Inhibition of N-Methyl-D-aspartate-induced Retinal Neuronal Death by Polyarginine Peptides Is Linked to the Attenuation of Stress-induced Hyperpolarization of the Inner Mitochondrial Membrane Potential.

It is widely accepted that overactivation of NMDA receptors, resulting in calcium overload and consequent mitochondrial dysfunction in retinal ganglion neurons, plays a significant role in promoting neurodegenerative disorders such as glaucoma. Calcium has been shown to initiate a transient hyperpolarization of the mitochondrial membrane potential triggering a burst of reactive oxygen species leading to apoptosis. Strategies that enhance cell survival signaling pathways aimed at preventing this adverse hyperpolarization of the mitochondrial membrane potential may provide a novel therapeutic intervention in retinal disease. In the retina, brain-derived neurotrophic factor has been shown to be neuroprotective, and our group previously reported a PSD-95/PDZ-binding cyclic peptide (CN2097) that augments brain-derived neurotrophic factor-induced pro-survival signaling. Here, we examined the neuroprotective properties of CN2097 using an established retinal in vivo NMDA toxicity model. CN2097 completely attenuated NMDA-induced caspase 3-dependent and -independent cell death and PARP-1 activation pathways, blocked necrosis, and fully prevented the loss of long term ganglion cell viability. Although neuroprotection was partially dependent upon CN2097 binding to the PDZ domain of PSD-95, our results show that the polyarginine-rich transport moiety C-R(7), linked to the PDZ-PSD-95-binding cyclic peptide, was sufficient to mediate short and long term protection via a mitochondrial targeting mechanism. C-R(7) localized to mitochondria and was found to reduce mitochondrial respiration, mitochondrial membrane hyperpolarization, and the generation of reactive oxygen species, promoting survival of retinal neurons.

Small-molecule inhibitors of JC polyomavirus infection.

The JC polyomavirus (JCPyV) infects approximately 50% of the human population. In healthy individuals, the infection remains dormant and asymptomatic, but in immuno-suppressed patients, it can cause progressive multifocal leukoencephalopathy (PML), a potentially fatal demyelinating disease. Currently, there are no drugs against JCPyV infection nor for the treatment of PML. Here, we report the development of small-molecule inhibitors of JCPyV that target the initial interaction between the virus and host cell and thereby block viral entry. Utilizing a combination of computational and NMR-based screening techniques, we target the LSTc tetrasaccharide binding site within the VP1 pentameric coat protein of JCPyV. Four of the compounds from the screen effectively block viral infection in our in vitro assays using SVG-A cells. For the most potent compound, we used saturation transfer difference NMR to determine the mode of binding to purified pentamers of JCPyV VP1. Collectively, these results demonstrate the viability of this class of compounds for eventual development of JCPyV-antiviral therapeutics.

Selection of heptapeptides that bind helix 69 of bacterial 23S ribosomal RNA.

Helix 69 of Escherichia coli 23S rRNA has important roles in specific steps of translation, such as subunit association, translocation, and ribosome recycling. An M13 phage library was used to identify peptide ligands with affinity for helix 69. One selected sequence, NQVANHQ, was shown through a bead assay to interact with helix 69. Electrospray ionization mass spectroscopy revealed an apparent dissociation constant for the amidated peptide and helix 69 in the low micromolar range. This value is comparable to that of aminoglycoside antibiotics binding to the A site of 16S rRNA or helix 69. Helix 69 variants (human) and unrelated RNAs (helix 31 or A site of 16S rRNA) showed two- to fourfold lower affinity for NQVANHQ-NH(2). These results suggest that the peptide has desirable features for development as a lead compound for novel antimicrobials.

The interplay between structure-based design and combinatorial chemistry.

The two most lauded drug design approaches from the past century--structure-based design and combinatorial chemistry--are increasingly experiencing integration, whereby the three-dimensional coordinates of a receptor supports the development of combinatorial-based ligand design. A selective polling of the recent literature demonstrates that this can be actualized in many ways.

Chemically modified peptides targeting the PDZ domain of GIPC as a therapeutic approach for cancer.

