Adenylate cyclase toxin from Bordetella pertussis. Identification and purification of the holotoxin molecule

Bordetella pertussis adenylate cyclase (AC) toxin is a calmodulin-activated adenylate cyclase enzyme which has the capacity to enter eukaryotic target cells and catalyze the conversion of endogenous ATP into cyclic AMP. In this work, the AC holotoxin molecule is identified and isolated. It is a single polypeptide of apparent 216 kDa as determined by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Monoclonal antibodies which immunoprecipitate AC activity from extracts of wild type B. pertussis (BP338) react with this 216-kDa band on Western blots, and it is absent from a transposon Tn5 mutant (BP348) specifically lacking AC toxin. Isolation of the 216-kDa protein to greater than 85% purity by hydrophobic chromatography, preparative sucrose gradient centrifugation, and affinity chromatography using either calmodulin-Sepharose or monoclonal antibody coupled to Sepharose 4B yields stepwise increases in AC toxin potency, to a maximum of 88.3 mumol of cAMP/mg of target cell protein/mg of toxin. Electroelution of the 216-kDa band following sodium dodecyl sulfate-polyacrylamide gel electrophoresis yields a preparation with both AC enzyme and toxin activities. These data indicate that this protein represents the AC holotoxin molecule.     

Studies on the alpha-subunit of bovine brain S-100 protein.

A method is described for the rapid purification of both S-100 protein and calmodulin from crude bovine brain extracts by the use of a fluphenazine-Sepharose affinity column eluted stepwise with decreasing concentrations of free Ca2+. Protein containing only alpha-subunit was purified from preparations of S-100 protein by anion-exchange chromatography. This protein co-migrated with the alpha-subunit of S-100 protein on sodium dodecyl sulphate/urea/polyacrylamide-gel electrophoresis and had an amino acid composition identical with that previously reported for this subunit. The results of u.v.-absorption and fluorescence-emission spectroscopy indicate that the tryptophan residue of the purified alpha-subunit of S-100 protein undergoes a Ca2+-induced change in environment. Measurements of changes in tryptophan fluorescence with increasing Ca2+ concentrations suggest an apparent dissociation constant of the alpha-subunit for Ca2+ of 7 X 10(-5)M in the absence of K+. In the presence of 90mM-K+ this value is increased to 3.4 X 10(-4)M.     

Resorption versus secretion in the rat epididymis

Micropuncture samples were taken from the rete testis, caput epididymidis and cauda epididymidis of anaesthetized adult rats and assayed for total protein, sodium and potassium concentrations. Intraluminal sperm concentrations were determined and used to calculate the amount of fluid resorbed from the efferent duct and epididymal lumen. It was demonstrated that large amounts of protein (30.2 mg/ml cauda volume) and sodium (241.8 mequiv./l) and smaller amounts of potassium (19.4 mequiv./l) are resorbed from the rat epididymal lumen between the caput and corpus epididymidis. This occurs despite increases in intraluminal concentrations of protein (from 22 to 28 mg/ml) and potassium (from 16 to 50 mequiv./l). Resorption is an important aspect of epididymal control of the intraluminal environment.     

DNA amplification in arsenite-resistant Leishmania

Arsenite-resistant variants of a trypanosomatid protozoan, Leishmania mexicana amazonensis, were selected in vitro by stepwise increases of sodium arsenite concentrations up to 30 microM in the culture medium. These variants were found to contain amplified DNA as extrachromosomal supercoiled molecules of about 69 kb. They originate from a single chromosome in the wild-type cells. There is evidence of chromosomal changes in these cells associated with the selection for arsenite resistance. The apparent absence of these circular molecules in the wild type and their loss from the drug-sensitive revertants suggest amplification of chromosomal DNA into these extrachromosomal circles as the mechanism of arsenite resistance.     

