DNA-damage response control of E2F7 and E2F8

Here, we report that the two recently identified E2F subunits, E2F7 and E2F8, are induced in cells treated with DNA-damaging agents where they have an important role in dictating the outcome of the DNA-damage response. The DNA-damage-dependent induction coincides with the binding of E2F7 and E2F8 to the promoters of certain E2F-responsive genes, most notably that of the E2F1 gene, in which E2F7 and E2F8 coexist in a DNA-binding complex. As a consequence, E2F7 and E2F8 repress E2F target genes, such as E2F1, and reducing the level of each subunit results in an increase in E2F1 expression and activity. Importantly, depletion of either E2F7 or E2F8 prevents the cell-cycle effects that occur in response to DNA damage. Thus, E2F7 and E2F8 act upstream of E2F1, and influence the ability of cells to undergo a DNA-damage response. E2F7 and E2F8, therefore, underpin the DNA-damage response.     

Interface characterization of the type II module pair from fibronectin

The lone (1)F2(2)F2 modular pair of fibronectin is found in the collagen-binding region. This exclusive localization suggests the (1)F2(2)F2 pair plays an important role in the recognition of collagen. However, no information is currently available about the interaction between the two F2 modules and, thus, the orientation of their putative collagen-binding sites with respect to one another. Comparison of a variety of high-resolution NMR parameters from the F2 modules in isolation and the (1)F2(2)F2 pair was used to establish the extent of interaction between the F2 modules in the pair. Chemical shifts of the F2 modules and the (1)F2(2)F2 pair indicate that the structures of the modules are preserved in the pair and that, with the exception of the covalent linkage, they do not interact. (15)N NMR relaxation data identify significant motion occurring in the linker region of the (1)F2(2)F2 pair, and analyses of the anisotropic diffusion properties of the (1)F2(2)F2 pair are consistent with the modules in the F2 pair tumbling independent of one another.     

The hairpin structure of the (6)F1(1)F2(2)F2 fragment from human fibronectin enhances gelatin binding

The solution structure of the (6)F1(1)F2(2)F2 fragment from the gelatin-binding region of fibronectin has been determined (Protein Data Bank entry codes 1e88 and 1e8b). The structure reveals an extensive hydrophobic interface between the non-contiguous (6)F1 and (2)F2 modules. The buried surface area between (6)F1 and (2)F2 ( approximately 870 A(2)) is the largest intermodule interface seen in fibronectin to date. The dissection of (6)F1(1)F2(2)F2 into the (6)F1(1)F2 pair and (2)F2 results in near-complete loss of gelatin-binding activity. The hairpin topology of (6)F1(1)F2(2)F2 may facilitate intramolecular contact between the matrix assembly regions flanking the gelatin-binding domain. This is the first high-resolution study to reveal a compact, globular arrangement of modules in fibronectin. This arrangement is not consistent with the view that fibronectin is simply a linear 'string of beads'.     

E2F1 and E2F2 Determine Thresholds for Antigen-Induced T-Cell Proliferation and Suppress Tumorigenesis

E2F activity is critical for the control of the G(1) to S phase transition. We show that the combined loss of E2F1 and E2F2 results in profound effects on hematopoietic cell proliferation and differentiation, as well as increased tumorigenesis and decreased lymphocyte tolerance. The loss of E2F1 and E2F2 impedes B-cell differentiation, and hematopoietic progenitor cells in the bone marrow of mice lacking E2F1 and E2F2 exhibit increased cell cycling. Importantly, we show that E2F1 and E2F2 double-knockout T cells exhibit more rapid entry into S phase following antigenic stimulation. Furthermore, T cells lacking E2F1 and E2F2 proliferate much more extensively in response to subthreshold antigenic stimulation. Consistent with these observations, E2F1/E2F2 mutant mice are highly predisposed to the development of tumors, and some mice exhibit signs of autoimmunity.     

