Role of founder cell deficit and delayed neuronogenesis in microencephaly of the trisomy 16 mouse.

Development of the neocortex of the trisomy 16 (Ts16) mouse, an animal model of Down syndrome (DS), is characterized by a transient delay in the radial expansion of the cortical wall and a persistent reduction in cortical volume. Here we show that at each cell cycle during neuronogenesis, a smaller proportion of Ts16 progenitors exit the cell cycle than do control, euploid progenitors. In addition, the cell cycle duration was found to be longer in Ts16 than in euploid progenitors, the Ts16 growth fraction was reduced, and an increase in apoptosis was observed in both proliferative and postmitotic zones of the developing Ts16 neocortical wall. Incorporation of these changes into a model of neuronogenesis indicates that they are sufficient to account for the observed delay in radial expansion. In addition, the number of neocortical founder cells, i.e., precursors present just before neuronogenesis begins, is reduced by 26% in Ts16 mice, leading to a reduction in overall cortical size at the end of Ts16 neuronogenesis. Thus, altered proliferative characteristics during Ts16 neuronogenesis result in a delay in the generation of neocortical neurons, whereas the founder cell deficit leads to a proportional reduction in the overall number of neurons. Such prenatal perturbations in either the timing of neuron generation or the final number of neurons produced may lead to significant neocortical abnormalities such as those found in DS.

Organotypic slice cultures for analysis of proliferation, cell death, and migration in the embryonic neocortex.

Dynamic cellular interactions during neocortical neurogenesis are critical for proper cortical development, providing both trophic and tropic support. Although cell proliferation and programmed cell death have been characterized in dissociated primary cell cultures, many in vivo processes during cortical neurogenesis depend on cell-cell interactions and therefore on the three-dimensional environment of the proliferating neuroblasts and their progeny. Here we describe a murine organotypic neocortical slice preparation that retains major morphological and functional in vivo characteristics of the developing neocortex and is viable (exhibits very low levels of cell death) for up to three days. Moreover, this slice preparation is amenable to direct experimental manipulation of potential diffusible regulators of neurogenesis. Using a variety of biochemical and physiological methods including time-lapse and quantitative confocal microscopy, we demonstrate that this system can be used effectively to investigate cellular mechanisms important for brain growth and maturation, including neurogenesis, apoptosis, and neuronal migration.

Neuronal apoptosis in mouse trisomy 16: mediation by caspases.

Hippocampal neurons from the trisomy 16 (Ts16) mouse, a potential animal model of Down's syndrome (trisomy 21) and neurodegenerative disorders such as Alzheimer's disease (AD), die at an accelerated rate in vitro. Here, we present evidence that the accelerated neuronal death in Ts16 occurs by apoptosis, as has been reported for neurons in AD. First, the nuclei of dying Ts16 neurons are pyknotic and undergo DNA fragmentation, as revealed by terminal transferase-mediated dUTP nick end-labeling. Second, the accelerated death of Ts16 neurons is prevented by inhibitors of the caspase family of proteases, which are thought to act at a late, obligatory step in the apoptosis pathway. In the presence of maximally effective concentrations of caspase inhibitors, Ts16 neuron survival was indistinguishable from that of control neurons. These results suggest that overexpression of one or more genes on mouse chromosome 16 leads to caspase-mediated apoptosis in Ts16 neurons.

MAP5 expression in proliferating neuroblasts.

MAP5, a microtubule-associated protein present in immature neurons, was found to be expressed in the embryonic mouse telencephalic ventricular zone (VZ). Since the VZ contains proliferating neuroblasts, the source of most of the neurons of the cerebral cortex, this observation raised the possibility that MAP5 is expressed by proliferating neuronal progenitors. MAP5-positive mitotic cells were observed at the ventricular surface, a finding consistent with progenitors expressing MAP5 prior to their last division. This possibility was investigated using dissociated, cortical cells in vitro by measuring the expression of MAP5 and the neuroepithelial marker nestin, together with the incorporation of bromodeoxyuridine (BrdU), a thymidine analogue that labels the DNA of proliferating cells in the S-phase of the cell cycle. All of the proliferating cells expressed nestin. A population of MAP5-positive cells was also found to incorporate BrdU; some cells expressed MAP5 within 30 min of BrdU labeling. The results suggest that uncommitted neuroblasts express only nestin, with expression of MAP5 occurring near the time the cell commits to become a postmitotic neuron after the next cell division. Subsequently, cells expressing both MAP5 and nestin leave the cell cycle and exit the VZ, lose nestin, and differentiate into neurons. Since some cells expressed MAP5 during or shortly after S-phase but before mitosis, MAP5 may be the earliest marker to identify neuronal progenitors that will become post-mitotic neurons following their next mitosis.