Changes in blood osmolarity,electrolytes, and metabolites among adult rats treated with a neurotoxic dose of MSG1

Adult rats were given large doses of MSG (4 g/kg) or isosmolar amounts of sodium chloride or L-alanine intraperitoneally or by forced intubation. Blood or plasma samples from these rats where assayed for osmolarity, hematocrit, pH, and concentrations of protein, sodium, potassium, chloride, calcium, magnesium, and urea nitrogen. Intraperitoneal MSG produced characteristic hypothalamic lesions; MSG by gavage failed to do so. Intraperitoneal MSG also caused major increases in plasma osmolarity, hemoconcentration, hypovolemia, alkalosis, hypernatremia, and uremia; plasma levels of chloride and potassium fell significantly. Administration of MSG by gavage caused much smaller changes in plasma osmolarity and sodium, and no significant changes in hematocrit, plasma protein or plasma urea nitrogen. Administration of sodium chloride or L-alanine (agents not known to produce the characteristics MSG brain lesions) caused some, but not all, of the metabolic changes seen after MSG. These observations suppot the hypothesis that the ability of large, concentrated doses of MSG to produce brain lesions in susceptible species involves a two-step process, i.e., initial damage to the blood-brain barrier for glutamate, followed by entry of the circulating amino acid into the extracellular space of the brain.     

Diminished paracrine regulation of the epithelial Na+ channel by purinergic signaling in mice lacking connexin 30

We tested whether ATP release through Connexin 30 (Cx30) is part of a local purinergic regulatory system intrinsic to the aldosterone-sensitive distal nephron (ASDN) important for proper control of sodium excretion; if changes in sodium intake influence ATP release via Cx30; and if this allows a normal ENaC response to changes in systemic sodium levels. In addition, we define the consequences of disrupting ATP regulation of ENaC in Cx30(-/-) mice. Urinary ATP levels in wild-type mice increase with sodium intake, being lower and less dependent on sodium intake in Cx30(-/-) mice. Loss of inhibitory ATP regulation causes ENaC activity to be greater in Cx30(-/-) versus wild-type mice, particularly with high sodium intake. This results from compromised ATP release rather than end-organ resistance: ENaC in Cx30(-/-) mice responds to exogenous ATP. Thus, loss of paracrine ATP feedback regulation of ENaC in Cx30(-/-) mice disrupts normal responses to changes in sodium intake. Consequently, ENaC is hyperactive in Cx30(-/-) mice lowering sodium excretion particularly during increases in sodium intake. Clamping mineralocorticoids high in Cx30(-/-) mice fed a high sodium diet causes a marked decline in renal sodium excretion. This is not the case in wild-type mice, which are capable of undergoing aldosterone-escape. This loss of the ability of ENaC to respond to changes in sodium levels contributes to salt-sensitive hypertension in Cx30(-/-) mice.     

Studies of the denaturation and partial renaturation of ovalbumin

1. The denaturation of ovalbumin by the reagents sodium dodecyl sulphate and guanidinium chloride was investigated, by following the changes in sedimentation velocity, optical rotatory dispersion and viscosity as a function of denaturant concentration. 2. With sodium dodecyl sulphate both the optical-rotatory-dispersion parameters a(0) and b(0) become more negative, the sedimentation coefficient decreases and the viscosity increases; significant differences in the denaturation profiles are observed. The change in each parameter is indicative of only limited denaturation. 3. With guanidinium chloride the transition occurs over the concentration range 1-4m: more extensive changes occur in all the physical parameters than with sodium dodecyl sulphate. The values of a(0) and b(0) are indicative of complete denaturation. Reduction by mercaptoethanol produces only minor further changes. 4. Renaturation was attempted from both denaturants, the removal of reagent being accomplished reversibly by controlled slow dialysis. Partial renaturation was observed, but aggregated or insoluble material was produced in both cases at relatively low concentrations of denaturant. Similar behaviour was observed with fully reduced protein in guanidinium chloride-mercaptoethanol; complete renaturation could not be brought about even at very low protein concentrations.     

Electrophoretic and spectroscopic characterization of the protein patterns formed in different surfactant solutions

The complexations between catalase and the sodium perfluorooctanoate/sodium octanoate and sodium perfluorooctanoate/sodium dodecanoate systems have been studied by a combination of electrophoresis and spectroscopy measurements. The numbers of adsorption sites on the protein were determined from the observed increases of the zeta-potential as a function of surfactant concentration in the regions where the adsorption was a consequence of the hydrophobic effect. The Gibbs energies of adsorption of the surfactants onto the protein were evaluated and the results show that for all systems, Gibbs energies are negative and larger, in absolute values, at low values of surfactant concentration where binding to the high energy sites takes place, and become less negative as more surfactant molecules bind, suggesting a saturation process. The role of hydrophobic interactions in these systems has been demonstrated to be the predominant. Spectroscopy measurements suggest conformational changes on catalase depending on the surfactant mixture as well as the mixed ratio. No isosbestic point or shifts have been found showing that catalase has spectrophotometrically one kind of binding site for these surfactant mixtures.     

