Assessment of gold nanoparticle effect on prostate cancer LNCaP cells.

UNLABELLED: In recent years gold nanoparticles (AuNPs) have received considerable attention for various biomedical applications including diagnostics and targeted drug delivery. However, more research is still needed to characterize such aspects of their use in clinical oncology as permeability, retention and functional effect on tumor cells. AIMS: This study was designed to describe the effect of non-functionalized AuNPs on LNCaP prostate cancer cells growth. MATERIAL AND METHODS: LNCaP cells were cultured in RPMI-1640 medium containing AuNPs covered by polyvinylpyrrolidone of average size 26.4 nm (10.0 µg/ml). Counts of cells were calculated and their morphology was examined. RESULTS: AuNPs conglomerates have been visualized in cultured cells. After 4-day incubation in presence of AuNPs significant retardation of LNCaP cells growth was observed both in 5α-dihydrotestosterone stimulated and non-stimulated cultures. No morphological changes of live LNCaP cells were seen in any experiment. CONCLUSION: Given absence of morphological changes in live cells and dribble and relatively constant numbers of dead cells, it was concluded that inhibitory effect of AuNPs on LNCaP cells growth was caused by alterations of proliferation.

Orai1 contributes to the establishment of an apoptosis-resistant phenotype in prostate cancer cells.

The molecular nature of calcium (Ca(2+))-dependent mechanisms and the ion channels having a major role in the apoptosis of cancer cells remain a subject of debate. Here, we show that the recently identified Orai1 protein represents the major molecular component of endogenous store-operated Ca(2+) entry (SOCE) in human prostate cancer (PCa) cells, and constitutes the principal source of Ca(2+) influx used by the cell to trigger apoptosis. The downregulation of Orai1, and consequently SOCE, protects the cells from diverse apoptosis-inducing pathways, such as those induced by thapsigargin (Tg), tumor necrosis factor α, and cisplatin/oxaliplatin. The transfection of functional Orai1 mutants, such as R91W, a selectivity mutant, and L273S, a coiled-coil mutant, into the cells significantly decreased both SOCE and the rate of Tg-induced apoptosis. This suggests that the functional coupling of STIM1 to Orai1, as well as Orai1 Ca(2+)-selectivity as a channel, is required for its pro-apoptotic effects. We have also shown that the apoptosis resistance of androgen-independent PCa cells is associated with the downregulation of Orai1 expression as well as SOCE. Orai1 rescue, following Orai1 transfection of steroid-deprived cells, re-established the store-operated channel current and restored the normal rate of apoptosis. Thus, Orai1 has a pivotal role in the triggering of apoptosis, irrespective of apoptosis-inducing stimuli, and in the establishment of an apoptosis-resistant phenotype in PCa cells.

Modulation by testosterone of an endogenous hERG potassium channel current.

hERG (human ether-a-go-go-related gene) potassium (K+) channels are expressed in a range of tissue types including neuroblastoma cells and the heart, in which hERG K+ current is important for action potential repolarization. Whilst gender differences in cardiac repolarization and the QT interval of the cardiac electrocardiogram are well-established, comparatively little is known about regulation of hERG channels by sex hormones. In this study, whole-cell patch-clamp recordings were made at 37 degrees C from SH-SY5Y human neuroblastoma cells to investigate modulation of endogenous hERG K+ channel current (I(hERG)) by testosterone. Acutely applied testosterone at a physiologically relevant concentration (10 nM) produced a modest (approximately 13-15 %) increase in I(hERG) amplitude, whilst a high concentration (1 microM) slightly decreased I(hERG). The stimulatory effect of testosterone was inhibited by the androgen receptor antagonist flutamide (10 microM) and the PI-3 kinase inhibitor wortmannin (1 microM). Chronic (24 h) application of testosterone also augmented IhERG via flutamide-sensitive receptor activation, without modulation of the current's voltage-dependence. These results demonstrate for the first time that testosterone can stimulate (hERG) K+ channels via activation of classical androgen receptors and implicate PI-3 kinase in the acute response.

Ion channels in death and differentiation of prostate cancer cells.

