Jijie Gu

Impaired apoptosis, extended duration of immune responses, and a lupus-like autoimmune disease in IEX-1-transgenic mice

Susceptibility of activated T cells to apoptosis must be tightly regulated to ensure sufficient T cell progeny for an effective response, while allowing a rapid depletion of them at the end of the immune response. We show here that a previously isolated, NF-κB/rel target gene IEX-1 (Immediate Early response gene X-1) is highly expressed in T cells at early stages of activation, but declines with a prolonged period of activation time, coincident with an increased susceptibility of T cells to apoptosis during the late phases of an immune response. Transgenic expression of IEX-1 specifically in lymphocytes impaired apoptosis in activated T cells, extended a duration of an effector-phase of a specific immune response, and increased the accumulation of effector/memory-like T cells and the susceptibility to a lupus-like autoimmune disease. Our study demonstrated an antiapoptotic effect of IEX-1 on T cell apoptosis triggered by ligation of Fas and T cell receptor (TCR)/CD3 complex. The ability of extending life expectancy of T effectors, in line with a decrease in its expression following prolonged T cell activation, suggests a key role for IEX-1 in regulating T cell homeostasis during immune responses.

Identification of p53 sequence elements that are required for MDM2-mediated nuclear export.

ABSTRACT It has been demonstrated that MDM2 can differentially regulate subcellular distribution of p53 and its close structural homologue p73. In contrast to MDM2-mediated p53 nuclear export, p73 accumulates in the nucleus as aggregates that colocalize with MDM2. Distinct distribution patterns of p53 and p73 suggest the existence of unique structural elements in the two homologues that determine their MDM2-mediated relocalization in the cell. Using a series of p53/p73 chimeric proteins, we demonstrate that three regions of p53 are involved in the regulation of MDM2-mediated nuclear export. The DNA binding domain (DBD) is involved in the maintenance of a proper conformation that is required for functional activity of the nuclear export sequence (NES) of p53. The extreme C terminus of p53 harbors several lysine residues whose ubiquitination by MDM2 appears to be the initial event in p53 nuclear export, as evidenced by the impaired nucleocytoplasmic shuttling of p53 mutants bearing simultaneous substitutions of lysines 370, 372, 373, 381, 382, and 386 to arginines (6KR) or alanines (6KA). Finally, the region between the DBD and the oligomerization domain of p53, specifically lysine 305, also plays a critical role in fully revealing p53NES. We conclude that MDM2-mediated nuclear export of p53 depends on a series of ubiquitination-induced conformational changes in the p53 molecule that lead to the activation of p53NES. In addition, we demonstrate that the p53NES may be activated without necessarily disrupting the p53 tetramer.

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.

Identification of a Sequence Element from p53 That Signals for Mdm2-Targeted Degradation

ABSTRACT The binding of Mdm2 to p53 is required for targeting p53 for degradation. p73, however, binds to Mdm2 but is refractory to Mdm2-mediated degradation, indicating that binding to Mdm2 is not sufficient for degradation. By utilizing the structural homology between p53 and p73, we generated p53-p73 chimeras to determine the sequence element unique to p53 essential for regulation of its stability. We found that replacing an element consisting of amino acids 92 to 112 of p53 with the corresponding region of p73 results in a protein that is not degradable by Mdm2. Removal of amino acids 92 to 112 of p53 by deletion also results in a non-Mdm2-degradable protein. Significantly, the finding that swapping this fragment converts p73 from refractory to sensitive to Mdm2-mediated degradation supports the conclusion that the amino acids 92 to 112 of p53 function as a degradation signal. We propose that the presence of an additional protein recognizes the degradation signal and coordinates with Mdm2 to target p53 for degradation. Our finding opens the possibility of searching for the additional protein, which most likely plays a critical role in the regulation of p53 stability and therefore function.

Molecular Basis of p53 Functional Inactivation by the Leukemic Protein MLL-ELL

ABSTRACT The Eleven Lysine-rich Leukemia (ELL) gene undergoes translocation and fuses in frame to the Multiple Lineage Leukemia (MLL) gene in a substantial proportion of patients suffering from acute forms of leukemia. Molecular mechanisms of cellular transformation by the MLL-ELL fusion are not well understood. Although both MLL-ELL and wild-type ELL can reduce functional activity of p53 tumor suppressor, our data reveal that MLL-ELL is a much more efficient inhibitor of p53 than is wild-type ELL. We also demonstrate for the first time that ELL extreme C terminus [ELL(eCT)] is required for the recruitment of p53 into MLL-ELL nuclear foci and is both necessary and sufficient for the MLL-ELL inhibition of p53-mediated induction of p21 and apoptosis. Finally, our results demonstrate that MLL-ELL requires the presence of intact ELL(eCT) in order to disrupt p53 interactions with p300/CBP coactivator and thus significantly reduce p53 acetylation in vivo. Since ELL(eCT) has recently been shown to be both necessary and sufficient for MLL-ELL-mediated transformation of normal blood progenitors, our data correlate ELL(eCT) contribution to MLL-ELL transformative effects with its ability to functionally inhibit p53.

A sequence element of p53 that determines its susceptibility to viral oncoprotein-targeted degradation.

The molecular basis that the viral oncoproteins, including HPV16 E6 and E1B55k/E4 34k complex, differentially target p53 but not its homolog p73 for degradation remains elusive. Using a series of p53/p73 chimeras, we demonstrated that despite binding to the different regions of p53, both HPV16 E6 and E1B55k/E4 34k required a very same p53 sequence, amino acid residues 92 to 112 [p53(aa.92–112)], previously identified as a necessity for Mdm2-mediated degradation, to target p53 for degradation. Removal of the p53(aa.92–112) by either substitution or deletion resulted in a p53 protein that was no longer degradable by the viral proteins. More significantly, swapping the oncoprotein-binding motif and the p53(aa.92–112) rendered p73 susceptible to oncoprotein-mediated degradation. Collectively, our data supports a model in which the p53(aa.92–112) functions as a determinant for p53 stability while the binding of the oncoproteins directs p53 into the specific pathway for proteolysis.