Successful fishing for nucleus pulposus progenitor cells of the intervertebral disc across species.

BACKGROUND: Recently, Tie2/TEK receptor tyrosine kinase (Tie2 or syn. angiopoietin-1 receptor) positive nucleus pulposus progenitor cells were detected in human, cattle, and mouse. These cells show remarkable multilineage differentiation capacity and direct correlation with intervertebral disc (IVD) degeneration and are therefore an interesting target for regenerative strategies. Nevertheless, there remains controversy over the presence and function of these Tie2+ nucleus pulposus cells (NPCs), in part due to the difficulty of identification and isolation. PURPOSE: Here, we present a comprehensive protocol for sorting of Tie2+ NPCs from human, canine, bovine, and murine IVD tissue. We describe enhanced conditions for expansion and an optimized fluorescence-activated cell sorting-based methodology to sort and analyze Tie2+ NPCs. METHODS: We present flow cytometry protocols to isolate the Tie2+ cell population for the aforementioned species. Moreover, we describe crucial pitfalls to prevent loss of Tie2+ NPCs from the IVD cell population during the isolation process. A cross-species phylogenetic analysis of Tie2 across species is presented. RESULTS: Our protocols are efficient towards labeling and isolation of Tie2+ NPCs. The total flow cytometry procedure requires approximately 9 hours, cell isolation 4 to 16 hours, cell expansion can take up to multiple weeks, dependent on the application, age, disease state, and species. Phylogenetic analysis of the TEK gene revealed a strong homology among species. CONCLUSIONS: Current identification of Tie2+ cells could be confirmed in bovine, canine, mouse, and human specimens. The presented flow cytometry protocol can successfully sort these multipotent cells. The biological function of isolated cells based on Tie2+ expression needs to be confirmed by functional assays such as in vitro differentiation. in vitro culture conditions to maintain and their possible proliferation of the Tie2+ fraction is the subject of future research.

The First Scube3 Mutant Mouse Line with Pleiotropic Phenotypic Alterations.

The vertebrate Scube (Signal peptide, CUB, and EGF-like domain-containing protein) family consists of three independent members, Scube1-3, which encode secreted cell surface-associated membrane glycoproteins. Limited information about the general function of this gene family is available, and their roles during adulthood. Here, we present the first Scube3 mutant mouse line (Scube3N294K/N294K), which clearly shows phenotypic alterations by carrying a missense mutation in exon 8, and thus contributes to our understanding of SCUBE3 functions. We performed a detailed phenotypic characterization in the German Mouse Clinic (GMC). Scube3N294K/N294K mutants showed morphological abnormalities of the skeleton, alterations of parameters relevant for bone metabolism, changes in renal function, and hearing impairments. These findings correlate with characteristics of the rare metabolic bone disorder Paget disease of bone (PDB), associated with the chromosomal region of human SCUBE3 In addition, alterations in energy metabolism, behavior, and neurological functions were detected in Scube3N294K/N294K mice. The Scube3N294K/N294K mutant mouse line may serve as a new model for further studying the effect of impaired SCUBE3 gene function.

Conditional knockout of Foxc2 gene in kidney: efficient generation of conditional alleles of single-exon gene by double-selection system.

Foxc2 is a single-exon gene and a key regulator in development of multiple organs, including kidney. To avoid embryonic lethality of conventional Foxc2 knockout mice, we conditionally deleted Foxc2 in kidneys. Conditional targeting of a single-exon gene involves the large floxed gene segment spanning from promoter region to coding region to avoid functional disruption of the gene by the insertion of a loxP site. Therefore, in ES cell clones surviving a conventional single-selection, e.g., neomycin-resistant gene (neo) alone, homologous recombination between the long floxed segment and target genome results in a high incidence of having only one loxP site adjacent to the selection marker. To avoid this limitation, we employed a double-selection system. We generated a Foxc2 targeting construct in which a floxed segment contained 4.6 kb mouse genome and two different selection marker genes, zeocin-resistant gene and neo, that were placed adjacent to each loxP site. After double-selection by zeocin and neomycin, 72 surviving clones were screened that yielded three correctly targeted clones. After floxed Foxc2 mice were generated by tetraploid complementation, we removed the two selection marker genes by a simultaneous-single microinjection of expression vectors for Dre and Flp recombinases into in vitro-fertilized eggs. To delete Foxc2 in mouse kidneys, floxed Foxc2 mice were mated with Pax2-Cre mice. Newborn Pax2-Cre; Foxc2(loxP/loxP) mice showed kidney hypoplasia and glomerular cysts. These results indicate the feasibility of generating floxed Foxc2 mice by double-selection system and simultaneous removal of selection markers with a single microinjection.