Molecular Mechanisms of Paraptosis Induction: Implications for a Non-Genetically Modified Tumor Vaccine

Paraptosis is the programmed cell death pathway that leads to cellular necrosis. Previously, rodent and human monocytes/macrophages killed glioma cells bearing the membrane macrophage colony stimulating factor (mM-CSF) through paraptosis, but the molecular mechanism of this killing process was never identified. We have demonstrated that paraptosis of rat T9 glioma cells can be initiated through a large potassium channel (BK)-dependent process initiated by reactive oxygen species. Macrophage mediated cytotoxicity upon the mM-CSF expressing T9-C2 cells was not prevented by the addition of the caspase inhibitor, zVAD-fmk. By a combination of fluorescent confocal and electron microscopy, flow cytometry, electrophysiology, pharmacology, and genetic knock-down approaches, we demonstrated that these ion channels control cellular swelling and vacuolization of rat T9 glioma cells. Cell lysis is preceded by a depletion of intracellular ATP. Six-hour exposure to BK channel activation caused T9 cells to over express heat shock proteins (Hsp 60, 70, 90 and gp96). This same treatment forced HMGB1 translocation from the nuclear region to the periphery. These last molecules are “danger signals” that can stimulate immune responses. Similar inductions of mitochondrial swelling and increased Hsp70 and 90 expressions by BK channel activation were observed with the non-immunogenic F98 glioma cells. Rats injected with T9 cells which were killed by prolonged BK channel activation developed immunity against the T9 cells, while the injection of x-irradiated apoptotic T9 cells failed to produce the vaccinating effect. These results are the first to show that glioma cellular death induced by prolonged BK channel activation improves tumor immunogenicity; this treatment reproduces the vaccinating effects of mM-CSF transduced cells. Elucidation of strategies as described in this study may prove quite valuable in the development of clinical immunotherapy against cancer.     

Productive phage infection in Escherichia coli with reduced internal levels of the major cations.

Bacteriophage-induced changes in the intracellular levels of the major cations of Escherichia coli were studied to investigate the role of ion concentrations for bacteriophage assembly in vivo. Infection of E. coli by phage T4, P1, or lambda caused a transient reduction of intracellular levels of potassium, magnesium, and polyamines. Phages T3 and T7, however, had no detectable effect on the cation concentrations within the cell. In all cases, any reduction in the ion concentrations was restored later in infection. When the intracellular potassium concentration was lowered from 325 to 150 mM with a different osmotic growth medium, the number of phage progeny was only slightly reduced (by a factor of two). On additional reduction of the intracellular magnesium concentration from 100 to 50 mM by adding the antibiotic polymyxin B to the infected cells, T4 infections, but not T3 or T7, were markedly affected. These studies show that T3, T4, and T7 phage assembly can efficiently occur in vivo over a broad spectrum of ion concentrations.     

Metabolic and thermal stimuli control K(2P)2.1 (TREK-1) through modular sensory and gating domains

K(2P)2.1 (TREK-1) is a polymodal two-pore domain leak potassium channel that responds to external pH, GPCR-mediated phosphorylation signals, and temperature through the action of distinct sensors within the channel. How the various intracellular and extracellular sensory elements control channel function remains unresolved. Here, we show that the K(2P)2.1 (TREK-1) intracellular C-terminal tail (Ct), a major sensory element of the channel, perceives metabolic and thermal commands and relays them to the extracellular C-type gate through transmembrane helix M4 and pore helix 1. By decoupling Ct from the pore-forming core, we further demonstrate that Ct is the primary heat-sensing element of the channel, whereas, in contrast, the pore domain lacks robust temperature sensitivity. Together, our findings outline a mechanism for signal transduction within K(2P)2.1 (TREK-1) in which there is a clear crosstalk between the C-type gate and intracellular Ct domain. In addition, our findings support the general notion of the existence of modular temperature-sensing domains in temperature-sensitive ion channels. This marked distinction between gating and sensory elements suggests a general design principle that may underlie the function of a variety of temperature-sensitive channels.     

Dependence of intracellular alkali-ion concentrations of 3T3 and SV 40-3T3 cells on growth density.

