified Cre‐expressing cells. Several studies have suggested that floxed alleles have differential sensitivities to Cre‐mediated recombination, which raises concerns regarding utilization of Cre‐reporters to monitor recombination of other floxed loci of interest. Here, we directly investigate the recombination correlation, at cellular resolution, between several floxed alleles induced by Cre‐expressing mouse lines. The recombination correlation between different reporter alleles varied greatly in otherwise genetically identical cell types. The chromosomal location of floxed alleles, distance between LoxP sites, sequences flanking the LoxP sites, and the level of Cre activity per cell all likely contribute to observed variations in recombination correlation. These findings directly demonstrate that, due to non‐parallel recombination events, commonly available Cre reporter mice cannot be reliably utilized, in all cases, to trace cells that have DNA recombination in independent‐target floxed alleles, and that careful validation of recombination correlations are required for proper interpretation of studies designed to trace the lineage of genetically modified populations, especially in mosaic situations. genesis 51:436–442. © 2013 Wiley Periodicals, Inc.     

Mx1‐Cre mediated Rgs12 conditional knockout mice exhibit increased bone mass phenotype

Regulators of G‐protein Signaling (Rgs) proteins are the members of a multigene family of GTPase‐accelerating proteins (GAP) for the Galpha subunit of heterotrimeric G‐proteins. Rgs proteins play critical roles in the regulation of G protein couple receptor (GPCR) signaling in normal physiology and human diseases such as cancer, heart diseases, and inflammation. Rgs12 is the largest protein of the Rgs protein family. Some in vitro studies have demonstrated that Rgs12 plays a critical role in regulating cell differentiation and migration; however its function and mechanism in vivo is largely unknown. Here, we generated a floxed Rgs12 allele (Rgs12^flox/flox) in which the exon 2, containing both PDZ and PTB_PID domains of Rgs12, was flanked with two loxp sites. By using the inducible Mx1‐cre and Poly I:C system to specifically delete Rgs12 at postnatal 10 days in interferon‐responsive cells including monocyte and macrophage cells, we found that Rgs12 mutant mice had growth retardation with the phenotype of increased bone mass. We further found that deletion of Rgs12 reduced osteoclast numbers and had no significant effect on osteoblast formation. Thus, Rgs12^flox/flox conditional mice provide a valuable tool for in vivo analysis of Rgs12 function and mechanism through time‐ and cell‐specific deletion of Rgs12. genesis 51:201–209, 2013. © 2013 Wiley Periodicals, Inc.