GIPC (GAIP-interacting protein, C terminus) represents a new target class for the discovery of chemotherapeutics. While many of the current generation of anticancer agents function by directly binding to intracellular kinases or cell surface receptors, the disruption of cytosolic protein-protein interactions mediated by non-enzymatic domains is an underdeveloped avenue for inhibiting cancer growth. One such example is the PDZ domain of GIPC. Previously we developed a molecular probe, the cell-permeable octapeptide CR1023 (N-myristoyl-PSQSSSEA), which diminished proliferation of pancreatic cancer cells. We have expanded upon that discovery using a chemical modification approach and here report a series of cell-permeable, side chain-modified lipopeptides that target the GIPC PDZ domain in vitro and in vivo. These peptides exhibit significant activity against pancreatic and breast cancers, both in cellular and animal models. CR1166 (N-myristoyl-PSQSK(εN-4-bromobenzoyl)SK(εN-4-bromobenzoyl)A), bearing two halogenated aromatic units on alternate side chains, was found to be the most active compound, with pronounced down-regulation of EGFR/1GF-1R expression. We hypothesize that these organic acid-modified residues extend the productive reach of the peptide beyond the canonical binding pocket, which defines the limit of accessibility for the native proteinogenic sequences that the PDZ domain has evolved to recognize. Cell permeability is achieved with N-terminal lipidation using myristate, rather than a larger CPP (cell-penetrating peptide) sequence. This, in conjunction with optimization of targeting through side chain modification, has yielded an approach that will allow the discovery and development of next-generation cellular probes for GIPC PDZ as well as for other PDZ domains.

RGS-GAIP-interacting protein controls breast cancer progression.

Although the importance of RGS-GAIP-interacting protein (GIPC) in the biology of malignant cells is well known, the molecular mechanism of GIPC in the inhibition of tumor progression has not been identified. This study focused on elucidating the molecular role of GIPC in breast cancer progression. By using a human breast tumor specimen, an in vivo mouse model, and breast cancer cell lines, we showed for the first time that GIPC is involved in breast cancer progression through regulation of breast cancer cell proliferation, survival, and invasion. Furthermore, we found that the Akt/Mdm2/p53 axis, insulin-like growth factor-1 receptor, matrix metalloproteinase-9, and Cdc42 were downstream of GIPC signaling in breast cancer cells. Moreover, we showed that wild-type p53 reduced GIPC-induced breast cancer cell survival, whereas mutant p53 inhibited GIPC-induced cell invasion. Finally, we demonstrated that an N-myristoylated GIPC peptide (CR1023, N-myristoyl-PSQSSSEA) capable of blocking the PDZ domain of GIPC successfully inhibited MDA-MB-231 cell proliferation, survival, and further in vivo tumor growth. Taken together, these findings demonstrate the importance of GIPC in breast tumor progression, which has a potentially significant impact on the development of therapies against many common cancers expressing GIPC, including breast and renal cancer.

T7 phage display as a method of peptide ligand discovery for PDZ domain proteins.

The use of bacteriophage T7 is presented as a peptide display platform to identify short binding sequences for PDZ domain proteins. Two different domains are examined, the 10th PDZ domain (PDZ10) of the multi-PDZ domain protein 1 (MUPP1) and the third PDZ domain (PDZ3) of postsynaptic density-95 (PSD-95) protein. Using the T7Select 415-1b construct, which displays 415 peptides per phage particle, a random heptapeptide and focused octapeptide libraries were constructed and subjected to iterative selection-enrichment cycles against surface-immobilized PDZ3 and PDZ10 proteins. The derived consensus sequences, together with those of high-frequency clones, were used as the basis for individual chemically synthesized peptides. Each peptide was subjected to isothermal titration calorimetry binding determinations against the corresponding PDZ domain under standard solution conditions. For MUPP1 PDZ10, binding analysis demonstrated that one of the heptapeptides, Ac-IGRISRV, displayed a two-fold improved affinity over the octapeptide derived from the carboxy terminus of the hc-Kit protein, which we had recently demonstrated as among the highest affinity ligands reported to date for that domain. In the case of PSD-95 PDZ3, peptides were found that possessed low-micromolar dissociation constants, as well as those that rediscovered the C-terminal sequence (KQTSV) of the protein CRIPT, a known natural binding protein of PDZ3. These successful examples of ligand discovery against two distinctly different PDZ domains demonstrate that the T7 phage platform could prove broadly applicable to the numerous other PDZ domains for which binding peptides are absent or of insufficient affinity.

Targeting GIPC/synectin in pancreatic cancer inhibits tumor growth.