脱水胁迫对连翘和冬青卫矛叶片细胞质外体和微环境的影响

用压力室、电导法和原子吸收分光光度分析法综合分析测定了连翘[Forsythiasuspensa (Thunb.) Vahl]和冬青卫矛(Euonymus japonicus Thunb.)在不同程度脱水胁迫时细胞外部微环境的变化.结果表明:(1)在脱水胁迫条件下,叶片细胞随着脱水胁迫强度的加大,细胞内离子外渗的累计量不断加大,但细胞内离子外渗的速度在不同的区间内并无明显的改变,即细胞膜的透性在所测范围内没有明显变化.(2)脱水胁迫同时造成了叶片质外体和共质体溶液中钠、钾离子浓度的增加,但质外体比共质体溶液中钠、钾离子浓度的增加幅度更高,导致细胞内、外离子浓度梯度的改变和离子平衡膜电位的改变,这些改变有可能引起细胞的次生生理变化,并有可能与植物的伤害反应和抗性有关.     

Protein conformational changes and myelin solubilization by anion-detergent solutions.

The addition of sodium sulfate to a myelin suspension in sodium phosphate buffer at neutral pH, containing octyl glucoside detergent (OG), increases the membrane solubility more than 5-fold by an unknown structural mechanism. FTIR spectroscopy has been applied to investigate anion effects on the conformational structure of myelin proteins. Sulfate and sulfate-phosphate media, but not phosphate alone, induce a great conformational protein disorder. The addition of the detergent to the anion mixture solution prevents the myelin from protein denaturation. The conformational transitions have also been quantified through the amide I region. Explanations of these changes and their connections with myelin solubility are also included.     

Effect of acrylamide on aldolase structure. I. Induction of intermediate states.

Acrylamide is a fluorescence quencher frequently applied for analysis of protein fluorophores exposure with the silent assumption that it does not affect the native structure of protein. In this report, it is shown that quenching of tryptophan residues in aldolase is a time-dependent process. The Stern-Volmer constant increases from 1.32 to 2.01 M-1 during the first 100 s of incubation of aldolase with acrylamide. Two tryptophan residues/subunit are accessible to quenching after 100 s of aldolase interaction with acrylamide. Up to about 1.2 M acrylamide concentration enzyme inactivation is reversible. Independent analyses of the changes of enzyme activity, 1ANS fluorescence during its displacement from aldolase active-site, UV-difference spectra and near-UV CD spectra were carried out to monitor the transition of aldolase structure. From these measurements a stepwise transformation of aldolase molecules from native state (N) through intermediates: I1, T, I2, to denatured (D) state is concluded. The maxima of I1, T, I2 and D states populations occur at 0.2, 1.0, 2.0 and above 3.0 M of acrylamide concentration, respectively. Above 3.5 M, acrylamide aldolase molecules become irreversibly inactivated.     

Proteinase-activated receptor 2 stimulates Na,K-ATPase and sodium reabsorption in native kidney epithelium

Proteinase-activated receptors 2 (PAR2) are expressed in kidney, but their function is mostly unknown. Since PAR2 control ion transport in several epithelia, we searched for an effect on sodium transport in the cortical thick ascending limb of Henle's loop, a nephron segment that avidly reabsorbs NaCl, and for its signaling. Activation of PAR2, by either trypsin or a specific agonist peptide, increased the maximal activity of Na,K-ATPase, its apparent affinity for sodium, the sodium permeability of the paracellular pathway, and the lumen-positive transepithelial voltage, featuring increased NaCl reabsorption. PAR2 activation induced calcium signaling and phosphorylation of ERK1,2. PAR2-induced stimulation of Na,K-ATPase Vmax was fully prevented by inhibition of phospholipase C, of changes in intracellular concentration of calcium, of classical protein kinases C, and of ERK1,2 phosphorylation. PAR2-induced increase in paracellular sodium permeability was mediated by the same signaling cascade. In contrast, increase in the apparent affinity of Na,K-ATPase for sodium, although dependent on phospholipase C, was independent of calcium signaling, was insensitive to inhibitors of classical protein kinases C and of ERK1,2 phosphorylation, but was fully prevented by the nonspecific protein kinase inhibitor staurosporine, as was the increase in transepithelial voltage. In conclusion, PAR2 increases sodium reabsorption in rat thick ascending limb of Henle's loop along both the transcellular and the paracellular pathway. PAR2 effects are mediated in part by a phospholipase C/protein kinase C/ERK1,2 cascade, which increases Na,K-ATPase maximal activity and the paracellular sodium permeability, and by a different phospholipase C-dependent, staurosporine-sensitive cascade that controls the sodium affinity of Na,K-ATPase.     

