Neonatal lead exposure impairs development of rodent barrel field cortex.

Childhood exposure to low-level lead can permanently reduce intelligence, but the neurobiologic mechanism for this effect is unknown. We examined the impact of lead exposure on the development of cortical columns, using the rodent barrel field as a model. In all areas of mammalian neocortex, cortical columns constitute a fundamental structural unit subserving information processing. Barrel field cortex contains columnar processing units with distinct clusters of layer IV neurons that receive sensory input from individual whiskers. In this study, rat pups were exposed to 0, 0.2, 1, 1.5, or 2 g/liter lead acetate in their dam's drinking water from birth through postnatal day 10. This treatment, which coincides with the development of segregated columns in the barrel field, produced blood lead concentrations from 1 to 31 microg/dl. On postnatal day 10, the area of the barrel field and of individual barrels was measured. A dose-related reduction in barrel field area was observed (Pearson correlation = -0.740; P < 0.001); mean barrel field area in the highest exposure group was decreased 12% versus controls. Individual barrels in the physiologically more active caudoventral group were affected preferentially. Total cortical area measured in the same sections was not altered significantly by lead exposure. These data support the hypothesis that lead exposure may impair the development of columnar processing units in immature neocortex. We demonstrate that low levels of blood lead, in the range seen in many impoverished inner-city children, cause structural alterations in a neocortical somatosensory map.

Immediate early gene expression in PC12 cells exposed to lead: requirement for protein kinase C.

We previously demonstrated induction of c-fos mRNA in PC12 cells exposed to lead that was dependent on new transcription. In the current work, we examined two signal transduction mechanisms that are activated by lead and have been shown to mediate induction of c-fos mRNA. One mechanism involves protein kinase C, and the other requires calmodulin-dependent protein kinase II. Significant increases in the levels of c-fos, c-jun, and egr-1 but not NGFIB mRNA were observed in PC12 cells exposed to lead or phorbol 12-myristate 13-acetate. In contrast, PC12 cells depolarized with 56 mM K+ displayed an increase in c-fos, egr-1, and NGFIB but not c-jun mRNA. Similar to other activators of protein kinase C, lead increased AP-1 and Egr-1 DNA binding activity. Additionally, lead increased luciferase activity in cerebellar granule cells transfected with an AP-1 luciferase reporter construct. Lead did not increase c-fos mRNA in PC12 cells that were depleted of protein kinase C by a 24-h treatment with phorbol 12,13-dibutyrate or incubated with the protein kinase C inhibitor H-7. In contrast, an inhibitor of calmodulin-dependent protein kinase, KN-62, and an inhibitor of calmodulin, W-7, did not block the induction of c-fos mRNA by lead. An increase in serum-response element DNA-binding activity was observed in nuclear extracts from PC12 cells exposed to lead. It is interesting that lead activated protein kinase C isoforms delta and epsilon, but not isoforms alpha and beta. In conclusion, lead appears to induce the expression of immediate early genes by a mechanism that requires protein kinase C.

Selective vulnerability of the developing brain to lead.

Environmental lead exposure in young children who ingest household paint dust or other sources impairs their potential intelligence in a linear, dose-dependent fashion in contrast to its far more subtle effects on other neurologic functions. Basic investigations have identified three interrelated steps in synaptic neurotransmission at which low levels of lead can disrupt signal processing. Lead enhances background transmitter release, but impairs stimulated release, inhibits function at the N-methyl-D-aspartate-type glutamate receptor and stimulates background levels of the intracellular messenger protein kinase C. Taken together these effects have the effect of diminishing the synaptic signal to noise ratio. The ability of lead to enhance 'synaptic noise' during a critical early period of postnatal development may permanently disrupt the architecture of cortical processing units by depriving them of high resolution environmental signals needed to refine synaptic connections.

Induction of c-fos mRNA by lead in PC 12 cells.

Addition of lead acetate to PC 12 pheochromocytoma cells elicits induction of c-fos, an immediate early response gene. Induction of c-fos was concentration- and time-dependent: the lowest concentration of lead acetate tested that induced c-fos was 10 microM; induction was observed after a 30 min incubation and remained high after 90 min. Treatment with lead acetate and cycloheximide superinduced c-fos mRNA. Actinomycin D, an inhibitor of mRNA transcription, decreased the level of c-fos mRNA induced by lead acetate by almost 80%. Cadmium chloride and zinc chloride did not induce c-fos mRNA. Since the c-fos gene encodes a transcription factor, Pb2+ has the potential to deregulate the expression of other genes.

Distinct mechanisms of neurotransmitter release from PC 12 cells exposed to lead.

