Regulation of expression of cholinergic neuronal phenotypic markers in neuroblastoma LA-N-2

A novel in vitro assay model developed to measure both extracellular and intracellular acetylcholine levels for screening cholinergic agents

Background

Cholinergic neurons utilize choline (Ch) to synthetize acetylcholine (ACh) and contain a high-affinity Ch transporter, Ch acetyltransferase (ChAT), ACh receptors, and acetylcholinesterase (AChE). As the depletion or malfunction of each component of the cholinergic system has been reported in patients with dementia, many studies have sought to evaluate whether treatment candidates affect each of the cholinergic components. The associated changes in the cholinergic components may be reflected by intra- or extra-cellular ACh levels, with an increase in extracellular ACh levels occurring following AChE inhibition. We hypothesized that increases in intracellular ACh levels can be more sensitively detected than those in extracellular ACh levels, thereby capturing subtle effects in the cholinergic components other than AChE. The objective of this study was to test this hypothesis.

Methods

We developed an in vitro model to measure both extracellular and intracellular ACh levels using the human cholinergic neuroblastoma cell line, LA-N-2, which have been reported to express Ch transporter, ChAT, muscarinic ACh receptor (mAChR), and AChE. With this model, we evaluated several drug compounds and food constituents reported to improve cholinergic function through various mechanisms. In addition, we conducted western blotting to identify the subtype of mAChR that is expressed on the cell line.

Results

Our cell-based assay system was capable of detecting increases in extracellular ACh levels induced by an AChE inhibitor at relatively high doses, as well as increases in intracellular ACh levels following the administration of lower AChE-inhibitor doses and an mAChR agonist. Moreover, increases in intracellular ACh levels were observed even after treatment with food constituents that have different mechanisms of action, such as Ch provision and ChAT activation. In addition, we revealed that LA-N-2 cells expressed mAChR M2.

Conclusion

The findings support our hypothesis and indicate that the developed assay model can broadly screen compounds from drugs to food ingredients, with varying strengths and mechanisms of action, to develop treatments for ACh-relevant phenomena, including dementia and aging-related cognitive decline.

Development of a model system for neuronal dysfunction in Fabry disease

Fabry disease is a glycosphingolipid storage disorder that is caused by a genetic deficiency of the enzyme alpha-galactosidase A (AGA, EC 3.2.1.22). It is a multisystem disease that affects the vascular, cardiac, renal, and nervous systems. One of the hallmarks of this disorder is neuropathic pain and sympathetic and parasympathetic nervous dysfunction. The exact mechanism by which changes in AGA activity result in change in neuronal function is not clear, partly due to of a lack of relevant model systems. In this study, we report the development of an in vitro model system to study neuronal dysfunction in Fabry disease by using short-hairpin RNA to create a stable knock-down of AGA in the human cholinergic neuronal cell line, LA-N-2. We show that gene-silenced cells show specifically reduced AGA activity and store globotriaosylceramide. In gene-silenced cells, release of the neurotransmitter acetylcholine is significantly reduced, demonstrating that this model may be used to study specific neuronal functions such as neurotransmitter release in Fabry disease.

Enhanced ubiquitination and proteasomal degradation of catalytically deficient human choline acetyltransferase mutants

