Giovanna Zinzalla

Targeting protein-protein interactions for therapeutic intervention: a challenge for the future

BACKGROUND Over the last two decades, an increasing research effort in academia and industry has focused on the modulation (both inhibition and stabilization) of protein-protein interactions (PPIs) in order to develop novel therapeutic approaches and target-selective agents in drug discovery. DISCUSSION The diversity and complexity of highly dynamic systems such as PPIs present many challenges for the identification of drug-like molecules with the ability to modulate the PPI with the necessary selectivity and potency. In this review, a number of these strategies will be presented along with a critical overview of the challenges and potential solutions relating to the exploitation of PPIs as molecular targets. CONCLUSIONS Both traditional drug discovery approaches and some more recently developed innovative strategies have already provided valuable tools for the discovery of PPI modulators, and a number of successful examples have highlighted the potential of targeting PPIs for therapeutic intervention, especially in the oncology area.

Chemical variation of natural product-like scaffolds: design and synthesis of spiroketal derivatives.

The design and synthesis of spiroketal structures and their chemical modification, leading to a collection of new small molecules for biological evaluation as orally-bioavailable lead compounds is described. Both [6,5]- and [6,6]-membered ring spiroketal units have been prepared in a stereochemically-varying fashion starting from commercially available (R)- or (S)-glycidol, in ten, eleven and twelve linear steps, in overall yields of 45, 40 and 20%, respectively. Further elaboration according to Lipinskis guidelines has given a collection of structurally-diverse, new spiroketal derivatives in high yields and with high purity.

Small-Molecule Inhibition of c-MYC:MAX Leucine Zipper Formation Is Revealed by Ion Mobility Mass Spectrometry

The leucine zipper interaction between MAX and c-MYC has been studied using mass spectrometry and drift time ion mobility mass spectrometry (DT IM-MS) in addition to circular dichroism spectroscopy. Peptides comprising the leucine zipper sequence with (c-MYC-Zip residues 402-434) and without a postulated small-molecule binding region (c-MYC-ZipΔDT residues 406-434) have been synthesized, along with the corresponding MAX leucine zipper (MAX-Zip residues 74-102). c-MYC-Zip:MAX-Zip complexes are observed both in the absence and in the presence of the reported small-molecule inhibitor 10058-F4 for both forms of c-MYC-Zip. DT IM-MS, in combination with molecular dynamics (MD), shows that the c-MYC-Zip:MAX-Zip complex [M+5H](5+) exists in two conformations, one extended with a collision cross section (CCS) of 1164 ± 9.3 Å(2) and one compact with a CCS of 982 ± 6.6 Å(2); similar values are observed for the two forms of c-MYC-ZipΔDT:MAX-Zip. Candidate geometries for the complexes have been evaluated with MD simulations. The helical leucine zipper structure previously determined from NMR measurements (Lavigne, P.; et al. J. Mol. Biol. 1998, 281, 165), altered to include the DT region and subjected to a gas-phase minimization, yields a CCS of 1247 Å(2), which agrees with the extended conformation we observe experimentally. More extensive MD simulations provide compact complexes which are found to be highly disordered, with CCSs that correspond to the compact form from experiment. In the presence of the ligand, the leucine zipper conformation is completely inhibited and only the more disordered species is observed, providing a novel method to study the effect of interactions of disordered systems and subsequent inhibition of the formation of an ordered helical complex.

Observation of unphosphorylated STAT3 core protein binding to target dsDNA by PEMSA and X-ray crystallography

pSTAT3βtc and pSTAT3βtc bind by molecular sieving (View interaction)

Facile nucleophilic substitution at the C3a tertiary carbon of the 3a-bromohexahydropyrrolo[2,3-b]indole scaffold

The synthesis of 3a-substituted hexahydropyrrolo[2,3-b]indole derivatives via nucleophilic substitution at the C3a position is reported. Nitrogen-, oxygen-, sulfur-, fluoro- and carbon-based nucleophiles have been employed, using both conventional organic solvents and ionic liquids. The C3a-substituted derivatives were obtained in good to excellent yields.

