The apoptosis mediator mDAP-3 is a novel member of a conserved family of mitochondrial proteins.

Programmed cell death is essential for organ development and regeneration. To identify molecules relevant for this process, full length cDNA cloning of a short, developmentally regulated murine cDNA fragment, MERM-3, was performed and showed a 1.7 kb mRNA encoding a 45 kDa protein with an ATP/GTP binding motive (P-loop). Sequence analysis revealed an 82% amino acid identity to the human death associated protein 3 (hDAP-3), a positive mediator of apoptosis. The full length sequence being the murine orthologue of hDAP-3 is therefore referred to as mDAP-3. In situ hybridization and northern blot analysis showed an abundant mRNA expression with a pronounced expression in highly proliferative epithelial compartments. For mDAP-3, cytochrome c release and induction of cell death could be demonstrated by overexpression of a mDAP-3/EGFP fusion protein. DAP-3 mediated apoptosis was shown to depend on a functional P-loop. Intracellular localization studies using the mDAP-3/EGFP fusion protein, cell fractionation and protease protection experiments localized mDAP-3 to the mitochondrial matrix. DAP-3, in contrast to cytochrome c, retained its mitochondrial localization during apoptosis induction. A mutant of a putative yeast orthologue of mDAP-3, YGL129c, here referred to as yDAP-3, has been shown to exhibit disrupted mitochondrial function. yDAP-3 deficient mutants could be shown to progressively loose mitochondrial DNA. Loss of mitochondrial DNA in yDAP-3 was partially prevented by transfection of the yDAP-3 deficient mutant with mDAP-3, indicating functional complementation by murine DAP-3 in the yeast system. These data identify mDAP-3 as one of the first proapoptotic factors in the mitochondrial matrix and provide evidence for a critical, evolutionary conserved role of members of the DAP-3 protein family for mitochondrial biogenesis.

Chemokine and chemokine receptor expression in a novel human mesangial cell line.

Chemokines are thought to play a pivotal role in mediating the selective migration of leukocytes into sites of tissue injury. The local production of chemokines by mesangial cells (MC) has been linked to inflammatory processes within the glomerulus. To study the chemokine biology of human MC, an immortalized human MC line was generated and then chemokine and chemokine receptor expression was examined in response to various proinflammatory stimuli. The results show that human MC have a specific and limited repertoire of chemokine expression. The stimulus-specific regulation of the chemokines monocyte chemoattractant protein- (MCP- 1), regulated upon activation, normal T cell expressed and secreted (RANTES), interleukin-8 (IL-8), and IP-10 was demonstrated using RNase protection assays. Transcripts for the chemokines MIP-1alpha, MIP-1beta, I-309, or lymphotactin could not be detected. The expression of CC chemokine receptors was investigated by reverse transcription-PCR and RNase protection assays. MC stimulated with interferon-gamma (IFN-gamma) expressed mRNA for the chemokine receptor CCR1. The expression could be further increased by activating the cells with a combination of tumor necrosis factor-a (TNF-alpha), IL-1beta, and IFN-gamma. Under these conditions, no mRNA for CCR2, CCR3, CCR4, CCR5, or CCR8 was detected. A comparison of the immortalized human mesangial cells with primary cells showed identical expression patterns of chemokine receptors. To demonstrate functional activity of chemokine receptors expressed by human MC, chemotaxis assays were performed. MC stimulated with a combination of TNF-alpha, IL-1beta, and IFN-gamma, but not unstimulated MC, migrated toward a RANTES gradient. Eotaxin did not enhance the migratory activity of human MC. In summary, a novel human mesangial cell line was established and the pattern of chemokine expression was examined. For the first time, the inducible expression of functionally active CCR1 by human MC was shown.