Choline acetyltransferase (ChAT) is essential for cholinergic neuron function as it mediates synthesis of the neurotransmitter acetylcholine. ChAT mutations have been linked to the neuromuscular disorder congenital myasthenic syndrome (CMS). One CMS-related ChAT mutation, V18M, reduces enzyme activity and cellular protein levels, and is positioned within a highly conserved proline-rich motif with the sequence 14 PKLPVPP20 . We demonstrate that N-terminal truncation that includes this proline-rich motif, as well as mutation of prolines-17/19 together to alanine (P17A/P19A), dramatically reduces ChAT steady-state protein levels and cellular activity when expressed in cholinergic SN56 neural cells. The in vitro activity of bacterially expressed recombinant P17A/P19A-ChAT is also reduced, although this is not caused by changes in protein secondary structure or thermal stability. Treatment of SN56 cells with the proteasome inhibitor MG132 increases cellular P17A/P19A-ChAT steady-state protein levels, and by immunoprecipitation we found that ChAT is ubiquitinated and that polyubiquitination of P17A/P19A-ChAT is increased compared to wild-type (WT) ChAT. Using a novel fluorescent-biorthogonal pulse-chase protocol in SN56 cells, we determined that the protein half-life of P17A/P19A-ChAT (2.2 h) is substantially reduced compared to WT-ChAT (19.7 h). Lastly, we show that two CMS-related ChAT mutants (V18M and A513T) have enhanced ubiquitination, and that treatment with MG132 can partially restore both the steady-state protein levels as well as cellular activity of some CMS-mutant ChAT. These results identify a novel mechanism for regulation of ChAT through the ubiquitin-proteasome system that is influenced by the conserved N-terminal proline-rich motif of ChAT and may be implicated in CMS pathology. Choline acetyltransferase (ChAT) synthesizes acetylcholine in cholinergic neurons. In this study we find that steady-state protein levels of human 69-kDa ChAT are regulated by the ubiquitin-proteasome system. Mutation of a highly conserved N-terminal proline-rich motif in human 69-kDa ChAT reduces both cellular ChAT protein levels, through enhanced ubiquitination and proteasomal degradation, and enzyme activity. Ubiquitination of catalytically deficient congenital myasthenic syndrome (CMS)-mutant ChAT is increased in cells, and importantly proteasome inhibition partially restores steady-state protein levels as well as cellular activity of some CMS-mutant ChAT proteins.

Substrate binding and catalytic mechanism of human choline acetyltransferase

Choline acetyltransferase (ChAT) catalyzes the synthesis of the neurotransmitter acetylcholine from choline and acetyl-CoA, and its presence is a defining feature of cholinergic neurons. We report the structure of human ChAT to a resolution of 2.2 A along with structures for binary complexes of ChAT with choline, CoA, and a nonhydrolyzable acetyl-CoA analogue, S-(2-oxopropyl)-CoA. The ChAT-choline complex shows which features of choline are important for binding and explains how modifications of the choline trimethylammonium group can be tolerated by the enzyme. A detailed model of the ternary Michaelis complex fully supports the direct transfer of the acetyl group from acetyl-CoA to choline through a mechanism similar to that seen in the serine hydrolases for the formation of an acyl-enzyme intermediate. Domain movements accompany CoA binding, and a surface loop, which is disordered in the unliganded enzyme, becomes localized and binds directly to the phosphates of CoA, stabilizing the complex. Interactions between this surface loop and CoA may function to lower the KM for CoA and could be important for phosphorylation-dependent regulation of ChAT activity.

Two methods for large-scale purification of recombinant human choline acetyltransferase

Choline acetyltransferase (ChAT) catalyzes the transfer of an acetyl group from acetyl-CoA to choline to produce the neurotransmitter acetylcholine (ACh). We have produced large quantities of pure human ChAT using two different bacterial expression systems. In the first, ChAT is fused to a chitin-binding domain via a self-cleavable linker allowing the release of ChAT without the use of proteases. In the second, ChAT is fused to a hexahistidine (His6) tag at the N-terminus with a linker incorporating a TEV protease cleavage site. In both cases, pure ChAT was produced that has a final specific activity of approximately 50 micromol ACh/min/mg and is suitable for structural characterization. Analysis of purified ChAT by Western blots and mass spectrometry revealed that the C-terminal 15 amino acids were slowly removed by endogenous proteolytic activity, to produce a stable 615 residue protein. Furthermore, we show that purified recombinant human ChAT is highly prone to oxidation, leading to the formation of covalent dimers and/or a loss of catalytic activity. Kinetic parameters of our purified proteins were obtained and, when compared to previously published constants for human placental ChAT, we found that recombinant human ChAT displays lower values for Michaelis and inhibition constants for ACh, which may be due to the complete absence of post-translational modifications.

