GAL4 enhancer traps that can be used to drive gene expression in developing Drosophila spermatocytes

The Drosophila testis has proven to be a valuable model organ for investigation of germline stem cell (GSC) maintenance and differentiation as well as elucidation of the genetic programs that regulate differentiation of daughter spermatogonia. Development of germ cell specific GAL4 driver transgenes has facilitated investigation of gene function in GSCs and spermatogonia but specific GAL4 tools are not available for analysis of postmitotic spermatogonial differentiation into spermatocytes. We have screened publically available pGT1 strains, a GAL4‐encoding gene trap collection, to identify lines that can drive gene expression in late spermatogonia and early spermatocytes. While we were unable to identify any germline‐specific drivers, we did identify an insertion in the chiffon locus, which drove expression specifically in early spermatocytes within the germline along with the somatic cyst cells of the testis. genesis 50:914–920, 2012. © 2012 Wiley Periodicals, Inc.     

Possible role of histone H1 in the regulation of furin-dependent proprotein processing

Histone H1 and its C-terminal lysine rich fragments were recently found to be potent inhibitorsof furin,a mammalian proprotein convertase.However,its role in the regulation of furin-dependent proproteinprocessing remains unclear.Here we report that histone H1 efficiently blocks furin-dependent pro-yonWillebrand factor(pro-vWF)processing in a dose-dependent manner.Coimmunoprecipitation and immunof-luorescence studies confirmed that histone H1 could interact with furin,and the interaction mainly took placeon the cell surface.We noted that histone H1 was released from cells undergoing necrosis and apoptosisinduced by H_2O_2.Our findings suggested that histone H1 might be involved in extracellular and/or intracellu-lar furin regulation.     

A K52Q substitution in the globular domain of histone H1t modulates its nucleosome binding properties

A comparison of the globular domain sequences of the somatic H1d and testis-specific H1t revealed a single substitution of lysine 52 in H1d to glutamine 54 in H1t, which is one of the three crucial residues within the second DNA binding site. The globular domains of both histones were modeled using the crystal structure of chicken GH5 as a template and was also docked onto the nucleosome structure. The glutamine residue in histone H1t forms a hydrogen bond with main chain carbonyl of methionine-52 (in H1t) and is spatially oriented away from the nucleosome dyad axis. A consequence of this change was a lower affinity of recombinant histone H1t towards Four-way junction DNA and reconstituted 5S mononucleosomes. When Gln-54 in Histone H1t was mutated to lysine, its binding affinity towards DNA substrates was comparable to that of histone H1d. The differential binding of histones H1d and H1t towards reconstituted mononucleosomes was also reflected in the chromatosome-stop assay.