Plasma membrane ion channels contribute to virtually all basic cellular processes, including such crucial ones for maintaining tissue homeostasis as proliferation, differentiation, and apoptosis. Enhanced proliferation, aberrant differentiation, and impaired ability to die are the prime reasons for abnormal tissue growth, which can eventually turn into uncontrolled expansion and invasion, characteristic of cancer. Prostate cancer (PCa) cells express a variety of plasma membrane ion channels. By providing the influx of essential signaling ions, perturbing intracellular ion concentrations, regulating cell volume, and maintaining membrane potential, PCa cells are critically involved in proliferation, differentiation, and apoptosis. PCa cells of varying metastatic ability can be distinguished by their ion channel characteristics. Increased malignancy and invasiveness of androgen-independent PCa cells is generally associated with the shift to a 'more excitable' phenotype of their plasma membrane. This shift is manifested by the appearance of voltage-gated Na(+) and Ca(2+) channels which contribute to their enhanced apoptotic resistance together with downregulated store-operated Ca(2+) influx, altered expression of different K(+) channels and members of the Transient Receptor Potential (TRP) channel family, and strengthened capability for maintaining volume constancy. The present review examines channel types expressed by PCa cells and their involvement in metastatic behaviors.

Calcium signalling and cancer cell growth.

Cancer is caused by defects in the mechanisms underlying cell proliferation and cell death. Calcium ions are central to both phenomena, serving as major signalling agents with spatial localization, magnitude and temporal characteristics of calcium signals ultimately determining cell's fate. There are four primary compartments: extracellular space, cytoplasm, endoplasmic reticulum and mitochondria that participate in the cellular Ca2+ circulation. They are separated by own membranes incorporating divers Ca2(+)-handling proteins whose concerted action provides for Ca2+ signals with the spatial and temporal characteristics necessary to account for specific cellular response. The transformation of a normal cell into a cancer cell is associated with a major re-arrangement of Ca2+ pumps, Na/Ca exchangers and Ca2+ channels, which leads to the enhanced proliferation and impaired ability to die. In the present chapter we examine what changes in Ca+ signalling and the mechanisms that support it underlie the passage from normal to pathological cell growth and death control. Understanding this changes and identifying molecular players involved provides new prospects for cancers treatment.

Tandem-pore domain potassium channels are functionally expressed in retinal (Müller) glial cells.

Tandem-pore domain (2P-domain) K+-channels regulate neuronal excitability, but their function in glia, particularly, in retinal glial cells, is unclear. We have previously demonstrated the immunocytochemical localization of the 2P-domain K+ channels TASK-1 and TASK-2 in retinal Müller glial cells of amphibians. The purpose of the present study was to determine whether these channels were functional, by employing whole-cell recording from frog and mammalian (guinea pig, rat and mouse) Müller cells and confocal microscopy to monitor swelling in rat Müller cells. TASK-like immunolabel was localized in these cells. The currents mediated by 2P-domain channels were studied in isolation after blocking Kir, K(A), K(D), and BK channels. The remaining cell conductance was mostly outward and was depressed by acid pH, bupivacaine, methanandamide, quinine, and clofilium, and activated by alkaline pH in a manner consistent with that described for TASK channels. Arachidonic acid (an activator of TREK channels) had no effect on this conductance. Blockade of the conductance with bupivacaine depolarized the Müller cell membrane potential by about 50%. In slices of the rat retina, adenosine inhibited osmotic glial cell swelling via activation of A1 receptors and subsequent opening of 2P-domain K+ channels. The swelling was strongly increased by clofilium and quinine (inhibitors of 2P-domain K+ channels). These data suggest that 2P-domain K+ channels are involved in homeostasis of glial cell volume, in activity-dependent spatial K+ buffering and may play a role in maintenance of a hyperpolarized membrane potential especially in conditions where Kir channels are blocked or downregulated.

Alterations in the regulatory volume decrease (RVD) and swelling-activated Cl- current associated with neuroendocrine differentiation of prostate cancer epithelial cells.

Neuroendocrine (NE) differentiation of prostate epithelial/basal cells is a hallmark of advanced, androgen-independent prostate cancer, for which there is no successful therapy. Here we report for the first time on alterations in regulatory volume decrease (RVD) and its key determinant, swelling-activated Cl- current (I(Cl,swell)), associated with NE differentiation of androgen-dependent LNCaP prostate cancer epithelial cells. NE-differentiating regimens, namely, chronic cAMP elevation or androgen deprivation, resulted in generally augmented I(Cl,swell) and enhanced RVD. This occurred as a result of both the increased endogenous expression of ClC-3, which is a volume-sensitive Cl- channel involved, as we show, in I(Cl,swell) in LNCaP (lymph-node carcinoma of the prostate) cells and the weaker negative I(Cl,swell) control from Ca2+ entering via store-dependent pathways. The changes in the RVD of NE-differentiated cells generally mimicked those reported for Bcl-2-conferred apoptotic resistance. Our results suggest that strengthening the mechanism that helps to maintain volume constancy may contribute to better survival rates of apoptosis-resistant NE cells.