Differential expression and regulation of the high-affinity choline transporter CHT1 and choline acetyltransferase in neurons of superior cervical ganglia

Previous studies revealed that leukemia inhibitory factor (LIF) and retinoic acid (RA) induce a noradrenergic to cholinergic switch in cultured sympathetic neurons of superior cervical ganglia (SCG) by up-regulating the coordinate expression of choline acetyltransferase (ChAT) and the vesicular acetylcholine transporter. Here, we examined the effect of both factors on high-affinity choline uptake (HACU) and on expression of the high-affinity choline transporter CHT1. We found that HACU and CHT1-mRNA levels are up-regulated by LIF and down-regulated by RA in these neurons. Thus, in contrast to LIF, RA differentially regulates the expression of the presynaptic cholinergic proteins. Moreover, we showed that untreated SCG neurons express HACU and CHT1-mRNAs at much higher levels than ChAT activity and transcripts. In intact SCG, CHT1-mRNAs are abundant and synthesized by the noradrenergic neurons themselves. This study provides the first example of CHT1 expression in neurons which do not use acetylcholine as neurotransmitter.

Protein Kinase C Isoforms Differentially Phosphorylate Human Choline Acetyltransferase Regulating Its Catalytic Activity

Choline acetyltransferase (ChAT) synthesizes acetylcholine in cholinergic neurons; regulation of its activity or response to physiological stimuli is poorly understood. We show that ChAT is differentially phosphorylated by protein kinase C (PKC) isoforms on four serines (Ser-440, Ser-346, Ser-347, and Ser-476) and one threonine (Thr-255). This phosphorylation is hierarchical, with phosphorylation at Ser-476 required for phosphorylation at other serines. Phosphorylation at some, but not all, sites regulates basal catalysis and activation. Ser-476 with Ser-440 and Ser-346/347 maintains basal ChAT activity. Ser-440 is targeted by Arg-442 for phosphorylation by PKC. Arg-442 is mutated spontaneously (R442H) in congenital myasthenic syndrome, rendering ChAT inactive and causing neuromuscular failure. This mutation eliminates phosphorylation of Ser-440, and Arg-442, not phosphorylation of Ser-440, appears primarily responsible for ChAT activity, with Ser-440 phosphorylation modulating catalysis. Finally, basal ChAT phosphorylation in neurons is mediated predominantly by PKC at Ser-476, with PKC activation increasing phosphorylation at Ser-440 and enhancing ChAT activity.

Phosphorylation of 69-kDa choline acetyltransferase at threonine 456 in response to amyloid-beta peptide 1-42

Choline acetyltransferase synthesizes acetylcholine in cholinergic neurons. In the brain, these neurons are especially vulnerable to effects of beta-amyloid (A beta) peptides. Choline acetyltransferase is a substrate for several protein kinases. In the present study, we demonstrate that short term exposure of IMR32 neuroblastoma cells expressing human choline acetyltransferase to A beta-(1-42) changes phosphorylation of the enzyme, resulting in increased activity and alterations in its interaction with other cellular proteins. Using mass spectrometry, we identified threonine 456 as a new phosphorylation site in choline acetyltransferase from A beta-(1-42)-treated cells and in purified recombinant ChAT phosphorylated in vitro by calcium/calmodulin-dependent protein kinase II (CaM kinase II). Whereas phosphorylation of choline acetyltransferase by protein kinase C alone caused a 2-fold increase in enzyme activity, phosphorylation by CaM kinase II alone did not alter enzyme activity. A 3-fold increase in choline acetyltransferase activity was found with coordinate phosphorylation of threonine 456 by CaM kinase II and phosphorylation of serine 440 by protein kinase C. This phosphorylation combination was observed in choline acetyltransferase from A beta-(1-42)-treated cells. Treatment of cells with A beta-(1-42) resulted in two phases of activation of choline acetyltransferase, the first within 30 min and associated with phosphorylation by protein kinase C and the second by 10 h and associated with phosphorylation by both CaM kinase II and protein kinase C. We also show that choline acetyltransferase from A beta-(1-42)-treated cells co-immunoprecipitates with valosin-containing protein, and mutation of threonine 456 to alanine abolished the A beta-(1-42)-induced effects. These studies demonstrate that A beta-(1-42) can acutely regulate the function of choline acetyltransferase, thus potentially altering cholinergic neurotransmission.