Two enzymes, protein kinase C and microsomal Ca(2+)-ATPase help regulate levels of Ca2+ in many types of cells. Since proteins that regulate Ca2+ often influence sensitivity to Pb2+, we determined the possible roles played by protein kinase C and microsomal Ca(2+)-ATPase for the Pb(2+)-evoked release of norepinephrine (NOR) in PC cells. NOR release was observed at 10 microM Pb2+ when PC 12 cells were stimulated with inhibitors of microsomal Ca(2+)-ATPase such as thapsigargin, cyclopiazonic acid, or 2,5-di-(t-butyl)-hydroquinone. At 5 microM, Pb2+ evoked the release of NOR in PC 12 cells stimulated with activators of protein kinase C such as phorbol 12-myristate 13-acetate (PMA) or (-)-7-octylindolactam. NOR release was observed at 1 microM Pb2+ in the presence of both PMA and thapsigargin. Ni2+ and Cd2+ blocked NOR release stimulated by Pb2+ in the presence of thapsigargin but not by PMA. NOR released by thapsigargin stimulation was not altered in PC 12 cells depleted of protein kinase C. Two proteins found in vesicles, chromogranin B and secretogranin-II were released with NOR. Our results indicate that in PC 12 cells, PB(2+)-evokes the release of neurotransmitters. Furthermore, thapsigargin and PMA increase the cell's sensitivity to Pb2+ by different pathways.

Modulation of serine proteinases and metalloproteinases during morphogenic glial-endothelial interactions.

The regulation of microvessel formation and the expression of CNS-specific endothelial properties are attributed to perivascular astroglia. Specific proteolytic pathways mediate processes such as tissue remodeling, differentiation, invasion, and metastasis. We used a co-culture system in which C6 glial cells induce CNS microvascular endothelial cells to form capillary-like structures to examine the role of plasminogen activators and collagenases in CNS microvessel morphogenesis. Fibrin zymography revealed the presence of high-molecular weight urokinase-type plasminogen activator (uPA), low-molecular weight uPA, and uPA/inhibitor complexes within endothelial cultures and cocultures. Gelatin zymography revealed the presence of 92-, 72-, and 62-kDa type IV collagenases within endothelial cultures and cocultures. uPA activity was confirmed by incubating the extracts with amiloride, an inhibitor of uPA. Collagenase activity was confirmed by incubating the gels with EDTA, an inhibitor of metalloproteinases. Quantitative densitometry showed a six- to eightfold decrease in coculture uPA during capillary-like structure formation. Substantially less change in type IV 72-kDa procollagenase activity was seen in cocultures during capillary-like structure formation, but active type IV 62-kDa collagenase activity was significantly increased during capillary-like structure formation. These findings establish that uPA and activated type IV collagenase activity specifically regulates morphogenic endothelial responses to glial interactions and suggest mechanisms by which microvessels respond within the CNS.

Phosphorylation of membrane proteins in erythrocytes treated with lead.

In immature rat microvessels, endothelial cells and glioma cells, exposure to lead results in an increase in the level of protein kinase C in membranes. In this paper we have extended these studies to human erythrocytes and, in addition, studied the phosphorylation of membrane proteins. A significant increase in the phosphorylation of membrane cytoskeletal proteins of molecular mass 120, 80, 52 and 45 kDa was observed in human erythrocytes treated for 60 min with lead acetate at concentrations greater than 100 nM. These same proteins were phosphorylated when erythrocytes were treated for 10 min with 50 nM phorbol 12-myristate 13-acetate (PMA). Similarly, protein kinase C activity was elevated and an increase in the amount of protein kinase C-alpha was observed in membranes from erythrocytes exposed to concentrations of lead acetate above 100 nM. No changes, however, in the activities of cAMP-dependent protein kinase, protein phosphatases I and IIA or casein kinase were observed. Phosphorylation of these membrane proteins stimulated by lead acetate or by PMA was not observed in erythrocytes depleted of protein kinase C by a 72-h treatment with 500 nM phorbol 12,13-dibutyrate. Finally, no changes in the levels of calcium or diacylglycerol were observed in erythrocytes stimulated with 100 nM lead acetate. These results indicate that, in erythrocytes, lead acetate stimulates the phosphorylation of membrane cytoskeletal proteins by a mechanism dependent on protein kinase C. Since levels of calcium or diacylglycerols did not increase, it appears that lead may activate the enzyme by a direct interaction.

Benzene exposure, assessed by urinary trans,trans-muconic acid, in urban children with elevated blood lead levels.