2-APB inhibits volume-regulated anion channels independently from intracellular calcium signaling modulation.

It has previously been suggested that volume-regulated anion channels (VRACs) and store-operated channels (SOCs) interact with each other according to their expected colocalization in the plasma membrane of LNCaP cells. In order to study interactions between these two channels, we used 2-aminoethoxydiphenyl borate (2-APB) as a regular SOC inhibitor. Surprisingly 2-APB reduced VRAC activity in a dose-dependent manner (IC(50)=122.8 microM), but not 2,2-diphenyltetrahydrofuran (a structural analog of 2-APB). This effect was also present in keratinocytes. We conclude that 2-APB is an inhibitor of the VRAC family, and is also a potent tool to study the SOC-VRAC interaction in LNCaP cells.

Ca2+ homeostasis and apoptotic resistance of neuroendocrine-differentiated prostate cancer cells.

Neuroendocrine (NE) differentiation is a hallmark of advanced, androgen-independent prostate cancer, for which there is no successful therapy. NE tumor cells are nonproliferating and escape apoptotic cell death; therefore, an understanding of the apoptotic status of the NE phenotype is imperative for the development of new therapies for prostate cancer. Here, we report for the first time on alterations in intracellular Ca(2+) homeostasis, which is a key factor in apoptosis, caused by NE differentiation of androgen-dependent prostate cancer epithelial cells. NE-differentiating regimens, either cAMP elevation or androgen deprivation, resulted in a reduced endoplasmic reticulum Ca(2+)-store content due to both SERCA 2b Ca(2+) ATPase and luminal Ca(2+) binding/storage chaperone calreticulin underexpression, and to a downregulated store-operated Ca(2+) current. NE-differentiated cells showed enhanced resistance to thapsigargin- and TNF-alpha-induced apoptosis, unrelated to antiapoptotic Bcl-2 protein overexpression. Our results suggest that targeting the key players determining Ca(2+) homeostasis in an attempt to enhance the proapoptotic potential of malignant cells may prove to be a useful strategy in the treatment of advanced prostate cancer.

Store-operated Ca2+ channels in prostate cancer epithelial cells: function, regulation, and role in carcinogenesis.

Ca2+ homeostasis mechanisms, in which the Ca2+ entry pathways play a key role, are critically involved in both normal function and cancerous transformation of prostate epithelial cells. Here, using the lymph node carcinoma of the prostate (LNCaP) cell line as a major experimental model, we characterize prostate-specific store-operated Ca2+ channels (SOCs)--a primary Ca2+ entry pathway for non-excitable cells--for the first time. We show that prostate-specific SOCs share major store-dependent, kinetic, permeation, inwardly rectifying, and pharmacological (including dual, potentiation/inhibition concentration-dependent sensitivity to 2-APB) properties with "classical" Ca2+ release-activated Ca2+ channels (CRAC), but have a higher single channel conductance (3.2 and 12pS in Ca2+- and Na+-permeable modes, respectively). They are subject to feedback inhibition via Ca2+-dependent PKC, CaMK-II and CaM regulatory pathways and are functionally dependent on caveolae integrity. Caveolae also provide a scaffold for spatial co-localization of SOCs with volume-regulated anion channels (VRAC) and their Ca2+-mediated interaction. The TRPC1 and TRPV6 members of the transient receptor potential (TRP) channel family are the most likely molecular candidates for the formation of prostate-specific endogenous SOCs. Differentiation of LNCaP cells to an androgen-insensitive, apoptotic-resistant neuroendocrine phenotype downregulates SOC current. We conclude that prostate-specific SOCs are important determinants in the transition to androgen-independent prostate cancer.

Receptor-coupled, DAG-gated Ca2+-permeable cationic channels in LNCaP human prostate cancer epithelial cells.