Specificity of acidic phospholipids (CL & PA) in the activation of mitochondrial F0F1 ATPase by Mg2+

The interaction of Mg2+ with native F0F1 ATPase was studied. The hydrolytic activity of F0F1 ATPase could be competitively activated by Mg2+, but the preincubation of F0F1 ATPase with cholate eliminated the Mg2+ effect. The result from the comparison of the effect of Mg2+ on F0F1 ATPase with that on soluble F1 ATPase, and the fact that the activation of Mg2+ on cholate-treated F0F1 ATPase could be reconstituted only by divalent acidic phospholipid cardiolipin, indicate that there exists a specificity between the acidic phospholipids of the mitochondrial inner membrane and Mg2+ enhancement of ATP-hydrolyzing activity of F0F1 ATPase.     

Methylation-mediated regulation of E2F1 in DNA damage-induced cell death

E2F1 promotes DNA damage-induced apoptosis and the post-translational modifications of E2F1 play an important role in the regulation of E2F1-mediated cell death. Here, we found that Set9 and LSD1 regulate E2F1-mediated apoptosis upon DNA damage. Set9 methylates E2F1 at lysine 185, a conserved residue in the DNA-binding domain of E2F family proteins. The methylation of E2F1 by Set9 leads to the stabilization of E2F1 and up-regulation of its proapoptotic target genes p73 and Bim, and thereby induces E2F1-mediated apoptosis in response to genotoxic agents. We also found that LSD1 demethylates E2F1 at lysine 185 and reduces E2F1-mediated cell death. The identification of the methylation/demethylation of E2F1 by Set9/LSD1 suggests that E2F1 is dynamically regulated by epigenetic enzymes in response to DNA damage.     

The relationship between histones F 2al and F 2a2 and the ancestral histone A peptide. Further evidence for the common origin of histones F 2al, F 2a2 and F 3.

The relationship between histones F 2al and F 2a2 becomes much more apparent if the alignment is not made between the total sequences but between the ancestral A peptide, reconstructed earlier for histone F 2al (IV) and F 2a2. 46.5% of the latter's sequence can thus be clearly connected with F 2al through this ancestral dodecapeptide. A parallel development of histones F 2al, F 2a2 and F 3 from the A peptide is proposed.     

Expression of prothrombin and protease activated receptors in human myometrium during pregnancy and labor

As thrombin is proposed to be involved in stimulating myometrial contractility during labor and preterm labor, we aimed to investigate the expression of prothrombin (F7), the precursor of thrombin, its receptors, the protease-activated receptor (PAR) family (F2R, F2RL1, F2RL2, and F2RL3), and prothrombinase FGL2 in human myometrium during pregnancy and labor. Messenger RNA and protein were isolated from human pregnant laboring and nonlaboring myometrial tissue and from human primary myometrial smooth muscle cells. Semiquantitative RT-PCR, real-time fluorescence RT-PCR, Western blotting, and fluorescence microscopy were performed to determine the expression levels of F7, FGL2, F2R, F2RL1, F2RL2, and F2RL3 in the myometrial tissues and cells. The expression of mRNA and protein for these molecules is reported for the first time in human myometrium at term pregnancy, at labor, and in the nonpregnant state. Importantly, an increase in F2R and a significant increase in F2RL3 mRNA expression at labor were demonstrated. Statistically significant increases in F2R and F2RL3 protein expression was also detected in human myometrium at labor. Furthermore, FGL2 mRNA expression at labor, and FGL2 protein expression at term pregnancy and at labor was observed in this tissue for the first time. The expression of F7, FGL2, F2R, F2RL1, F2RL2, and F2RL3 in human myometrium reveals that all the machinery necessary for thrombin activation and cellular activity is present in the myometrium during pregnancy and labor. These data, in conjunction with the demonstrated increase in F2R and F2RL3 expression at labor, suggest a principal role for these molecules in the regulation of myometrial function at labor, including preterm labor.