Functional characterization of phosphorylation of 69-kDa human choline acetyltransferase at serine 440 by protein kinase C

Choline acetyltransferase, the enzyme that synthesizes the transmitter acetylcholine in cholinergic neurons, is a substrate for protein kinase C. In the present study, we used mass spectrometry to identify serine 440 in recombinant human 69-kDa choline acetyltransferase as a protein kinase C phosphorylation site, and site-directed mutagenesis to determine that phosphorylation of this residue is involved in regulation of the enzyme's catalytic activity and binding to subcellular membranes. Incubation of HEK293 cells stably expressing wild-type 69-kDa choline acetyltransferase with the protein kinase C activator phorbol 12-myristate 13-acetate showed time- and dose-related increases in specific activity of the enzyme; in control and phorbol ester-treated cells, the enzyme was distributed predominantly in cytoplasm (about 88%) with the remainder (about 12%) bound to cellular membranes. Mutation of serine 440 to alanine resulted in localization of the enzyme entirely in cytoplasm, and this was unchanged by phorbol ester treatment. Furthermore, activation of mutant enzyme in phorbol ester-treated HEK293 cells was about 50% that observed for wild-type enzyme. Incubation of immunoaffinity purified wild-type and mutant choline acetyltransferase with protein kinase C under phosphorylating conditions led to incorporation of [(32)P]phosphate, with radiolabeling of mutant enzyme being about one-half that of wild-type, indicating that another residue is phosphorylated by protein kinase C. Acetylcholine synthesis in HEK293 cells expressing wild-type choline acetyltransferase, but not mutant enzyme, was increased by about 17% by phorbol ester treatment.

Cholinergic differentiation triggered by blocking cell proliferation and treatment with all-trans-retinoic acid

This study determined whether the effect of all-trans-retinoic acid (t-RA) on markers of cholinergic differentiation in a murine septal cell line, SN56.B5.G4, differed depending upon the cell's proliferative status. To develop a model of non-proliferating cells, aphidicolin, a DNA alpha-polymerase inhibitor, was used. Cessation of proliferation by aphidicolin increased intracellular choline and acetylcholine (ACh) levels in the absence of change to choline acetyltransferase (ChAT) activity and mRNA and vesicular ACh transporter (VAChT) mRNA. Importantly, the response to t-RA differed depending upon proliferative status. Consistent with previous reports, t-RA increased ChAT and VAChT mRNA, ChAT activity and intracellular ACh levels in proliferating SN56 cells with no effect on intracellular choline levels. When cells were treated with t-RA while undergoing proliferative arrest, an additive effect of combined treatment was observed on ACh levels; nevertheless, this was only accompanied by an increase in choline levels, VAChT and ChAT mRNAs, but not ChAT activity. Indeed, aphidicolin treatment completely suppressed the t-RA-induced increase in ChAT activity observed in proliferating cells. To explore the response to t-RA in post-mitotic cells, a sequential treatment of aphidicolin and t-RA was employed. t-RA treatment was ineffective in increasing ACh and choline levels, over and above that observed with the aphidicolin treatment alone. Comparable to the combined treatment, sequential treatment lead to an increase in ChAT mRNA without any increase in ChAT activity. In conclusion, both the magnitude and the mechanism(s) of action whereby t-RA enhances the cholinergic phenotype of SN56 cells is dependent upon the cell's proliferative status.