Cyclic AMP mediates beta-adrenergic-induced increases in N-linked protein glycosylation in rat parotid acinar cells.

beta-Adrenergic stimulation of rat parotid cells by isoprenaline (isoproterenol) results in 2-3-fold increases in [3H]mannose incorporation into N-linked oligosaccharides. This occurs without perceptible lag and is linear with time for 60 min after agonist addition. Concomitantly, isoprenaline markedly increases cellular cyclic AMP. Examination of individual proteins by sodium dodecyl sulphate/polyacrylamide-gradient-gel electrophoresis reveals that glycosylation changes are primarily associated with four secretory proteins, of approx. Mr 17000, 32000, 38000 and 220000. Beta-Adrenoreceptor activation additionally elicits a slight increase in parotid protein synthesis. The greatest increase in [14C]leucine incorporation is that into another secretory protein (Mr approx. 24000). Exposure of cells to dibutyryl cyclic AMP yields results comparable with those after isoprenaline treatment. Forskolin, which increases parotid-cell cyclic AMP, also causes similar effects. Conversely, dibutyryl cyclic GMP shows no such response. The data are consistent with the notion that beta-adrenergic stimulation of N-linked protein glycosylation in rat parotid cells is mediated by cyclic AMP.     

Drift and benthic invertebrate responses to stepwise and abrupt increases in non-scouring flow

We conducted two experiments to assess drift and benthic invertebrate responses to stepwise and abrupt changes in non-scouring flow in gravel-bed experimental streams. Intuitively, a stepwise flow increase should allow aquatic invertebrates more time to seek refuges than would an abrupt increase. We hypothesized that abrupt flow increases would result in larger increases in taxon richness and in the number of invertebrates in the drift, and a larger decrease in benthic density than would stepwise flow increases. Two kinds of drift response to flow increases were observed in the stepwise experiment: (1) no response (e.g. Caenissp. [Ephemeroptera] and Sphaeriidae [Pelecypoda]); (2) threshold response of some aquatic (e.g. Crangonyx pseudogracilis[Amphipoda]) and semiaquatic (e.g. Ormosiasp. [Diptera]) taxa. Drift richness and drift density in both experiments declined after reaching a peak. The peak was reached almost immediately in the abrupt treatment and later in the stepwise treatment. Maximum richness of taxa and taxon composition in the drift were similar in both experiments. Despite significant increases in drift, stepwise and abrupt increases in flow did not have a significant effect on benthic density. However, relative to reference streams, the percentage of total benthic invertebrates in the drift increased 10× in the stepwise experiment and 33× in the abrupt experiment. These non-scouring increases in flow were non-trivial. Our results suggest that several high flow events of the same magnitude (i.e. 2.5–3.0 fold increases) may cause considerable losses of benthic populations to the drift. The rate of increases in flow appears to be important: abrupt increases in flow had a stronger effect on invertebrate drift than did stepwise increases.     

Direct effects of nitroprusside do not alter gas exchange in canine oleic acid edema

The authors investigated why intrapulmonary shunt (QS/QT) increases with sodium nitroprusside (SNP) in canine oleic acid pulmonary edema. To determine the effects of flow alone on QS/QT, a peripheral arteriovenous fistula with a variable resistor was employed to increase cardiac output (Q) 26 and 52% above base line in a stepwise fashion (P less than 0.01). To examine the direct effects of SNP, distinct from changes in flow, the drug was given to produce matched increments in Q in each dog (P less than 0.01). To control for time, base-line measurements were obtained before and after each intervention, the sequence of which was alternated. At each increment in Q, SNP and the arteriovenous fistula increased QS/QT a similar amount. The mixed venous O2 tension (P-vO2) followed Q similarly in each group. Pulmonary vascular resistance (PVR) fell more (P less than 0.01) with SNP than with the arteriovenous fistula at identical Q and P-vO2. The authors conclude that, in this model, a direct pharmacological effect of SNP does not contribute to the deterioration in QS/QT. In fact, SNP exerts a pulmonary vasoactive effect that does not adversely affect gas exchange.     

