Chonghui Zhang

Monitoring early cellular responses in apoptosis is aided by the mitochondrial membrane protein‐specific monoclonal antibody APO2.7

A recently described mitochondrial membrane protein-specific monoclonal antibody, APO2.7, was examined for monitoring early apoptotic responses in anti-CD95 (7C11)-induced Jurkat cells. Jurkat cells were harvested at 1.5, 3, 4.5, 6, 12, and 18 h after induction of apoptosis, and APO2.7 antibody monitored in unprocessed (no permeabilization agent used prior to staining) and processed (permeabilized prior to staining) cells. Light-scatter changes (decreased forward-scatter and increased side-scatter) by flow cytometry were observed after 3 h, and detection of cell permeability in unprocessed cells, as measured by light microscopic examination of Trypan blue-stained cells and flow cytometric detection of tubulin, showed little change until after 6 h. In addition, unprocessed cells stained with APO2.7 antibody showed little increase in staining until after 6 h following induction of apoptosis, when DNA fragmentation was demonstrated by flow cytometry and gel electrophoresis; however, processed cells stained with APO2.7 antibody showed significant increase in staining after 1.5 h. Detection, using annexin V and flow cytometry, of phospholipid membrane asymmetry from exposure of phosphatidylserine showed greater, apparent nonspecific staining in noninduced cells as compared to the other markers of apoptosis, but nearly paralleled the results of APO2.7 staining in processed cells from 3-18 h following CD95 induction of apoptosis. The data presented herein indicate that the mitochondrial membrane protein-specific antibody, APO2.7, is useful as a marker for the detection of apoptotic cells.

Functional interaction of DFF35 and DFF45 with caspase-activated DNA fragmentation nuclease DFF40.

DNA fragmentation factor (DFF) functions downstream of caspase-3 and directly triggers DNA fragmentation during apoptosis. Here we described the identification and characterization of DFF35, an isoform of DFF45 comprised of 268 amino acids. Functional assays have shown that only DFF45, not DFF35, can assist in the synthesis of highly active DFF40. Using the deletion mutants, we mapped the function domains of DFF35/45 and demonstrated that the intact structure/conformation of DFF45 is essential for it to function as a chaperone and assist in the synthesis of active DFF40. Whereas the amino acid residues 101–180 of DFF35/45 mediate its binding to DFF40, the amino acid residues 23–100, which is homologous between DFF35/45 and DFF40, may function to inhibit the activity of DFF40. In contrast to DFF45, DFF35 cannot work as a chaperone, but it can bind to DFF40 more strongly than DFF45 and can inhibit its nuclease activity. These findings suggest that DFF35 may function in vivo as an important alternative mechanism to inhibit the activity of DFF40 and further, that the inhibitory effects of both DFF35 and DFF45 on DFF40 can put the death machinery under strict control.

Molecular cloning of Porimin, a novel cell surface receptor mediating oncotic cell death

Anti-Porimin (Pro-oncosis receptor inducing membrane injury) mAb mediates oncosis-like cell death in Jurkat cells. Porimin cDNA was isolated from a Jurkat cell cDNA library by COS cell-expression cloning. The 3,337-bp cDNA has an ORF of 567 bp, encoding a type I transmembrane protein of 189 amino acids. The extracellular domain of Porimin contains many O-linked and seven N-linked glycosylation sites that define it as a new member of the mucin family. COS7 and 293 cells transiently transfected with Porimin cDNA were specifically recognized by anti-Porimin Ab in cell staining and immunoblotting experiments. When expressed in Jurkat cells, a His-tagged Porimin cDNA construct resulted in the generation of a specific 110-kDa-size protein that matched the molecular mass of the endogenous Porimin protein. Crosslinking of the Porimin receptor expressed on COS7 transfectants resulted in the loss of cell membrane integrity and cell death as measured by the leakage of intracellular lactate dehydrogenase. Both COS7 and 293 cells expressing transfected Porimin at a relatively high level lost their ability to adhere to culture dishes, suggesting a role for Porimin in cell adhesion. The Porimin gene was mapped to human chromosome 11q22.1 and is composed of four exons spanning 133 kb of genomic DNA.

APO2.7 defines a shared apoptotic–necrotic pathway in a breast tumor hypoxia model†

A breast tumor hypoxia model used to simulate conditions which may exist within an enlarging tumor was examined using documented methods for identifying mechanisms of cell death and compared to the mitochondrial membrane-specific APO2.7 antigen expression. Hypoxic conditions were induced by holding cell pellets of MDA-MB-175-VII breast carcinoma cells in tightly capped centrifuge tubes for up to 10 days. Cells were harvested at 1.5, 3, 4.5, 6, 12, 18, and 24 h, and each 24 h thereafter to 10 days. APO2.7 was monitored in unprocessed cells (no permeabilization prior to staining) for all time points and processed cells (permeabilized prior to staining) for only the first 24 h. Cell viability probes trypan blue and anti-tubulin antibody showed a rapid increase in staining over the first 24 h, as did the phosphatidylserine-specific annexin V and DNA fragmentation by flow cytometry (range of 60-81% positive staining). Light scatter changes indicative of cell death were also quite remarkable. APO2.7 staining never exceeded 42% of the cell pellet over the 10 days of testing compared to greater than 95% staining for all other methods tested. When APO2.7 antigen expression was examined with respect to depth in the cell pellet, it was apparent that cells deeper in the pellet expressed APO2.7 more rapidly; however, fewer cells stained and cells showed fewer apoptotic features on an ultrastructural level than cells at the cell media interface. The study indicates that the anti-APO2.7 antibody may be able to discern apoptotic and incomplete apoptotic cells from necrotic MDA-MB breast cancer cells, traversing a heterogeneous pathway to cell death induced by hypoxia.