Expression, purification and characterization of recombinant human choline acetyltransferase: phosphorylation of the enzyme regulates catalytic activity

Choline acetyltransferase synthesizes acetylcholine in cholinergic neurons and, in humans, may be produced in 82- and 69-kDa forms. In this study, recombinant choline acetyltransferase from baculovirus and bacterial expression systems was used to identify protein isoforms by two-dimensional SDS/PAGE and as substrate for protein kinases. Whereas hexa-histidine-tagged 82- and 69-kDa enzymes did not resolve as individual isoforms on two-dimensional gels, separation of wild-type choline acetyltransferase expressed in insect cells revealed at least nine isoforms for the 69-kDa enzyme and at least six isoforms for the 82-kDa enzyme. Non-phosphorylated wild-type choline acetyltransferase expressed in Escherichia coli yielded six (69 kDa) and four isoforms (82 kDa) respectively. Immunofluorescent labelling of insect cells expressing enzyme showed differential subcellular localization with the 69-kDa enzyme localized adjacent to plasma membrane and the 82-kDa enzyme being cytoplasmic at 24 h. By 64 h, the 69-kDa form was in cytoplasm and the 82-kDa form was only present in nucleus. Studies in vitro showed that recombinant 69-kDa enzyme was a substrate for protein kinase C (PKC), casein kinase II (CK2) and alpha-calcium/calmodulin-dependent protein kinase II (alpha-CaM kinase), but not for cAMP-dependent protein kinase (PKA); phosphorylation by PKC and CK2 enhanced enzyme activity. The 82-kDa enzyme was a substrate for PKC and CK2 but not for PKA or alpha-CaM kinase, with only PKC yielding increased enzyme activity. Dephosphorylation of both forms of enzyme by alkaline phosphatase decreased enzymic activity. These studies are of functional significance as they report for the first time that phosphorylation enhances choline acetyltransferase catalytic activity.

Nuclear localization of the 82-kDa form of human choline acetyltransferase

Choline acetyltransferase is the enzyme catalyzing synthesis of the neurotransmitter acetylcholine in cholinergic neurons. In human, transcripts encoding two forms of the enzyme with apparent molecular masses of 69 and 82 kDa are found in brain and spinal cord; the 82-kDa form differs from the 69-kDa enzyme only in terms of a 118-amino acid extension on its amino terminus. Using green fluorescent protein-tagged choline acetyltransferase, we show that the 82-kDa enzyme is targeted to nuclei of cells, whereas the 69-kDa protein is found in cytoplasm. Expression of site-directed and deletion mutants of the 82-kDa isoform reveals that the extended amino terminus contains a nuclear localization signal in the first nine amino acids which targets the protein to nucleus. This represents the first report of a neurotransmitter-synthesizing enzyme that is localized to the cell nucleus.

AF64A-induced changes in N-myc expression in the LA-N-2 human neuroblastoma cell line are modulated by choline and hemicholinium-3

Due to AF64A's structural similarity to choline, AF64A can selectively affect cholinergic neurons, which possess a high affinity choline transport system for acetylcholine synthesis. The mechanism by which AF64A selectively produces its cytotoxic effect is unknown. However, based on previous studies that demonstrate that DNA lesions produced by AF64A caused premature termination of N-myc transcription in vitro, it is possible that AF64A may affect the transcription of genes necessary for developmental maintenance in cholinergic cells. Using the LA-N-2 cells as a model to study the effects of AF64A in a purely cholinergic system, we investigated the effects of AF64A on the expression of the N-myc gene and monitored cell growth. AF64A produced a maximal decrease in N-myc mRNA with a return to steady state levels at later time points. Moreover, a decrease in cell numbers in AF64A-treated cells was observed, and these cells did not double in number at their respective doubling time as compared to control. In other studies, a causal relationship between a reduction in N-myc and an inhibition of cell growth and replication has been reported. While these studies do not allow us to conclude that AF64A is specific for N-myc, the data do, nevertheless, suggest that AF64A affects cell growth and/or replication by down-regulating the expression of N-myc which is involved in differentiation and cell growth in neuroblastomas. Presence of choline or hemicholinium-3 prevented the AF64A-induced decrease of N-myc levels by competing with, or inhibiting the choline transport mechanism by which AF64A enters the cell, respectively.