Natural-product-like spiroketals and fused bicyclic acetals as potential therapeutic agents for B-cell chronic lymphocytic leukaemia

B‐cell chronic lymphocytic leukaemia (CLL) is the most common form of leukaemia in the Western world for which no curative treatments are currently available. Purine nucleotide analogues and alkylating agents feature frequently in combination regimens to treat the malignant state, but their use has not led to any significant improvement in patient survival. Consequently, there still remains a need for alternative small‐molecule chemotherapeutics. Natural products are an unparalleled source of drug leads, and an unending inspiration for the design of small‐molecule libraries for drug discovery. The screening of focused libraries of natural‐product‐like spiroketal and fused bicyclic acetal small molecules against primary CLL cells has led to the identification of a small series of novel and potent cytotoxic agents towards primary CLL cells. The validation of the activity of these molecules is delineated through a series of synthesis and screening iterations, whereas preliminary mode of action studies positively indicate their ability to induce cell death via an apoptotic pathway with no evidence of necrosis to further support their potential as novel chemotherapeutic agents.

Investigation of the protein alkylation sites of the STAT3:STAT3 inhibitor Stattic by mass spectrometry

STAT3 (Signal Transducer and Activator of Transcription factor 3) is constitutively active in a wide range of human tumours. Stattic is one of the first non-peptidic small molecules reported to inhibit formation of the STAT3:STAT3 protein dimer complex. A mass spectrometry method has been developed to investigate the binding of Stattic to the un-phosphorylated STAT3βtc (U-STAT3) protein. Alkylation of four cysteine residues has been observed with possible reaction at a fifth which could account for the mechanism of action.

Molecular dynamics studies of the STAT3 homodimer:DNA complex: relationships between STAT3 mutations and protein-DNA recognition.

Signal Transducers and Activators of Transcription (STAT) proteins are a group of latent cytoplasmic transcription factors involved in cytokine signaling. STAT3 is a member of the STAT family and is expressed at elevated levels in a large number of diverse human cancers and is now a validated target for anticancer drug discovery.. Understanding the dynamics of the STAT3 dimer interface, accounting for both protein-DNA and protein-protein interactions, with respect to the dynamics of the latent unphosphorylated STAT3 monomer, is important for designing potential small-molecule inhibitors of the activated dimer. Molecular dynamics (MD) simulations have been used to study the activated STAT3 homodimer:DNA complex and the latent unphosphorylated STAT3 monomer in an explicit water environment. Analysis of the data obtained from MD simulations over a 50 ns time frame has suggested how the transcription factor interacts with DNA, the nature of the conformational changes, and ways in which function may be affected. Examination of the dimer interface, focusing on the protein-DNA interactions, including involvement of water molecules, has revealed the key residues contributing to the recognition events involved in STAT3 protein-DNA interactions. This has shown that the majority of mutations in the DNA-binding domain are found at the protein-DNA interface. These mutations have been mapped in detail and related to specific protein-DNA contacts. Their structural stability is described, together with an analysis of the model as a starting-point for the discovery of novel small-molecule STAT3 inhibitors.

Targeting protein-protein interactions (PPIs) of transcription factors: Challenges of intrinsically disordered proteins (IDPs) and regions (IDRs).

In this review we discuss recent progress in targeting the protein-protein interactions made by oncogenic transcription factors. We particularly focus on the challenges posed by the prevalence of intrinsically disordered regions in this class of protein and the strategies being used to overcome them.

A New Way Forward in Cancer Drug Discovery: Inhibiting the SWI/SNF Chromatin Remodelling Complex

Mutations in subunits of the SWI/SNF chromatin remodelling complex are found in 20 % of human cancers. At face value, this would appear to indicate that this multiprotein complex is a potent tumour suppressor. However, it has recently emerged that some mutations in the SWI/SNF complex can have a gain‐of‐function effect and that in other tumours, such as pancreatic cancer, leukaemia, and breast cancer, the wild‐type complex is used to drive cancer. Thus, paradoxically, this “tumour suppressor” has become an attractive target for developing anticancer agents. The SWI/SNF complex makes several protein–protein interactions both within the complex and with a wide range of transcription factors, and targeting these protein–protein interactions is emerging as the best approach to modulating the activity of the complex selectively.