Impaired spatial working and reference memory in segmental trisomy (Ts65Dn) mice.

To evaluate the cognitive phenotype of the segmental trisomy 16 (Ts65Dn) mouse, a model of Down Syndrome (DS, trisomy 21), we assessed spatial working and reference memory using a 12-arm radial maze (RAM). Ts65Dn mice made a greater number of reference memory errors across trials compared to control mice. Both genotypes showed improvement across trials, although improvement was slower in Ts65Dn mice. Ts65Dn mice also made a greater number of working memory errors on the RAM, and in contrast to control mice, did not improve across trials, always performing at near-chance levels. These results provide evidence for both spatial working and reference memory deficits in Ts65Dn mice, characteristics of cognitive dysfunction.

Abnormal calcium homeostasis in astrocytes from the trisomy 16 mouse.

The regulation of intracellular Ca2+ was investigated in cultured astrocytes from the trisomy 16 (Ts16) mouse, an animal model for Down syndrome and Alzheimer's disease (AD). The cytoplasmic ionized Ca2+ concentration ([Ca2+]cyt) was determined using digital imaging of fura-2-loaded cells. The relative Ca2+ content of internal endoplasmic reticulum (ER) stores was estimated from the magnitude of the transient increase in [Ca2+]cyt induced by cyclopiazonic acid (CPA), an inhibitor of Ca2+ sequestration into ER stores. At rest, the average [Ca2+]cyt was 140 nM in euploid (normal) astrocytes, but over twice as high, 320 nM, in Ts16 cells. In the absence of extracellular Ca2+, CPA induced a transient increase in [Ca2+]cyt to over 1200 nM in Ts16 astrocytes as compared to only 500 nM in euploid cells, indicating an increased amount of Ca2+ in the Ts16 astrocyte ER. In contrast to euploid astrocytes, both resting [Ca2+]cyt and the amount of Ca2+ in the ER stores varied widely among individual Ts16 astrocytes. These results show that Ts16 produces a dysregulation of Ca2+ homeostasis leading to increased cytoplasmic and stored Ca2+. Since increases in [Ca2+]cyt have been implicated in the etiology of neurodegenerative diseases, including AD, this finding of abnormal Ca2+ homeostasis in a genetic model of human neurological disorders suggests that Ca2+ dysregulation may be a common feature underlying neurodegenerative processes.

Spatial memory deficits in segmental trisomic Ts65Dn mice.

Spatial memory was assessed in the segmental trisomic 16 mouse (Ts65Dn), a potential model for Down syndrome (DS), using the 12-arm radial maze (RAM). Ts65Dn mice have a portion of mouse chromosome 16 syntenic to the distal end of human chromosome 21 triplicated. On each of 8 daily trials of the RAM, Ts65Dn mice made fewer correct choices than control mice and performed at or near chance levels, indicating a deficit in spatial working memory. On trials 9 and 10, Ts65Dn mice performed as well as control mice on the initial 12 choices, but required a greater number of choices to complete the RAM. The improved performance of Ts65Dn mice on trials 9 and 10 was lost when the animals were retested after a 50-day retention period, suggesting that long-term memory is also defective. These results are not likely explained by differences in either response bias or perceptual discrimination. Ts65Dn and control mice displayed comparable levels of performance in spontaneous alternation in a T-maze, demonstrating that simple spatial memory was not impaired. In the elevated plus maze, Ts65Dn mice did not display higher anxiety levels which could affect their performance in the RAM. In fact, Ts65Dn mice visited open arms on the elevated plus maze more frequently and spent more time on open arms than did control mice. Taken together, these results provide evidence for short- and long-term spatial memory deficits in Ts65Dn mice.

Expression of glial antigens in mouse astrocytes: species differences and regulation in vitro.

