Rearrangement of a unique Kv1.3 selectivity filter conformation upon binding of a drug.

We report two structures of the human voltage-gated potassium channel (Kv) Kv1.3 in immune cells alone (apo-Kv1.3) and bound to an immunomodulatory drug called dalazatide (dalazatide-Kv1.3). Both the apo-Kv1.3 and dalazatide-Kv1.3 structures are in an activated state based on their depolarized voltage sensor and open inner gate. In apo-Kv1.3, the aromatic residue in the signature sequence (Y447) adopts a position that diverges 11 Å from other K+ channels. The outer pore is significantly rearranged, causing widening of the selectivity filter and perturbation of ion binding within the filter. This conformation is stabilized by a network of intrasubunit hydrogen bonds. In dalazatide-Kv1.3, binding of dalazatide to the channel's outer vestibule narrows the selectivity filter, Y447 occupies a position seen in other K+ channels, and this conformation is stabilized by a network of intersubunit hydrogen bonds. These remarkable rearrangements in the selectivity filter underlie Kv1.3's transition into the drug-blocked state.

Contributions of natural products to ion channel pharmacology.

Covering: Up to 2020Ion channels are a vast super-family of membrane proteins that play critical physiological roles in excitable and non-excitable cells. Their biomedical importance makes them valuable and attractive drug targets for neurological, cardiovascular, gastrointestinal and metabolic diseases, and for cancer therapy and immune modulation. Current therapeutics target only a minor subset of ion channels, leaving a large unexploited space within the ion channel field. Natural products harnessed from the almost unlimited and diverse universe of compounds within the bioenvironment have been used to modulate channels for decades. In this review we highlight the impact made by natural products on ion channel pharmacology, specifically on K+, NaV and CaV channels, and use case studies to describe the development of ion channel-modulating drugs from natural sources for the treatment of pain, heart disease and autoimmune diseases.

Modulation of Lymphocyte Potassium Channel KV1.3 by Membrane-Penetrating, Joint-Targeting Immunomodulatory Plant Defensin.

We describe a cysteine-rich, membrane-penetrating, joint-targeting, and remarkably stable peptide, EgK5, that modulates voltage-gated KV1.3 potassium channels in T lymphocytes by a distinctive mechanism. EgK5 enters plasma membranes and binds to KV1.3, causing current run-down by a phosphatidylinositol 4,5-bisphosphate-dependent mechanism. EgK5 exhibits selectivity for KV1.3 over other channels, receptors, transporters, and enzymes. EgK5 suppresses antigen-triggered proliferation of effector memory T cells, a subset enriched among pathogenic autoreactive T cells in autoimmune disease. PET-CT imaging with 18F-labeled EgK5 shows accumulation of the peptide in large and small joints of rodents. In keeping with its arthrotropism, EgK5 treats disease in a rat model of rheumatoid arthritis. It was also effective in treating disease in a rat model of atopic dermatitis. No signs of toxicity are observed at 10-100 times the in vivo dose. EgK5 shows promise for clinical development as a therapeutic for autoimmune diseases.

Venom-Derived Peptide Modulators of Cation-Selective Channels: Friend, Foe or Frenemy.

Ion channels play a key role in our body to regulate homeostasis and conduct electrical signals. With the help of advances in structural biology, as well as the discovery of numerous channel modulators derived from animal toxins, we are moving toward a better understanding of the function and mode of action of ion channels. Their ubiquitous tissue distribution and the physiological relevancies of their opening and closing suggest that cation channels are particularly attractive drug targets, and years of research has revealed a variety of natural toxins that bind to these channels and alter their function. In this review, we provide an introductory overview of the major cation ion channels: potassium channels, sodium channels and calcium channels, describe their venom-derived peptide modulators, and how these peptides provide great research and therapeutic value to both basic and translational medical research.

In vitro assembly of polymorphic virus-like particles from the capsid protein of a nodavirus.