PURPOSE: Various studies have shown the importance of the GAIP interacting protein, COOH-terminus (GIPC, also known as Synectin) as a central adaptor molecule in different signaling pathways and as an important mediator of receptor stability. GIPC/Synectin is associated with different growth-promoting receptors such as insulin-like growth factor receptor I (IGF-IR) and integrins. These interactions were mediated through its PDZ domain. GIPC/Synectin has been shown to be overexpressed in pancreatic and breast cancer. The goal of this study was to show the importance of GIPC/Synectin in pancreatic cancer growth and to evaluate a possible therapeutic strategy by using a GIPC-PDZ domain inhibitor. Furthermore, the effect of targeting GIPC on the IGF-I receptor as one of its associated receptors was tested. EXPERIMENTAL DESIGN: The in vivo effects of GIPC/Synectin knockdown were studied after lentiviral transduction of luciferase-expressing pancreatic cancer cells with short hairpin RNA against GIPC/Synectin. Additionally, a GIPC-PDZ--targeting peptide was designed. This peptide was tested for its influence on pancreatic cancer growth in vitro and in vivo. RESULTS: Knockdown of GIPC/Synectin led to a significant inhibition of pancreatic adenocarcinoma growth in an orthotopic mouse model. Additionally, a cell-permeable GIPC-PDZ inhibitor was able to block tumor growth significantly without showing toxicity in a mouse model. Targeting GIPC was accompanied by a significant reduction in IGF-IR expression in pancreatic cancer cells. CONCLUSIONS: Our findings show that targeting GIPC/Synectin and its PDZ domain inhibits pancreatic carcinoma growth and is a potential strategy for therapeutic intervention of pancreatic cancer.

Design, synthesis, and evaluation of linear and cyclic peptide ligands for PDZ10 of the multi-PDZ domain protein MUPP1.

PDZ10 is the 10th of 13 PDZ domains found within MUPP1, a cytoplasmic scaffolding protein first identified as an endogenous binding partner of serotonin receptor type 2c (5HT2c). This association, as with those of several other interacting proteins that have subsequently been identified, is mediated through the C-terminal tail of the PDZ domain partner. Using isothermal titration calorimetry (ITC), we measured the thermodynamic binding parameters [changes in Gibbs free energy (DeltaG), enthalpy (DeltaH) and entropy (TDeltaS)] of the isolated PDZ10 domain for variable-length N-acetylated peptides from the 5HT2c serotonin receptor C-terminal sequence, as well as for octapeptides of eight other putative partner proteins of PDZ10 (5HT2a, hc-kit, hTapp1, mTapp2, TARP, NG2, claudin-1, and HPV-18 E6). In length dependence studies of the 5HT2c sequence, the maximal affinity of the peptides leveled off rapidly and further elongation did not significantly improve the dissociation constant (Kd) of 11 microM observed with the pentapeptide. Among the native partners of PDZ10, octapeptides derived from the hc-kit and 5HT2c proteins were the strongest binders, with Kd values of 5.2 and 8.5 microM, respectively. The heat capacity change (DeltaCp) for the 5HT2c octapeptide was determined to be -94 cal/mol, and a calculated estimate indicates burial of polar and apolar surface areas in equal measure upon ligand binding. Peptides with phosphoserine at either the P-1 or P-2 position experienced decreased affinity, which is in accord with the hypothesis that reversible phosphorylation is a possible mechanism for regulating PDZ domain-mediated interactions. Additionally, two conformationally constrained side chain-bridged cyclic peptide ligands were also designed, prepared, evaluated by ITC, and shown to bind PDZ10 primarily through a favorable change in entropy.

Dual role of the exocyst in AMPA receptor targeting and insertion into the postsynaptic membrane.

Intracellular membrane trafficking of glutamate receptors at excitatory synapses is critical for synaptic function. However, little is known about the specialized trafficking events occurring at the postsynaptic membrane. We have found that two components of the exocyst complex, Sec8 and Exo70, separately control synaptic targeting and insertion of AMPA-type glutamate receptors. Sec8 controls the directional movement of receptors towards synapses through PDZ-dependent interactions. In contrast, Exo70 mediates receptor insertion at the postsynaptic membrane, but it does not participate in receptor targeting. Thus, interference with Exo70 function accumulates AMPA receptors inside the spine, forming a complex physically associated, but not yet fused with the postsynaptic membrane. Electron microscopic analysis of these complexes indicates that Exo70 mediates AMPA receptor insertion directly within the postsynaptic density, rather than at extrasynaptic membranes. Therefore, we propose a molecular and anatomical model that dissects AMPA receptor sorting and synaptic delivery within the spine, and uncovers new functions of the exocyst at the postsynaptic membrane.