Expression of developmentally regulated antigens was used to characterize glial cells in cultures from embryonic mouse cerebral cortex. Over 90% of the cells had a flat morphology, and about 50% of these flat cells also expressed the ganglioside GD3. Up to 40% of all the GD3 expressing cells also expressed A2B5 antigen. Flat cells expressing either glial fibrillary acidic protein (GFAP), or GD3 or both were present at all times in vitro. These three populations of flat cells could not be further distinguished on the basis of NG2 or fibronectin expression, or with respect to their responses to the mitogens FGF-2, PDGF, or EGF. The glial cultures also contain a small number (approximately 5%) of process bearing cells with the morphological and immunocytochemical characteristics of oligodendrocyte precursors. The expression of GD3 by flat cells changed with time in culture as the fraction of flat cells expressing only GD3 declined and the fraction of cells expressing GFAP (with or without GD3) increased. The data are consistent with those flat cells expressing only GD3 being astrocyte precursors. Furthermore, between 1 and 3 weeks in vitro GD3/GFAP cells lose GD3 while retaining GFAP. Cells expressing only GFAP could be induced to express GD3 and A2B5 by treatment with FGF-2. The widespread and regulated expression of GD3 and A2B5 by murine glia is different from the restricted pattern of expression previously reported for these antigens in rat brain cell cultures. These results demonstrate that expression of GD3 and A2B5 by murine astrocytes depends on both culture age and extracellular signals and that these gangliosides are not markers for cell lineage in the mouse.

Consequences of trisomy 16 for mouse brain development: corticogenesis in a model of Down syndrome.

We have studied abnormalities in the tangential and radial expansion of the cerebral cortex during fetal development in the trisomy 16 (Ts16) mouse, a model for human trisomy 21 (Down syndrome). Slowed tangential expansion of the neuroepithelium in Ts16 resulted in a reduction of final telencephalic size and is predicted to decrease the number of radial cortical units in the mature brain. In addition, radial growth of the Ts16 cortex was delayed at the time of peak cortical neurogenesis in normal mice, but by embryonic day 18 the cortex reached normal thickness. Because mouse chromosome 16 shares many genes with human chromosome 21, abnormalities in Ts16 brain development may parallel abnormalities in trisomy 21.

Modulation of two functionally distinct Ca2+ stores in astrocytes: role of the plasmalemmal Na/Ca exchanger.

Mechanisms that regulate the amount of releasable Ca2+ in intracellular stores of cultured mouse astrocytes were investigated using digital imaging of fura-2 loaded cells. At rest, the cytoplasmic Ca2+ concentration, [Ca2+]cyt, was about 110 nM. In the absence of extracellular Ca2+, cyclopiazonic acid (CPA), an inhibitor of the endoplasmic reticulum (ER) Ca(2+)-ATPase, induced a transient, four-fold increase in [Ca2+]cyt due to the release of Ca2+ from inositol triphosphate (IP3) sensitive stores. Caffeine (CAF), which releases Ca2+ from Ca(2+)-sensitive stores, induced a two-fold increase in [Ca2+]cyt. The CPA- and CAF-sensitive stores could be released independently. Changes in the amplitudes of the Ca2+ transients were taken as a measure of changes in store content. Removal of extracellular Na+ or addition of ouabain, which inhibit Ca2+ extrusion and promote Ca2+ entry across the plasmalemma via the Na/Ca exchanger, caused minimal increases in resting [Ca2+]cyt but greatly potentiated both CPA- and CAF-induced Ca2+ transients. The amount of Ca2+ releasable from the IP3(CPA) sensitive store was directly proportional to cytosolic Na+ concentration (i.e., inversely proportional to the transmembrane Na+ electrochemical gradient). Under these reduced Na+ gradient conditions, little, if any, Ca2+ destined for the ER stores enters the cells through voltage-dependent Ca2+ channels. These results demonstrate that mouse astrocytes contain two distinct ER Ca2+ stores, the larger, IP3- (CPA-) sensitive, and the smaller, Ca(2+)- (CAF-) sensitive. The Ca2+ content of both ER stores can be regulated by the Na/Ca exchanger. Thus, the magnitude of cellular responses to signals that are mediated by Ca2+ release induced by the two second messengers, IP3 and Ca2+, can be modulated by factors that affect the net transport of Ca2+ across the plasmalemma.

Glutamate as a hippocampal neuron survival factor: an inherited defect in the trisomy 16 mouse.