Differentiation agents enhance cholinergic characteristics of LA-N-2 human neuroblastoma cells

LA-N-2, a cell line derived from a human peripheral neuroblastoma, has a partially cholinergic phenotype and is a potential in vitro model of cholinergic neurons. The object of this study was to enhance the cholinergic phenotype of these cells with differentiation agents to improve the cell line's usefulness as a convenient model of cholinergic function. I treated cells in the presence of serum with 10 microM 5-azacytidine, 2.5 microM bromodeoxyuridine, 2 nM ciliary neurotrophic factor, 1 mM dibutyryl cAMP, 0.25 nM leukemia inhibitory factor and/or 3.8 nM nerve growth factor, N-2 supplement (without serum), or 10 microM retinoic acid for 9-14 days. Treated cells were loaded with [3H]choline for 30 min at 37 degrees and washed. The amounts of cellular and released (5 min, room temperature), labeled and unlabeled acetylcholine and choline were determined by HPLC. None of the differentiation agents induced Ca(2+)-dependent release of [3H]acetylcholine, but 5-azacytidine, dibutyryl cAMP, N-2, and retinoic acid increased Ca(2+)-independent release that was specific for acetylcholine. In addition, 5-azacytidine, bromodeoxyuridine, leukemia inhibitory factor, and N-2 substantially increased [3H]acetylcholine levels, and these increases correlated highly with increases in total acetylcholine levels. Overall, LA-N-2 cells should prove to be a good model for studying cholinergic function.

Alkylphosphocholines inhibit choline uptake and phosphatidylcholine biosynthesis in rat sympathetic neurons and impair axonal extension

At least 50% of the major axonal membrane lipid, phosphatidylcholine, of rat sympathetic neurons is synthesized in situ in axons [Posse de Chaves, Vance, Campenot and Vance (1995) J. Cell Biol. 128, 913-918]. In the same study we reported that, in a choline-deficient model for neuron growth, phosphatidylcholine synthesis in cell bodies is neither necessary nor sufficient for growth of distal axons. Rather, the local synthesis of phosphatidylcholine in distal axons is required for normal axon growth. We have now used three alkylphosphocholines (hexadecylphosphocholine, dodecylphosphocholine and octadecylphosphocholine) as inhibitors of PtdCho biosynthesis in a compartmented model for culture of rat sympathetic neurons. The experiments reveal that alkylphosphocholines decrease the uptake of choline into these neurons and inhibit PtdCho synthesis, but not via an effect on the activity of the enzyme CTP: phosphocholine cytidylyltransferase. We also show that when the distal axons, but not the cell bodies, are exposed to alkylphosphocholines, axonal elongation is inhibited, which is consistent with the hypothesis that phosphatidylcholine synthesis in axons, but not in cell bodies, is required for axonal elongation. The inhibitory effect of alkylphosphocholines on axon growth is most likely not mediated via a decrease in the activity of protein kinase C, since when this enzyme activity is down-regulated by treatment of the cells with phorbol ester, the alkylphosphocholines retain their ability to inhibit axonal growth.