Intracellular contents of potassium and of sodium are determined for 3T3 and SV 40-3T3 cells in dependence of growth density. In parallel, total cell volume and volume of intracellular water is determined for these cells suspended in physiological buffer. Intracellular potassium concentration thus evaluated for suspended 3T3 cells exhibits a sharp decrease at cellular growth densities which lead to density dependent inhibition of cell proliferation. In the case of SV 40-3T3 cells, this drop of potassium concentration with increasing cellular growth density is not observed, which correlates well with the absence of cell density dependent inhibition of cell growth in the transformed cell line. These results support the notion that processes of stimulation of quiescent 3T3 cells or of cell density dependent inhibition of their proliferation are mediated by processes including changes of potassium transport characteristics leading to increase or decrease respectively of their intracellular potassium concentration. Furthermore, these and other results suggest, that a difference between normal and transformed cells most relevant to their different proliferation behaviour might reside in different transport characteristics for potassium of the plasma membranes of these cells.     

Immunosuppressive effects of a Kv1.3 inhibitor

The voltage gated potassium channel (Kv1.3) has been shown to play a role in immune responsiveness. Blockade of the channel led to diminution of T cell activation and delayed type hypersensitivity. Previous in vitro studies of the blockade were focused on T cell activation and proliferation. In this study we examined other T and monocytic cell mediated events to glean the extent of the immunosuppressive effects of a Kv1.3 specific inhibitor, Margatoxin (MgTX). We found that MgTX inhibited the intracellular production of Th-1 as well as Th-2 cytokines. MgTX can also inhibit IL-2 production and proliferation of T cells upon stimulation with anti-CD3 and VCAM-1. Furthermore, a redirected cytolytic activity was also inhibited by MgTX. However, MgTX did not inhibit generation of CTL to EBV transformed lymphoma cells or antibody-dependent cellular cytolysis mediated by monocytes. It appears that a Kv1.3 blockade does not affect all immune responses, particularly those of innate immunity.     

Dual modulation of a potassium channel by the m1 muscarinic and beta2-adrenergic receptors

Neurotransmitter receptors alter membrane excitability and synaptic efficacy by generating intracellular signals that ultimately change the properties of ion channels. Given their critical role in controlling cell membrane potential, potassium channels are frequently the targets of modulatory signals from many different G protein-coupled receptors. However, due to the heterogeneity of potassium channel expression in vivo, it has been difficult to determine the molecular mechanisms governing the regulation of molecularly defined potassium channels. Through expression studies in Xenopus oocytes and mammalian cells, we found that the m1 muscarinic acetylcholine receptor (mAChR) potently suppresses a cloned delayed rectifier potassium channel, termed RAK, through a pathway involving phospholipase C activation and direct tyrosine phosphorylation of the RAK protein. In contrast, we found that RAK channel activity is strongly enhanced following agonist activation of beta2-adrenergic receptors; this effect requires a single PKA consensus phosphorylation site located near the amino terminus of the channel protein. These results demonstrate that a specific type of potassium channel that is widely expressed in the mammalian brain and heart is subject to both positive and negative regulation by G protein-dependent pathways.     

The dipole moments of membrane proteins: potassium channel proteins. II. T1 assembly. Search for the voltage sensor

The dipole moments of potassium channel protein (Kcsa) and beta-subunits were discussed in the previous paper of this series [Takashima, Biophys. Chem. 94 (2001) 209-218]. While the dipole moment of beta-subunits was found to be very large, the dipole moment of Kcsa turned out to be somewhat smaller than beta-subunits. As the continuation of this work, the discussion of the present paper is focussed on the dipole moment of T1 assembly, another component of the K-channel. As discussed later, the calculation using the X-ray crystallographic data by MacKinnon et al., revealed an astoundingly large dipole moment for T1 assembly. The dipole moment of T1 assembly combined with the likewise large dipole moment of beta-subunits amounts to a sufficient value to play an essential role as a voltage sensor of potassium channel.     

Volume regulation of murine T lymphocytes relies on voltage-dependent and two-pore domain potassium channels

A variety of ion channels are supposed to orchestrate the homoeostatic volume regulation in T lymphocytes. However, the relative contribution of different potassium channels to the osmotic volume regulation and in particular to the regulatory volume decrease (RVD) in T cells is far from clear. This study explores a putative role of the newly identified K(2P) channels (TASK1, TASK2, TASK3 and TRESK) along with the voltage-gated potassium channel K(V)1.3 and the calcium-activated potassium channel K(Ca)3.1 in the RVD of murine T lymphocytes, using genetic and pharmacological approaches. K(2P) channel knockouts exerted profound effects on the osmotic properties of murine T lymphocytes, as revealed by reduced water and RVD-related solute permeabilities. Moreover, both genetic and pharmacological data proved a key role of K(V)1.3 and TASK2 channels in the RVD of murine T cells exposed to hypotonic saline. Our experiments demonstrate a leading role of potassium channels in the osmoregulation of T lymphocytes under different conditions. In summary, the present study sheds new light on the complex and partially redundant network of potassium channels involved in the basic physiological process of the cellular volume homeostasis and extends the repertoire of potassium channels by the family of K(2P) channels.     