The survival of cultured mouse hippocampal neurons was found to be greatly enhanced by micromolar concentrations of the excitatory neurotransmitter glutamate. Blockade of kainate/AMPA (alpha-amino-3-hydroxy-5-methyl-4-isoxazole propionic acid) glutamate receptors increased the rate of neuron death, suggesting that endogenous glutamate in the cultures promotes survival. Addition of glutamate (0.5-1 microM) further increased neuron survival, whereas glutamate in excess of 20 microM resulted in increased death. Thus, the survival vs. glutamate dose-response relation is bell-shaped with an optimal glutamate concentration near 1 microM. We found that hippocampal neurons from mice with the genetic defect trisomy 16 (Ts16) died 2-3 times faster than normal (euploid) neurons. Moreover, glutamate, at all concentrations tested, failed to increase survival of Ts16 neurons. In contrast, the neurotrophic polypeptide basic fibroblast growth factor did increase the survival of Ts16 and euploid neurons. Ts16 is a naturally occurring mouse genetic abnormality, the human analog of which (Down syndrome) leads to altered brain development and Alzheimer disease. These results demonstrate that the Ts16 genotype confers a defect in the glutamate-mediated survival response of hippocampal neurons and that this defect can contribute to their accelerated death.

A novel, abundant sodium channel expressed in neurons and glia.

A novel, voltage-gated sodium channel cDNA, designated NaCh6, has been isolated from the rat central and peripheral nervous systems. RNase protection assays showed that NaCh6 is highly expressed in the brain, and NaCh6 mRNA is as abundant or more abundant than the mRNAs for previously identified rat brain sodium channels. In situ hybridization demonstrated that a wide variety of neurons express NaCh6, including motor neurons in the brainstem and spinal cord, cerebellar granule cells, and pyramidal and granule cells of the hippocampus. RT-PCR and/or in situ hybridization showed that astrocytes and Schwann cells express NaCh6. Thus, this sodium channel is broadly distributed throughout the nervous system and is shown to be expressed in both neurons and glial cells.

Evidence for large-scale astrocyte death in the developing cerebellum.

There is increasing evidence that some glial cells die during normal vertebrate development, but the extent of the death and the types of glial cells that die remain uncertain. We have analyzed pyknotic cells in the developing postnatal rat cerebellum. During the first postnatal week, the majority of pyknotic cells are in the developing white matter where their number peaks at about postnatal day 7 (P7) and then declines sharply. Pyknotic cells in the internal granule cell layer peak at P10, while those in the molecular and external granule cell layers peak later. Both electron microscopy and in situ end labeling of DNA catalyzed by terminal deoxynucleotidyl transferase confirm that the pyknotic cells are undergoing apoptosis. Immunohistochemical staining suggests that 50-70% of the pyknotic cells in the white matter and internal granule cell layer are astrocytes. We estimate that at P7, as many as 50% of the white matter cells die and, of these, more than half appear to be astrocytes.

Sodium/calcium exchange in rat cortical astrocytes.

Regulation of the cytosolic free Ca2+ concentration ([Ca2+]cyt) by an Na/Ca exchanger was studied in primary cultured rat cortical astrocytes. [Ca2+]cyt was measured by digital imaging in cells loaded with fura-2. The resting [Ca2+]cyt, approximately 150 nM, was only slightly increased by reducing the extracellular Na+ concentration ([Na+]o) to 6.2 mM, or by treating the cells with ouabain for 15 min (to raise cytosolic Na+). Following treatment with ouabain, however, lowering [Na+]o caused [Ca2+]cyt to rise rapidly to approximately 1300 nM. When Ca2+ sequestration in intracellular stores was blocked by thapsigargin, lowering [Na+]o increased [Ca2+]cyt to approximately 1500 nM in the absence of ouabain. The low-[Na+]o-stimulated rise in [Ca2+]cyt was abolished by removal of external Ca2+, but was not blocked by the Ca2+ channel blocker verapamil, or by caffeine or ryanodine, which deplete an intracellular Ca2+ store responsible for Ca(2+)-induced Ca2+ release. These data suggest that Na+ gradient reduction promotes net Ca2+ gain via Na/Ca exchange. Normally, however, a large rise in [Ca2+]cyt is prevented by sequestration of the entering Ca2+; this buffering of cytosolic Ca2+ can be circumvented by blocking sequestration with thapsigargin, or overwhelmed by enhancing net Ca2+ gain by pretreating the cells with ouabain. The presence of Na/Ca exchanger protein and mRNA in the astrocytes was confirmed by Western and Northern blot analyses, respectively. Immunohistochemistry revealed that exchanger molecules are distributed in a reticular pattern over the astrocyte surface. We suggest that the Na/Ca exchanger plays a role in regulating both [Ca2+]cyt and the intracellular stores of Ca2+ in astrocytes, and may thus contribute to the control of astrocyte responsiveness to neurotransmitters and neurotoxins.