Although the prostate gland is a rich source of alpha1-adreno- (alpha1-AR) and m1-cholino receptors (m1-AChR), the membrane processes associated with their activation in glandular epithelial cells is poorly understood. We used the whole-cell patch-clamp technique to show that the agonists of the respective receptors, phenylephrine (PHE) and carbachol (CCh), activate cationic membrane currents in lymph node carcinoma of the prostate (LNCaP) human prostate cancer epithelial cells, which are not dependent on the filling status of intracellular IP3-sensitive Ca2+ stores, but directly gated by diacylglycerol (DAG), as evidenced by the ability of its membrane permeable analogue, OAG, to mimic the effects of the agonists. The underlying cationic channels are characterized by the weak field-strength Eisenman IV permeability sequence for monovalent cations (PK(25) > PCs(4.6) > PLi(1.4) > PNa(1.0)), and the following permeability sequence for divalent cations: PCa(1.0) > PMg(0.74) > PBa(0.6) > PSr(0.36) > PMn(0.3). They are 4.3 times more permeable to Ca2+ than Na+ and more sensitive to the inhibitor 2-APB than SK&F 96365. RT-PCR analysis shows that DAG-gated members of the transient receptor potential (TRP) channel family, including TRPC1 and TRPC3, are present in LNCaP cells. We conclude that, in prostate cancer epithelial cells, alpha1-ARs and m1-AChRs are functionally coupled to Ca2+-permeable DAG-gated cationic channels, for which TRPC1 and TRPC3 are the most likely candidates.

Direct modulation of volume-regulated anion channels by Ca(2+) chelating agents.

Ca(2+) chelating agents are widely used in biological research for Ca(2+) buffering. Here we report that BAPTA, EDTA and HEDTA produce fast, reversible, voltage-dependent inhibition of swelling-activated Cl(-) current (I(Cl,swell)) in LNCaP prostate cancer epithelial cells that is unrelated to their Ca(2+) binding. BAPTA was the most effective (maximal blockade 67%, IC(50)=70 microM, at +100 mV) followed by EDTA and HEDTA. I(Cl,swell) blockade by EDTA was pH-dependent. BAPTA blocked I(Cl,swell) also in other cell types. We conclude that Ca(2+) chelating agents block I(Cl,swell) by acting directly on the underlying channel, and that the negative charge of the free chelator form is critical for the blockade.

Testosterone-mediated modulation of HERG blockade by proarrhythmic agents.

Diverse drugs from many therapeutic classes exert cardiotoxic side effects by inducing torsades de pointes (TdP), a life threatening cardiac arrhythmia, which often results from drug interaction with HERG (human ether-a-go-go related gene) encoded K(+) channels, that generate an I(Kr) component of the delayed rectifier cardiac K(+) current. Men are known to be at a lower risk for drug-induced TdP than women suggesting a role of sex steroid hormones, androgens and estrogens, in modulation of drug sensitivity of cardiac K(+) channels, particularly those encoded by HERG. Here by using neuroleptic agents haloperidol, pimozide, and fluspirilene, all of which can induce TdP, and a steroid hormone-sensitive system Xenopus oocytes for HERG channels expression we show that testosterone is able to reduce HERG-blocking potency of neuroleptics. Haloperidol, pimozide, and fluspirilene inhibited HERG current with IC(50) of 1.36, 1.74, and 2.34 microM, and maximal block of 73%, 76% and 65%, respectively. The action of these neuroleptics was voltage-dependent, most consistent with an open-channel blocking mechanism. Pretreatment of HERG-expressing oocytes with 1 microM testosterone increased the IC(50) values to 2.73, 2.08, and 5.04 microM, reduced the maximal block to 65%, 59%, and 64%, and strongly diminished voltage-dependence of the blockade. Testosterone treatment per se produced about a 35% reduction of HERG current compared with untreated oocytes. Our data suggest that androgens may protect against the arrhythmogenic actions of some cardiotoxic drugs.

Subtypes of low voltage-activated Ca2+ channels in laterodorsal thalamic neurons: possible localization and physiological roles.