Chronic activation of plasma renin is log-linearly related to dietary sodium and eliminates natriuresis in response to a pulse change in total body sodium

Responses to acute sodium loading depend on the load and on the level of chronic sodium intake. To test the hypothesis that an acute step increase in total body sodium (TBS) elicits a natriuretic response, which is dependent on the chronic level of TBS, we measured the effects of a bolus of NaCl during different low-sodium diets spanning a 25-fold change in sodium intake on elements of the renin-angiotensin-aldosterone system (RAAS) and on natriuresis. To custom-made, low-sodium chow (0.003%), NaCl was added to provide four levels of intake, 0.03-0.75 mmol.kg(-1).day(-1) for 7 days. Acute NaCl administration increased PV (+6.3-8.9%) and plasma sodium concentration (~2%) and decreased plasma protein concentration (-6.4-8.1%). Plasma ANG II and aldosterone concentrations decreased transiently. Potassium excretion increased substantially. Sodium excretion, arterial blood pressure, glomerular filtration rate, urine flow, plasma potassium, and plasma renin activity did not change. The results indicate that sodium excretion is controlled by neurohumoral mechanisms that are quite resistant to acute changes in plasma volume and colloid osmotic pressure and are not down-regulated within 2 h. With previous data, we demonstrate that RAAS variables are log-linearly related to sodium intake over a >250-fold range in sodium intake, defining dietary sodium function lines that are simple measures of the sodium sensitivity of the RAAS. The dietary function line for plasma ANG II concentration increases from theoretical zero at a daily sodium intake of 17 mmol Na/kg (intercept) with a slope of 16 pM increase per decade of decrease in dietary sodium intake.     

Regulation of the amiloride-blockable sodium channel from epithelial tissue

The first step in net active transepithelial transport of sodium in tight epithelia is mediated by the amiloride-blockable sodium channel in the apical membrane. This sodium channel is the primary site for discretionary control of total body sodium and, therefore, investigating its regulatory mechanisms is important to our understanding of the physiology of fluid and electrolyte balance. Because essentially all of the regulatory sites on the channel are on the intracellular surface, patch clamp methods have proven extremely useful in the electrophysiological characterization of the sodium channel by isolating it from other channel proteins in the epithelial membrane and by allowing access to the intracellular surface of the protein. We have examined three different regulatory mechanisms. (1) Inhibition of channel activity by activation of protein kinase C; (2) activation of the channel by agents which activate G-proteins; and (3) modulation of channel kinetics and channel number by mineralocorticoids. Activation of protein kinase C by phorbol esters or synthetic diacylglycerols reduces the open probability of sodium channels. Protein kinase C can be activated in a physiological context by enhancing apical sodium entry. Actions which reduce sodium entry (low luminal sodium concentrations or the apical application of amiloride) increase channel open probability. The link between sodium entry and activation of protein kinase C appears to be mediated by intracellular calcium activity linked to sodium via a sodium/calcium exchange system. Thus, the intracellular sodium concentration is coupled to sodium entry in a negative feedback loop which promotes constant total entry of sodium. Activation of G-proteins by pertussis toxin greatly increases the open probability of sodium channels. Since channels can also be activated by pertussis toxin or GTP gamma S in excised patches, the G-protein appears to be closely linked in the apical membrane to the sodium channel protein itself. The mechanism for activation of this apical G-protein, when most hormonal and transmitter receptors are physically located on the basolateral membrane, is unclear. Mineralocorticoids such as aldosterone have at least two distinct effects. First, as expected, increasing levels of aldosterone increase the density of functional channels detectable in the apical membrane. Second, contrary to expectations, application of aldosterone increases the open probability of sodium channels. Thus aldosterone promotes the functional appearance of new sodium channels and promotes increased sodium entry through both new and pre-existant channels.     