Ion permeation, divalent ion block, and chemical modification of single sodium channels. Description by single- and double-occupancy rate-theory models.

Calcium ions, applied internally, externally, or symmetrically, have been used in conjunction with rate-theory modeling to explore the energy profile of the ion-conducting pore of sodium channels. The block, by extracellular and/or intracellular calcium, of sodium ion conduction through single, batrachotoxin-activated sodium channels from rat brain was studied in planar lipid bilayers. Extracellular calcium caused a reduction of inward current that was enhanced by hyperpolarization and a weaker block of outward current. Intracellular calcium reduced both outward and inward sodium current, with the block being weakly dependent on voltage and enhanced by depolarization. These results, together with the dependence of single-channel conductance on sodium concentration, and the effects of symmetrically applied calcium, were described using single- or double-occupancy, three-barrier, two-site (3B2S), or single-occupancy, 4B3S rate-theory models. There appear to be distinct outer and inner regions of the channel, easily accessed by external or internal calcium respectively, separated by a rate-limiting barrier to calcium permeation. Most of the data could be well fit by each of the models. Reducing the ion interaction energies sufficiently to allow a small but significant probability of two-ion occupancy in the 3B2S model yielded better overall fits than for either 3B2S or 4B3S models constrained to single occupancy. The outer ion-binding site of the model may represent a section of the pore in which sodium, calcium, and guanidinium toxins, such as saxitoxin or tetrodotoxin, compete. Under physiological conditions, with millimolar calcium externally, and high potassium internally, the model channels are occupied by calcium or potassium much of the time, causing a significant reduction in single-channel conductance from the value measured with sodium as the only cation species present. Sodium conductance and degree of block by external calcium are reduced by modification of single channels with the carboxyl reagent, trimethyloxonium (TMO) (Worley et al., 1986) Journal of General Physiology. 87:327-349). Elevations of only the outermost parts of the energy profiles for sodium and calcium were sufficient to account for the reductions in conductance and in efficacy of calcium block produced by TMO modification.

Tityustoxin K alpha blocks voltage-gated noninactivating K+ channels and unblocks inactivating K+ channels blocked by alpha-dendrotoxin in synaptosomes.

Two nonhomologous polypeptide toxins, tityustoxin K alpha (TsTX-K alpha) and tityustoxin K beta (TsTX-K beta), purified from the venom of the Brazilian scorpion Tityus serrulatus, selectively block voltage-gated noninactivating K+ channels in synaptosomes (IC50 values of 8 nM and 30 nM, respectively). In contrast, alpha-dendrotoxin (alpha-DTX) and charybdotoxin (ChTX) block voltage-gated inactivating K+ channels in synaptosomes (IC50 values of 90 nM and 40 nM, respectively). We studied interactions among these toxins in 125I-alpha-DTX binding and 86Rb efflux experiments. Both TsTX-K alpha and ChTX completely displaced specifically bound 125I-alpha-DTX from synaptic membranes, but TsTX-K beta had no effect on bound alpha-DTX. TsTX-K alpha and TsTX-K beta blocked the same noninactivating component of 100 mM K(+)-stimulated 86Rb efflux in synaptosomes. Both alpha-DTX and ChTX blocked the same inactivating component of the K(+)-stimulated 86Rb efflux in synaptosomes. Both the inactivating and the noninactivating components of the 100 mM K(+)-stimulated 86Rb efflux were completely blocked when 200 nM TsTX-K beta and either 600 nM alpha-DTX or 200 nM ChTX were present. The effects of TsTX-K alpha and ChTX on 86Rb efflux were also additive. When TsTX-K alpha was added in the presence of alpha-DTX, however, only the noninactivating component of the K(+)-stimulated efflux was blocked. The inactivating component could then be blocked by ChTX, which is structurally homologous to TsTX-K alpha. We conclude that TsTX-K alpha unblocks the voltage-gated inactivating K+ channels in synaptosomes when they are blocked by alpha-DTX, but not when they are blocked by ChTX. TsTX-K alpha binds to a site on the inactivating K+ channel that does not occlude the pore; its binding apparently prevents alpha-DTX (7054 Da), but not ChTX (4300 Da), from blocking the pore. The effects of TsTX-K alpha on 125I-alpha-DTX binding and 86Rb efflux are mimicked by noxiustoxin, which is homologous to TsTX-K alpha and ChTX.