The macroscopic, low-voltage-activated (LVA or T-type) Ca2+ current in isolated associative (or local-circuit) neurons from the laterodorsal thalamic nucleus of 14-17-day old rats was dissected into two components ("fast" and "slow"), corresponding to the activation of two LVA channel subtypes, based on the difference in the kinetics of inactivation and recovery from inactivation. The steady-state activation and inactivation properties of the channel subtypes endowed slow channels with a substantial window current, whereas fast channels had almost no such current. Fast channels were almost 2 times more sensitive to 30 microM nifedipine (78% inhibition), 10 microM flunarizine (92% inhibition) and 1 microM La3+ (87% inhibition), but about 1.8-fold less sensitive to 100 microM Ni2+ (32% inhibition) than slow channels (40%, 52%, 46% and 56% inhibition respectively). Both channels were almost equally sensitive to 100 microM amiloride (58% and 51% inhibition of fast and slow channels respectively). Comparison of the fast and slow LVA Ca2+ current amplitudes and densities between enzymatically isolated and intact (in brain slices) neurons suggest a predominant localization of the fast channels in soma and the proximal dendrites that remain intact during isolation procedure, whereas the slow channels are more evenly distributed with some preference to the distal areas. These data, together with our previous studies, support the notion of two LVA Ca2+ channel subtypes in associative thalamic neurons and suggest a role for the slow channels in providing the constant Ca2+ influx necessary for the outgrowth of the neurites and for the fast channels in the generation of low-threshold Ca2+ spikes and bursting activity.

Volume-regulated chloride conductance in the LNCaP human prostate cancer cell line.

Patch-clamp recordings were used to study ion currents induced by cell swelling caused by hypotonicity in human prostate cancer epithelial cells, LNCaP. The reversal potential of the swelling-evoked current suggested that Cl(-) was the primary charge carrier (termed I(Cl,swell)). The selectivity sequence of the underlying volume-regulated anion channels (VRACs) for different anions was Br(-) approximately I(-) > Cl(-) > F(-) > methanesulfonate >> glutamate, with relative permeability numbers of 1.26, 1.20, 1.0, 0.77, 0.49, and 0.036, respectively. The current-voltage patterns of the whole cell currents as well as single-channel currents showed moderate outward rectification. Unitary VRAC conductance was determined at 9.6 +/- 1.8 pS. Conventional Cl(-) channel blockers 5-nitro-2-(3-phenylpropylamino)benzoic acid (100 microM) and DIDS (100 microM) inhibited whole cell I(Cl,swell) in a voltage-dependent manner, with the block decreasing from 39.6 +/- 9.7% and 71.0 +/- 11. 0% at +50 mV to 26.2 +/- 7.2% and 14.5 +/- 6.6% at -100 mV, respectively. Verapamil (50 microM), a standard Ca(2+) antagonist and P-glycoprotein function inhibitor, depressed the current by a maximum of 15%. Protein tyrosine kinase inhibitors downregulated I(Cl,swell) (genistein with an IC(50) of 2.6 microM and lavendustin A by 60 +/- 14% at 1 microM). The protein tyrosine phosphatase inhibitor sodium orthovanadate (500 microM) stimulated I(Cl,swell) by 54 +/- 11%. We conclude that VRACs in human prostate cancer epithelial cells are modulated via protein tyrosine phosphorylation.

Store depletion and store-operated Ca2+ current in human prostate cancer LNCaP cells: involvement in apoptosis.

1. In the present study, we investigated the mechanisms involved in the induction of apoptosis by the Ca2+-ATPase inhibitor thapsigargin (TG), in androgen-sensitive human prostate cancer LNCaP cells. 2. Exposure of fura-2-loaded LNCaP cells to TG in the presence of extracellular calcium produced an increase in intracellular Ca2+, the first phase of which was associated with depletion of intracellular stores and the second one with consecutive extracellular Ca2+ entry through plasma membrane, store-operated Ca2+ channels (SOCs). 3. For the first time we have identified and characterized the SOC-mediated membrane current (Istore) in prostate cells using whole-cell, cell-attached, and perforated patch-clamp techniques, combined with fura-2 microspectrofluorimetric and Ca2+-imaging measurements. 4. Istore in LNCaP cells lacked voltage-dependent gating and displayed an inwardly rectifying current-voltage relationship. The unitary conductance of SOCs with 80 mM Ca2+ as a charge carrier was estimated at 3.2 +/- 0.4 pS. The channel has a high selectivity for Ca2+ over monovalent cations and is inhibited by Ni2+ (0.5-3 mM) and La3+ (1 microM). 5. Treatment of LNCaP cells with TG (0.1 microM) induced apoptosis as judged from morphological changes. Decreasing extracellular free Ca2+ to 200 nM or adding 0.5 mM Ni2+ enhanced TG-induced apoptosis. 6. The ability of TG to induce apoptosis was not reduced by loading the cells with intracellular Ca2+ chelator (BAPTA-AM). 7. These results indicate that in androgen-sensitive prostate cancer cells the depletion of intracellular Ca2+ stores may trigger apoptosis but that there is no requirement for the activation of store-activated Ca2+ current and sustained Ca2+ entry in induction and development of programmed cell death.