Viral capsid proteins are programmed to assemble into homogeneous structures in native environments; but the molecular details of these assembly pathways are seldom clearly understood. In order to define the chain of events in the construction of a minimal system, we attempted controlled assembly of the capsid protein of a small insect nodavirus, Flock House Virus (FHV). Bacterial expression of the FHV capsid protein, and subsequent in vitro assembly, generated a heterogeneous population of closed particles. We show that in spite of the altered structure, these particles are capable of membrane disruption, like native viruses, and of incorporating and delivering foreign cargo to specific locations. The unique structure and characteristics of these particles extends our understanding of nodavirus assembly. Additionally, the establishment of a bacterial production system, and methods for in vitro assembly and packaging are of considerable benefit for biotechnological applications of FHV.

Non-Enveloped Virus Entry: Structural Determinants and Mechanism of Functioning of a Viral Lytic Peptide.

In the absence of lipid envelopes and associated fusion proteins, non-enveloped viruses employ membrane lytic peptides to breach the limiting membranes of host cells. Although several of these lytic peptides have been identified and characterized, their manner of deployment and interaction with host membranes remains unclear in most cases. We are using the gamma peptide of Flock House Virus (FHV), a model non-enveloped virus, to understand the mechanistic details of non-enveloped virus interaction with host cell membranes. We utilized a combination of biophysical assays, molecular dynamics simulation studies, and single-particle cryo-electron microscopy to elucidate the functional and structural determinants for membrane penetration by gamma in context of the FHV capsid. Although the amphipathic, helical N-terminal region of gamma (γ1) was previously thought to be the membrane-penetrating module, with the C-terminal region having a supporting role in correct structural positioning of γ1, we demonstrate that the C terminus of gamma directly participates in membrane penetration. Our studies suggest that full-length gamma, including the hydrophobic C terminus, forms an alpha-helical hairpin motif, and any disruption in this motif drastically reduces its functionality, in spite of the correct positioning of amphipathic γ1 in the virus capsid. Taken together, our data suggest that the most effective module for membrane disruption is a pentameric unit of full-length gamma, released from the virus, which associates with membranes via both N- and C-terminal ends.

Engineering Virus Capsids Into Biomedical Delivery Vehicles: Structural Engineering Problems in Nanoscale.

Virus capsids have evolved to protect the genome sequestered in their interior from harsh environmental conditions, and to deliver it safely and precisely to the host cell of choice. This characteristic makes them naturally perfect containers for delivering therapeutic molecules to specific locations. Development of an ideal virus-based nano-container for medical usage requires that the capsid be converted into a targetable protein cage which retains the original stability, flexibility and host cell penetrating properties of the native particles, without the associated immunogenicity, and is able to encapsulate large quantities of therapeutic or diagnostic material. In the last few years, several icosahedral, non-enveloped viruses, with a diameter of 25-90 nm-a size which conveniently falls within the 10-100 nm range desirable for biomedical nanoparticles-have been chemically or genetically engineered towards partial fulfilment of the above criteria. This review summarizes the approaches taken towards engineering viruses into biomedical delivery devices and discusses the challenges involved in achieving this goal.

Evaluation of salivary and serum lipid peroxidation, and glutathione in oral leukoplakia and oral squamous cell carcinoma.

Lipid peroxidation induced by reactive oxygen species (ROS) is involved in the pathogenesis of malignancy. Overall, lipid peroxidation levels are indicated by malondialdehyde (MDA), which is the most frequently used biomarker to detect oxidative changes. Antioxidant defense systems such as glutathione (GSH) limit cell injury induced by ROS. Therefore, MDA and GSH can be used to monitor oxidative stress (OS). Hence, this study aimed to evaluate and compare both salivary and serum levels of MDA and GSH in oral leukoplakia and oral squamous cell carcinoma (OSCC) patients, and healthy controls. The study included 100 subjects comprising 30 apparently healthy controls, 30 patients with oral leukoplakia and 40 clinically and histologically diagnosed patients with OSCC. Saliva and blood samples were obtained and evaluated for MDA and GSH. The study revealed enhanced MDA levels in saliva and serum in oral leukoplakia and OSCC patients as compared to controls. On the other hand, significant decreases were seen in serum and salivary GSH levels in oral leukoplakia and OSCC patients as compared to controls. Augmentation of OS in blood and saliva is reflected by increase in MDA and decrease in GSH levels, indicating that tumor processes cause an imbalance of oxidant-antioxidant status in cell structures.