p21 Exploits Residue Tyr151 as a Tether for High-Affinity PCNA Binding.

Proliferating cell nuclear antigen (PCNA, processivity factor, sliding clamp) is a ring-shaped protein that tethers proteins to DNA in processes, including DNA replication, DNA repair, and cell-cycle control. Often used as a marker for cell proliferation, PCNA is overexpressed in cancer cells, making it an appealing pharmaceutical target. PCNA interacts with proteins through a PCNA interacting protein (PIP)-box, an eight-amino acid consensus sequence; different binding partners display a wide range of affinities based on function. Of all biological PIP-boxes, p21 has the highest known affinity for PCNA, allowing for inhibition of DNA replication and cell growth under cellular stress. As p21 is one of the few PIP-box sequences to contain a tyrosine rather than a phenylalanine in the eighth conserved position, we probed the significance of the hydroxyl group at this position using a mutational approach. Here we present the cocrystal structure of PCNA bound to a mutant p21 PIP-box peptide, p21Tyr151Phe, with associated isothermal titration calorimetry data. The p21Tyr151Phe peptide showed a 3-fold difference in affinity, as well as differences in entropy and enthalpy of binding. These differences can be attributed to a loss of hydrogen bonding capacity, as well as structural plasticity in the PCNA interdomain connector loop and the hydrophobic cavity of PCNA to which p21 binds. Thus, the hydroxyl group of Tyr151 in p21 acts as a tethering point for ideal packing and surface recognition of the peptide interface, increasing the binding affinity of p21 for PCNA.

Structure of the sliding clamp from the fungal pathogen Aspergillus fumigatus (AfumPCNA) and interactions with Human p21.

The fungal pathogen Aspergillus fumigatus has been implicated in a drastic increase in life-threatening infections over the past decade. However, compared to other microbial pathogens, little is known about the essential molecular processes of this organism. One such fundamental process is DNA replication. The protein responsible for ensuring processive DNA replication is PCNA (proliferating cell nuclear antigen, also known as the sliding clamp), which clamps the replicative polymerase to DNA. Here we present the first crystal structure of a sliding clamp from a pathogenic fungus (A. fumigatus), at 2.6Å. Surprisingly, the structure bears more similarity to the human sliding clamp than other available fungal sliding clamps. Reflecting this, fluorescence polarization experiments demonstrated that AfumPCNA interacts with the PCNA-interacting protein (PIP-box) motif of human p21 with an affinity (Kd ) of 3.1 µm. Molecular dynamics simulations were carried out to better understand how AfumPCNA interacts with human p21. These simulations revealed that the PIP-box bound to AfuPCNA forms a secondary structure similar to that observed in the human complex, with a central 310 helix contacting the hydrophobic surface pocket of AfumPCNA as well as a ß-strand that forms an antiparallel sheet with the AfumPCNA surface. Differences in the 310 helix interaction with PCNA, attributed to residue Thr131 of AfumPCNA, and a less stable ß-strand formation, attributed to residues Gln123 and His125 of AfumPCNA, are likely causes of the over 10-fold lower affinity of the p21 PIP-box for AfumPCNA as compared to hPCNA. DATABASE: The atomic coordinates and structure factors for the Aspergillus fumigatus sliding clamp can be found in the RCSB Protein Data Bank (http://www.rcsb.org) under the accession code 5TUP.

Review of the Structural and Dynamic Mechanisms of PPARγ Partial Agonism.

PPARγ (peroxisome proliferator activated receptor γ) is a ligand activated transcription factor of the nuclear receptor superfamily that controls the expression of a variety of genes involved in fatty acid metabolism, adipogenesis, and insulin sensitivity. While endogenous ligands of PPARγ include fatty acids and eicosanoids, synthetic full agonists of the receptor, including members of the thiazolidinedione (TZD) class, have been widely prescribed for the treatment of type II diabetes mellitus (T2DM). Unfortunately, the use of full agonists has been hampered by harsh side effects with some removed from the market in many countries. In contrast, partial agonists of PPARγ have been shown to retain favourable insulin sensitizing effects while exhibiting little to no side effects and thus represent a new potential class of therapeutics for the treatment of T2DM. Partial agonists have been found to not only display differences in transcriptional and cellular outcomes, but also act through distinct structural and dynamic mechanisms within the ligand binding cavity compared to full agonists.