Mutually exclusive exon splicing of type III brain sodium channel alpha subunit RNA generates developmentally regulated isoforms in rat brain.

We have identified two exons of the type III rat brain sodium channel alpha subunit gene that undergo mutually exclusive alternative RNA splicing to produce mRNAs coding either for an isoform predominant in neonatal brain (IIIN) or a different isoform (IIIA) predominant in the adult. These exons are 92 base pairs in length and encode amino acids 203-232, which correspond to part of the S3 and most of the S4 transmembrane segments within domain I and the extracellular loop between them. Despite 21 nucleotide differences between the exons, only a single amino acid at position 209 is altered, specifying either aspartic acid (IIIA) or serine (IIIN). As evidence that these isoforms are generated via alternative splicing, we demonstrate that both exons are encoded within the type III gene. The nucleotide sequences of the neonatal and adult type III exons and the intervening intron as well as the developmental regulation of this splicing are nearly identical in the type II sodium channel gene. The conservation of the exon/intron structure and of the developmentally regulated patterns of expression of the type II and III sodium channel genes suggests that alternative mRNA splicing of this exon may play a substantial role in modulating sodium channel function during brain development by alteration of a single amino acid.

Lipid surface charge does not influence conductance or calcium block of single sodium channels in planar bilayers.

We have studied the effects of membrane surface charge on Na+ ion permeation and Ca2+ block in single, batrachotoxin-activated Na channels from rat brain, incorporated into planar lipid bilayers. In phospholipid membranes with no net charge (phosphatidylethanolamine, PE), at low divalent cation concentrations (approximately 100 microM Mg2+), the single channel current-voltage relation was linear and the single channel conductance saturated with increasing [Na+] and ionic strength, reaching a maximum (gamma max) of 31.8 pS, with an apparent dissociation constant (K0.5) of 40.5 mM. The data could be approximated by a rectangular hyperbola. In negatively charged bilayers (70% phosphatidylserine, PS; 30% PE) slightly larger conductances were observed at each concentration, but the hyperbolic form of the conductance-concentration relation was retained (gamma max = 32.9 pS and K0.5 = 31.5 mM) without any preferential increase in conductance at lower ionic strengths. Symmetrical application of Ca2+ caused a voltage-dependent block of the single channel current, with the block being greater at negative potentials. For any given voltage and [Na+] this block was identical in neutral and negatively charged membranes. These observations suggest that both the conduction pathway and the site(s) of Ca2+ block of the rat brain Na channel protein are electrostatically isolated from the negatively charged headgroups on the membrane lipids.

Polypeptide toxins from the venoms of Old World and New World scorpions preferentially block different potassium channels.

Venoms from five Old World and two New World scorpions were tested for their ability to block various K+ channels in rat brain synaptosomes. A 86Rb efflux kinetic assay was used to identify three types of K+ channels, Ca(2+)-independent, voltage-gated, inactivating (A-type) and noninactivating (delayed rectifier) K+ channels and Ca(2+)-activated K+ channels [J. Physiol. (Lond.) 361:419-440, 441-457 (1985)]. The venoms from the Old World scorpions all blocked the A-type K+ channel but not the delayed rectifier K+ channel; only venom from the Israeli scorpion, Leiurus quinqestriatus hebraeus (Lqh), blocked the Ca(2+)-activated K+ channel. In contrast, venoms from the two New World scorpions selectively blocked the delayed rectifier K+ channel. Water-soluble components from Lqh venom from the Brazillian scorpion, Tityus serrulatus (Ts), were separated by ion exchange high performance liquid chromatography (HPLC). Seven components that blocked synaptosome K+ channels were isolated from Lqh venom by ion exchange HPLC. All seven components blocked the A-type K+ channel; the five most potent toxins had IC50 values of 18-40 nM. Two of the components from Lqh venom (one identified as charybdotoxin and the other denoted as Lqk4) also blocked a Ca(2+)-activated K+ channel (IC50 = 15 and 60 nM for charybdotoxin and Lqk4, respectively). Five K+ channel-blocking components were isolated from the Ts venom; all five blocked the delayed rectifier channel selectively, and the two most potent components had IC50 values of 8 and 30 nM. Several of the more potent Lqh and Ts toxins were purified to near-homogeneity by reverse phase HPLC. These toxins should be useful as ligands for K+ channel purification, for elucidation of K+ channel structure, and for studies of K+ channel function.