Primary structure and expression of a sodium channel characteristic of denervated and immature rat skeletal muscle

The alpha subunit of a voltage-sensitive sodium channel characteristic of denervated rat skeletal muscle was cloned and characterized. The cDNA encodes a 2018 amino acid protein (SkM2) that is homologous to other recently cloned sodium channels, including a tetrodotoxin (TTX)-sensitive sodium channel from rat skeletal muscle (SkM1). The SkM2 protein is no more homologous to SkM1 than to the rat brain sodium channels and differs notably from SkM1 in having a longer cytoplasmic loop joining domains 1 and 2. Steady-state mRNA levels for SkM1 and SkM2 are regulated differently during development and following denervation: the SkM2 mRNA level is highest in early development, when TTX-insensitive channels predominate, but declines rapidly with age as SkM1 mRNA increases; SkM2 mRNA is not detectable in normally innervated adult skeletal muscle but increases greater than 100-fold after denervation; rat cardiac muscle has abundant SkM2 mRNA but no detectable SkM1 message. These findings suggest that SkM2 is a TTX-insensitive sodium channel expressed in both skeletal and cardiac muscle.     

A reinvestigation of the secondary structure of functionally active vSGLT, the vibrio sodium/galactose cotransporter

The bacterial Na(+)/galactose cotransporter vSGLT of Vibrio parahaemolyticus is a member of the sodium:solute symporter family (SSS). Previous studies using electron microscopy have shown that vSGLT is a monomeric protein. Computational and experimental topological analyses have consistently indicated that this protein possesses 14 transmembrane alpha-helices. Our previous study using attenuated total reflectance Fourier transform infrared spectroscopy (ATR-FTIR) to quantitate secondary structure content had indicated, in contrast, an alpha-helical content of only 35%, too little to be consistent with the 14-span model [le Coutre, J., et al. (2002) Biochemistry 41, 8082-6]. ATR-FTIR had also indicated that upon binding of Na(+) and d-galactose, the alpha-helical content increased to 53%. Here we revisit the vSGLT secondary structural distribution using an alternative approach, ultraviolet circular dichroism spectropolarimetry (CD), which is highly accurate in determining the alpha-helical content of a protein in solution. CD spectra were obtained from actively functional, soluble vSGLT and, as an internal check, from a fusion protein of vSGLT and the beta-barrel green fluorescent protein (GFP). Far-UV CD of vSGLT indicates a predominating 85% alpha-helical content, and an absence of beta-strands. Far-UV CD of the vSGLT-GFP fusion corroborates this profile, indicating an equivalent alpha-helical content, and a beta-strand content consistent with the GFP contribution. No detectable substrate-induced macroscopic changes in secondary structure are apparent in the far UV. In the near UV, increases in positive CD intensity occur in a stepwise manner with added substrates, implying changing environments of aromatic amino acid residues. CD thus confirms the current 14-transmembrane span model of vSGLT and reveals distinct substrate-induced conformational changes. The high percentage of alpha-helical structure found requires, when considered in the context of membrane topology, that nearly a third of the total alpha-helical fraction lies in extramembrane domains, which distinguishes this cotransporter from the unrelated lactose and glycerol 3-phosphate transporters.     

The Calcium Content of Mitochondria from Brain Subregions Following Short-Term Forebrain Ischemia and Recirculation in the Rat

Abstract: A procedure was established for determining the calcium content of mitochondria isolated from rat brain subregions based on changes in fura-2 fluorescence after disruption of the organelles with Triton X-100 and sodium dodecyl sulfate. Mitochondria isolated from the forebrain of normal rats contained 2.5 ± 0.9 nmol of calcium/mg of protein. A 30-min ischemic period produced an approximately twofold increase in the calcium content of mitochondria isolated from the dorsolateral striatum, a region in which most neurons die within 24 h after this period of ischemia. The calcium content of mitochondria from the paramedian cortex, a region in which there are few ischemia-susceptible neurons, tended to be similarly increased, although this difference was not statistically significant. Larger increases (to approximately five times control values) were seen in mitochondria isolated from both regions after 10 min of recirculation. By 1 h of recirculation, mitochondrial calcium had returned close to preischemic control values in both regions. Longer recirculation periods produced no further changes in the calcium content of mitochondria from the paramedian cortex. However, mitochondrial calcium was again increased in the dorsolateral striatum after 6 h (6.5 nmol of calcium/mg of protein) and 24 h (8.7 nmol of calcium/mg of protein) of recirculation. This regionally selective increase in calcium in the dorsolateral striatum preceded the period during which the majority of neurons in this region exhibit advanced degenerative changes. Thus, this increase may be an essential step, albeit a late one, in the development of neuronal loss.