AF64A-induced cytotoxicity and changes in choline acetyltransferase activity in the LA-N-2 neuroblastoma cell line are modulated by choline and hemicholinium-3

The cholinergic neurotoxin AF64A (ethylcholine aziridinium) has been used to selectively destroy the cholinergic system. Due to its structural similarity to choline, this compound may be selectively taken up by the cholinergic terminal via the high-affinity choline transport (HAChT) system to produce persistent and selective cholinergic deficits. The mechanism by which it exerts its cholinotoxicity remains to be elucidated. We have examined the effects of AF64A in the human neuroblastoma cell line, LA-N-2, which has an intact sodium-coupled choline uptake system, and is capable of synthesizing acetylcholine (ACh). AF64A (25, 50 and 100 microM) produced dose-dependent increases in cell kill as measured by colony formation assay. The addition of increasing concentrations (10(-5), 10(-4) and 10(-3) M) of choline and hemicholinium-3 (HC-3) protected the cells from the cytotoxic effects of AF64A. At the same doses, AF64A also decreased choline acetyltransferase (ChAT) activity. In the presence of the highest concentration of choline or HC-3 (10(-3) M) which produced complete protection against AF64A's cytotoxicity in the colony formation assay, ChAT activity was restored to control values. These results demonstrate that agents that utilize (i.e., choline) or inhibit (i.e., HC-3) the choline uptake system prevented AF64A-induced cytotoxicity and decreases in ChAT activity, in a manner similar to that which has been observed in chick and rat primary cholinergic cultures in vitro. The LA-N-2 neuroblastoma cell line thus serves well as an in vitro model of the cholinergic neuron and provides a useful system to study the mode of cholinotoxicity induced by AF64A.

Effect of cellular differentiation on nucleoside transport in human neuroblastoma cells

The nucleoside transport characteristics of undifferentiated and differentiated LA-N-2 human neuroblastoma cells were compared through measurement of the cellular accumulation of [3H]formycin B in the absence and presence of specific nucleoside transport blockers such as dipyridamole and nitrobenzylthioinosine (NBMPR). [3H]NBMPR was also used as a high affinity probe to obtain an estimate of the number of NBMPR-sensitive nucleoside transport proteins. Undifferentiated LA-N-2 cells accumulated [3H]formycin B (25 microM) via a NBMPR/dipyridamole sensitive, Na(+)-independent, nucleoside transport system (Vi = 1.52 pmol/microliters/s; maximum intracellular concentration = 45 pmol/microliters cell water). The undifferentiated cells also had a high density of site-specific [3H]NBMPR binding sites (135,000 sites/cell; KD = 0.4 nM). When cell differentiation was induced by exposure to a serum-free defined medium, the initial rate of transporter-mediated [3H]formycin B uptake increased to 1.92 pmol/microliters/s, and the steady-state intracellular concentration of [3H]formycin B also increased significantly to 73 pmol/microliters. However, there was no concomitant change in the number of [3H]NBMPR binding sites, and the additional uptake was not Na(+)-dependent. This enhanced uptake in the differentiated cells appeared to be due, in part, to an increased functional expression of a NBMPR-resistant form of facilitated nucleoside transporter. Approximately 18% of the transporter-mediated uptake in the differentiated cells was resistant to inhibition by NBMPR at concentrations that blocked transport completely in the undifferentiated cells. This cell model may prove useful for basic studies on regulation of nucleoside transporter subtype expression in neural tissues, and for evaluation of the efficacy and potential host toxicity of cytotoxic nucleoside analogues (+/- specific transport blockers) in the treatment of neuroblastoma.

Modulation of neurite promoting proteoglycans by neuronal differentiation

A human cell line committed to neuronal lineage was used to examine the influence of differentiation on proteoglycan synthesis and function. Where the LA-N-2 cells were stimulated to differentiate towards a phenotype of cholinergic neurons, proteoglycans of the heparan sulphate class increased relative to chondroitin sulphate proteoglycans and displayed more homogeneously shorter glycosaminoglycan chains with increasing degrees of sulphation. The changes were accompanied by increasing potency of the heparan sulphate proteoglycans in neurite growth-promoting activity when immobilized on a laminin substrate. These studies begin to address the role of activity-independent growth and differentiation on the synthesis and release by neurons of neurite growth-promoting proteoglycans. The observations have implications for understanding the role of proteoglycan overexpression and the production of dystrophic neurites in Alzheimer disease.