Expression of the two pore domain potassium channel TREK-1 in human intervertebral disc cells

Potassium channels play a major role in intracellular homeostasis and regulation of cell volume. Intervertebral disc cells respond to mechanical loading in a complex manner. Mechanical loading may play a role in disc degeneration. Lumbar intervertebral disc samples from 5 patients (average age: 47 years, range: 25-64 years) were used for this study, investigating cells from the nucleus pulposus and the annulus fibrosus duplicate samples to determine RNA expression and protein expression. Analysis of mRNA expression by RT-PCR demonstrated that TREK 1 was expressed by nucleus pulposus (n=5) and annulus fibrosus (n=5) cells. Currently, TREK-1 is the only potassium channel known to be activated by intracellular acidosis, and responds to mechanical and chemical stimuli. Whilst the precise role of potassium channels in cellular homeostasis remains to be determined, TREK-1 may be important to protect disc cells against ischaemic damage, and subsequent disc degeneration, and may also play a role in effecting mechanotransduction. Further research is required to fully elucidate the role of the TREK-1 ion channel in intervertebral disc cells.     

Inositol phosphates promote HIV-1 assembly and maturation to facilitate viral spread in human CD4+ T cells

Gag polymerization with viral RNA at the plasma membrane initiates HIV-1 assembly. Assembly processes are inefficient in vitro but are stimulated by inositol (1,3,4,5,6) pentakisphosphate (IP5) and inositol hexakisphosphate (IP6) metabolites. Previous studies have shown that depletion of these inositol phosphate species from HEK293T cells reduced HIV-1 particle production but did not alter the infectivity of the resulting progeny virions. Moreover, HIV-1 substitutions bearing Gag/CA mutations ablating IP6 binding are noninfectious with destabilized viral cores. In this study, we analyzed the effects of cellular depletion of IP5 and IP6 on HIV-1 replication in T cells in which we disrupted the genes encoding the kinases required for IP6 generation, IP5 2-kinase (IPPK) and Inositol Polyphosphate Multikinase (IPMK). Knockout (KO) of IPPK from CEM and MT-4 cells depleted cellular IP6 in both T cell lines, and IPMK disruption reduced the levels of both IP5 and IP6. In the KO lines, HIV-1 spread was delayed relative to parental wild-type (WT) cells and was rescued by complementation. Virus release was decreased in all IPPK or IPMK KO lines relative to WT cells. Infected IPMK KO cells exhibited elevated levels of intracellular Gag protein, indicative of impaired particle assembly. IPMK KO compromised virus production to a greater extent than IPPK KO suggesting that IP5 promotes HIV-1 particle assembly in IPPK KO cells. HIV-1 particles released from infected IPPK or IPMK KO cells were less infectious than those from WT cells. These viruses exhibited partially cleaved Gag proteins, decreased virion-associated p24, and higher frequencies of aberrant particles, indicative of a maturation defect. Our data demonstrate that IP6 enhances the quantity and quality of virions produced from T cells, thereby preventing defects in HIV-1 replication.     

A central role for the T1 domain in voltage-gated potassium channel formation and function

To interpret the recent atomic structures of the Kv (voltage-dependent potassium) channel T1 domain in a functional context, we must understand both how the T1 domain is integrated into the full-length functional channel protein and what functional roles the T1 domain governs. The T1 domain clearly plays a role in restricting Kv channel subunit heteromultimerization. However, the importance of T1 tetramerization for the assembly and retention of quarternary structure within full-length channels has remained controversial. Here we describe a set of mutations that disrupt both T1 assembly and the formation of functional channels and show that these mutations produce elevated levels of the subunit monomer that becomes subject to degradation within the cell. In addition, our experiments reveal that the T1 domain lends stability to the full-length channel structure, because channels lacking the T1 containing N terminus are more easily denatured to monomers. The integration of the T1 domain ultrastructure into the full-length channel was probed by proteolytic mapping with immobilized trypsin. Trypsin cleavage yields an N-terminal fragment that is further digested to a tetrameric domain, which remains reactive with antisera to T1, and that is similar in size to the T1 domain used for crystallographic studies. The trypsin-sensitive linkages retaining the T1 domain are cleaved somewhat slowly over hours. Therefore, they seem to be intermediate in trypsin resistance between the rapidly cleaved extracellular linker between the first and second transmembrane domains, and the highly resistant T1 core, and are likely to be partially structured or contain dynamic structure. Our experiments suggest that tetrameric atomic models obtained for the T1 domain do reflect a structure that the T1 domain sequence forms early in channel assembly to drive subunit protein tetramerization and that this structure is retained as an integrated stabilizing structural element within the full-length functional channel.     

