Rational Design of Selective TMPRSS6 Peptidomimetic Inhibitors via Exploitation of the S2 Subpocket.

TMPRSS6 is a potential therapeutic target for the treatment of iron overload due to its role in regulating levels of hepcidin. Although potent TMPRSS6 inhibitors have been previously developed, their lack of specificity requires optimization to avoid potential side effects before pursuing preclinical development with models. Here, using computer-aided drug design based on a TMPRSS6 homology model, we reveal that the S2 position of TMPRSS6 offers a potential avenue to achieve selectivity against other members of the TTSP family.

Insights on Structure-Passive Permeability Relationship in Pyrrole and Furan-Containing Macrocycles.

Macrocycles have recognized therapeutic potential, but their limited cellular permeability can hinder their development as oral drugs. To better understand the structure-permeability relationship of heterocycle-containing, semipeptidic macrocycles, a library was synthesized. These compounds were created by developing two novel reactions described herein: the reduction of activated oximes by LiBH and the aqueous reductive mono--alkylation of aldehydes using catalytic SmI and stoichiometric Zn.

Comparative Analysis of Cyclization Techniques in Stapled Peptides: Structural Insights into Protein-Protein Interactions in a SARS-CoV-2 Spike RBD/hACE2 Model System.

Medicinal chemistry is constantly searching for new approaches to develop more effective and targeted therapeutic molecules. The design of peptidomimetics is a promising emerging strategy that is aimed at developing peptides that mimic or modulate the biological activity of proteins. Among these, stapled peptides stand out for their unique ability to stabilize highly frequent helical motifs, but they have failed to be systematically reported.

Characterization of PGua, a Guanidinium-Rich Peptoid that Delivers IgGs to the Cytosol via Macropinocytosis.

To investigate the structure-cellular penetration relationship of guanidinium-rich transporters (GRTs), we previously designed PGua, a five-amino acid peptoid containing a conformationally restricted pattern of eight guanidines, which showed high cell-penetrating abilities and low cell toxicity. Herein, we characterized the cellular uptake selectivity, internalization pathway, and intracellular distribution of PGua, as well as its capacity to deliver cargo. PGua exhibits higher penetration efficiency in HeLa cells than in six other cell lines (A549, Caco-2, fibroblast, HEK293, Mia-PaCa2, and MCF7) and is mainly internalized by clathrin-mediated endocytosis and macropinocytosis.

Surface micropatterning for the formation of an in vitro functional endothelial model for cell-based biosensors.

Label-free biosensing, such as with surface plasmon resonance (SPR), is a highly efficient method for monitoring the responses of living cells exposed to pharmacological agents and biochemical stimuli in vitro. Conventional cell culture protocols used in cell-based biosensing generally provide little direct control over cell morphologies and phenotypes. Surface micropatterning techniques have been exploited for the controlled immobilization and establishment of well-defined cell morphologies and phenotypes.

Label-free cell signaling pathway deconvolution of angiotensin type 1 receptor reveals time-resolved G-protein activity and distinct AngII and AngIIIIV responses.

Angiotensin II (AngII) type 1 receptor (ATR) is a G protein-coupled receptor known for its role in numerous physiological processes and its implication in many vascular diseases. Its functions are mediated through G protein dependent and independent signaling pathways. ATR has several endogenous peptidic agonists, all derived from angiotensinogen, as well as several synthetic ligands known to elicit biased signaling responses.

The signaling signature of the neurotensin type 1 receptor with endogenous ligands.

The human neurotensin 1 receptor (hNTS1) is a G protein-coupled receptor involved in many physiological functions, including analgesia, hypothermia, and hypotension. To gain a better understanding of which signaling pathways or combination of pathways are linked to NTS1 activation and function, we investigated the ability of activated hNTS1, which was stably expressed by CHO-K1 cells, to directly engage G proteins, activate second messenger cascades and recruit β-arrestins. Using BRET-based biosensors, we found that neurotensin (NT), NT(8-13) and neuromedin N (NN) activated the Gα-, Gα-, Gα-, and Gα-protein signaling pathways as well as the recruitment of β-arrestins 1 and 2.

iRAGE as a novel carboxymethylated peptide that prevents advanced glycation end product-induced apoptosis and endoplasmic reticulum stress in vascular smooth muscle cells.

Advanced glycation end-products (AGE) and the receptor for AGE (RAGE) have been linked to numerous diabetic vascular complications. RAGE activation promotes a self-sustaining state of chronic inflammation and has been shown to induce apoptosis in various cell types. Although previous studies in vascular smooth muscle cells (VSMC) showed that RAGE activation increases vascular calcification and interferes with their contractile phenotype, little is known on the potential of RAGE to induce apoptosis in VSMC.

Using carboxyfluorescein diacetate succinimidyl ester to monitor intracellular protein glycation.

Protein glycation is a ubiquitous process involved in vascular complications observed in diabetes. Glyoxal (GO), an intracellular reactive oxoaldehyde that is one of the most potent glycation agents, readily reacts with amines present on proteins to produce the lysine-derived adduct carboxymethyllysine, which is a prevalent advanced glycation end-product (AGE). Our group previously showed that cell exposure to GO leads to an alteration in the cell contractile activity that could occur as a result of the glycation of various proteins regulating the cell contractile machinery.

Amplification of AngII-dependent cell contraction by glyoxal: implication of cell mechanical properties and actomyosin activity.

Glyoxal (GO), a highly reactive metabolite of glucose, is associated with diabetic vascular complications via the formation of advanced glycation end-products. Considering its ability to react with proteins' amino acids and its crosslinking potential, we suggest that GO affects cellular mechanical functions such as contractility. Therefore, we tested the effects of GO on cellular contractile response following AngII stimulation of human embryonic kidney cells over-expressing the AT1 receptor (HEK 293 AT1aR).

Cancer-associated regulation of alternative splicing.

Alternative splicing of pre-mRNA increases the diversity of protein functions. Here we show that about half of all active alternative splicing events in ovarian and breast tissues are changed in tumors, and many seem to be regulated by a single factor; sequence analysis revealed binding sites for the RNA binding protein FOX2 downstream of one-third of the exons skipped in cancer. High-resolution analysis of FOX2 binding sites defined the precise positions relative to alternative exons at which the protein may function as either a silencer or an enhancer.

Identification of alternative splicing markers for breast cancer.

Breast cancer is the most common cause of cancer death among women under age 50 years, so it is imperative to identify molecular markers to improve diagnosis and prognosis of this disease. Here, we present a new approach for the identification of breast cancer markers that does not measure gene expression but instead uses the ratio of alternatively spliced mRNAs as its indicator. Using a high-throughput reverse transcription-PCR-based system for splicing annotation, we monitored the alternative splicing profiles of 600 cancer-associated genes in a panel of 21 normal and 26 cancerous breast tissues.

Multiple and specific mRNA processing targets for the major human hnRNP proteins.

Alternative splicing is a key mechanism regulating gene expression, and it is often used to produce antagonistic activities particularly in apoptotic genes. Heterogeneous nuclear ribonucleoparticle (hnRNP) proteins form a family of RNA-binding proteins that coat nascent pre-mRNAs. Many but not all major hnRNP proteins have been shown to participate in splicing control.

Anticancer drugs affect the alternative splicing of Bcl-x and other human apoptotic genes.

Inducing an apoptotic response is the goal of most current chemotherapeutic interventions against cancer. However, little is known about the effect of chemotherapeutic agents on the alternative splicing of apoptotic genes. Here, we have tested 20 of the mainstream anticancer drugs for their ability to influence the production of Bcl-x splice isoforms.