Divalent cation selectivity of the subtypes of low voltage-activated Ca2+ channels in thalamic neurons.

LVA Ca2+ current in isolated associative neurons from the laterodorsal thalamic nucleus of 14- to 17-day-old rats was dissected into two, 'fast' and 'slow', components based on the difference in the kinetics of inactivation. The selectivity of the channel responsible for the fast LVA current for Ca2+, Sr2+ and Ba2+ (I(Ca):I(Sr):I(Ba) = 1.0:1.23:0.94) as well as the shifts of the I-V produced by these ions were found to be almost identical to those observed for LVA channels in other preparations. The channel responsible for the slow LVA current showed selectivity more characteristic of HVA Ca2+ channels (I(Ca):I(Sr):I(Ba) = 1.0:2.5:3.4), although the ability of Ca2+, Sr2+ and Ba2+ to shift its voltage dependence remained the same as for the fast channel.

A novel molecular determinant for cAMP-dependent regulation of the frog heart Na+-Ca2+ exchanger.

Na+-Ca2+ exchanger is one of the major sarcolemmal Ca2+ transporters of cardiac myocytes. In frog ventricular myocytes the exchanger is regulated by isoproterenol via a beta-adrenoreceptor/adenylate-cyclase/cAMPdependent signaling pathway providing a molecular mechanism for the relaxant effect of the hormone. Here, we report on the presence of a novel exon of 27-base pair insertion, which generates a nucleotide binding motif (P-loop) in the frog cardiac Na+-Ca2+ exchanger. To examine the functional role of this motif, we constructed a full-length frog heart Na+-Ca2+ exchanger cDNA (fNCX1a) containing this exon. The functional expression of fNCX1a in oocytes showed characteristic voltage dependence, divalent (Ni2+, Cd2+) inhibition, and sensitivity to cAMP in a manner similar to that of native exchanger in frog myocytes. In oocytes expressing the dog heart NCX1 or the frog mutant (DeltafNCX1a) lacking the 9-amino acid exon, cAMP failed to regulate Na+-dependent Ca2+ uptake. We suggest that this motif is responsible for the observed cAMP-dependent functional differences between the frog and the mammalian hearts.

Expression of Ca2+ channels from rat brain with model phenylketonuria in Xenopus oocytes.

Ca2+ channels expressed in Xenopus oocytes using mRNA purified from the brain of the rats subjected to chronic treatment with l-phenylalanine in order to model conditions typical for the congenital disease called phenylketonuria (PKU) were studied using double microelectrode technique. The amplitude of Ca2+ channel currents (IBa, 40 mM Ba2+ as a charge carrier) directed in the oocytes by mRNA from the brain of the animals with model PKU was significantly smaller compared to the control animals (145+/-23 nA vs. 270+/-38 nA, p<0.025) while the voltage-dependence of both currents was similar and typical for that of high voltage-activated (HVA) Ca2+ channels. No evidence for the expression of low voltage-activated Ca2+ channels were found. The decrease of the overall HVA Ba2+ current under model PKU occurred primarily at the expense of the decaying, omega-conotoxin-sensitive component which accounted for about 64% of the total current amplitude in control, and apparently was associated with the activity of the expressed N-type Ca2+ channels. omega-Aga-IVA-sensitive, P/Q component of IBa that contributed not more than 10% to the total current in control showed no change under PKU conditions. In addition to the decreased amplitude, Ba2+ current from model PKU animals showed accelerated run-down during prolonged recording (50%/h compared to 15%/h in control). Our data suggest that hyperphenylalaninemic conditions affect the expression of preferentially N-type Ca2+ channels via the reduction of their specific mRNA content as well as influence the type and manner of channels regulation. The underexpression of N-type Ca2+ channels is consistent with the decrease in the overall number of synaptic contacts during PKU and may be one of the factors contributing to the severe damage of the brain function.