ESCRT regulates surface expression of the Kir2.1 potassium channel

Protein quality control (PQC) is required to ensure cellular health. PQC is recognized for targeting the destruction of defective polypeptides, whereas regulated protein degradation mechanisms modulate the concentration of specific proteins in concert with physiological demands. For example, ion channel levels are physiologically regulated within tight limits, but a system-wide approach to define which degradative systems are involved is lacking. We focus on the Kir2.1 potassium channel because altered Kir2.1 levels lead to human disease and Kir2.1 restores growth on low-potassium medium in yeast mutated for endogenous potassium channels. Using this system, first we find that Kir2.1 is targeted for endoplasmic reticulum–associated degradation (ERAD). Next a synthetic gene array identifies nonessential genes that negatively regulate Kir2.1. The most prominent gene family that emerges from this effort encodes members of endosomal sorting complex required for transport (ESCRT). ERAD and ESCRT also mediate Kir2.1 degradation in human cells, with ESCRT playing a more prominent role. Thus multiple proteolytic pathways control Kir2.1 levels at the plasma membrane.     

Effects of bilirubin on potassium (86Rb+) influx and ionic content in Ehrlich ascites cells

Potassium influx, intracellular potassium and sodium content and cellular volume were determined in vitro in Ehrlich ascites cells in the presence of up to 0.8 mM bilirubin in the incubation medium. Bilirubin uptake into cells as a function of bilirubin concentration in the incubation medium increased linearly with a molar bilirubin/albumin ratio of 20 : 1. Potassium influx and intracellular content decreased while cellular volume increased after 180 min of incubation of cells in bilirubin at a molar bilirubin/albumin ratio of 20 : 1. At a bilirubin/albumin ratio 2 : 1, potassium influx decreased, cellular volume remained unchanged, and bilirubin uptake into cells became saturated at bilirubin concentrations greater than 0.3 mM. It is suggested that bilirubin-induced alterations in potassium gradients across cell membranes may play a role in toxic effects of bilirubin on cells.     

Effects of bilirubin on potassium (86Rb+) influx and ionic content in Ehrlich ascites cells.

Potassium influx, intracellular potassium and sodium content and cellular volume were determined in vitro in Ehrlich ascites cells in the presence of up to 0.8 mM bilirubin in the incubation medium. Bilirubin uptake into cells as a function of bilirubin concentration in the incubation medium increased linearly with a molar bilirubin/albumin ratio of 20 : 1. Potassium influx and intracellular content decreased while cellular volume increased after 180 min of incubation of cells in bilirubin at a molar bilirubin/albumin ratio of 20 : 1. At a bilirubin/albumin ratio 2 : 1, potassium influx decreased, cellular volume remained unchanged, and bilirubin uptake into cells became saturated at bilirubin concentrations greater than 0.3 mM. It is suggested that bilirubin-induced alterations in potassium gradients across cell membranes may play a role in toxic effects of bilirubin on cells.     

Cation transport and content in serum-stimulated CHO-773 cells. II. Late changes in rubidium influx and intracellular potassium content

Serum stimulation of stationary cultures of Chinese hamster ovary cells CHO-K1 (clone 773) is accompanied by sustained increase in ouabain-sensitive rubidium (potassium) influx which results in the elevation of intracellular potassium content from 0.5-0.6 to 0.7-0.8 mmole per gram of protein. Cytofluorometric studies of serum-stimulated CHO-773 cultures have shown that the intracellular potassium increase is necessary for successful G1----S progression. The elevation of intracellular potassium was found to occur simultaneously with the cellular protein growth. Cycloheximide (10 micrograms/ml) does not influence the early Na,K-ATPase activation induced by serum; however, it abolishes the sustained increase of both rubidium influx and intracellular potassium content. In serum stimulated cells ouabain increases the potassium efflux; this ouabain effect is not observed after S phase, when rubidium (potassium) influx decreases and intracellular potassium content stops growing.