A pilot study was performed to evaluate the feasibility of using trans,trans-muconic acid (MA) as a biomarker of environmental benzene exposure. A secondary aim was to provide data on the extent of exposure to selected toxicants in a unique population consisting of inner-city children who were already overexposed to one urban hazard, lead. Potential sources of benzene were assessed by a questionnaire. Exposure biomarkers included urinary MA and cotinine and blood lead. Mean MA was 176.6 +/- 341.7 ng/mg creatinine in the 79 children who participated. A wide range of values was found with as many as 10.1%, depending on the comparison study, above the highest levels reported in adults not exposed by occupation. Mean MA was increased in children evaluated in the afternoon compared to morning, those at or above the median for time spent playing near the street, and those studied in the first half of the investigation. MA levels were not associated with blood lead or, consistently, with either questionnaire environmental tobacco smoke (ETS) data or cotinine. As expected, the mean blood lead level was elevated (23.6 micrograms/dl). Mean cotinine was also increased at 79.2 ng/mg creatinine. We conclude that the use of MA as a biomarker for environmental benzene exposure is feasible since it was detectable in 72% of subjects with a wide range of values present. In future studies, correlation of MA with personal air sampling in environmental exposure will be essential to fully interpret the significance of these findings. In addition, these inner-city children comprise a high risk group for exposure to environmental toxicants including ETS, lead, and probably benzene, based on questionnaire sources and its presence in ETS.

Enhanced endothelial cell adhesion of human cerebrospinal fluid lymphocytes.

Lymphocyte migration into a tissue depends on properties of both the lymphocyte and the tissue's vascular endothelium. The central nervous system (CNS) possesses a specialized microvasculature and lymphocytes appear to enter the CNS less readily than peripheral tissues. We investigated whether those lymphocytes that interact with the CNS, as represented by cerebrospinal fluid (CSF)-derived lymphocytes, express adhesive properties distinct from peripheral blood lymphocytes (PBLs). Adhesion of human lymphocytes to bovine endothelial cell monolayers was quantitated microscopically. A greater number of PBLs adhered to aortic than to retinal endothelial cell cultures (e.g., 10.9 +/- 0.6 and 4.5 +/- 0.2, respectively; p = 0.0023). Preincubation of either endothelial cell type with tumor necrosis factor-alpha (TNF-alpha) enhanced lymphocyte adhesion. Activation of PBLs with concanavalin A or phytohemagglutinin increased endothelial cell adhesion and the effect was additive with that of TNF-alpha. The number of CSF lymphocytes adhering to endothelial cell cultures (retinal, 67.5 +/- 9.0; aortic, 83.7 +/- 10.6) was more than 10 times the number of PBLs (retinal, 5.4 +/- 0.8; aortic, 8.0 +/- 1.3; p < 0.0001). CSF lymphocytes did not, however, adhere preferentially to CNS-derived endothelial cell cultures. These results suggest that CSF may be enriched, compared with peripheral blood, in its content of surveillance lymphocytes, but that these cells might enter target tissues nonspecifically.

Endothelial cell implantation and survival within experimental gliomas.

The delivery of therapeutic genes to primary brain neoplasms opens new opportunities for treating these frequently fatal tumors. Efficient gene delivery to tissues remains an important obstacle to therapy, and this problem has unique characteristics in brain tumors due to the blood-brain and blood-tumor barriers. The presence of endothelial mitogens and vessel proliferation within solid tumors suggests that genetically modified endothelial cells might efficiently transplant to brain tumors. Rat brain endothelial cells immortalized with the adenovirus E1A gene and further modified to express the beta-galactosidase reporter were examined for their ability to survive implantation to experimental rat gliomas. Rats received 9L, F98, or C6 glioma cells in combination with endothelial cells intracranially to caudate/putamen or subcutaneously to flank. Implanted endothelial cells were identified by beta-galactosidase histochemistry or by polymerase chain reaction in all tumors up to 35 days postimplantation, the latest time examined. Implanted endothelial cells appeared to cooperate in tumor vessel formation and expressed the brain-specific endothelial glucose transporter type 1 as identified by immunohistochemistry. The proliferation of implanted endothelial cells was supported by their increased number within tumors between postimplantation days 14 and 21 (P = 0.015) and by their expression of the proliferation antigen Ki67. These findings establish that genetically modified endothelial cells can be stably engrafted to growing gliomas and suggest that endothelial cell implantation may provide a means of delivering therapeutic genes to brain neoplasms and other solid tumors. In addition, endothelial implantation to brain may be useful for defining mechanisms of brain-specific endothelial differentiation.

Development of endogenous beta-galactosidase and autofluorescence in rat brain microvessels: implications for cell tracking and gene transfer studies.

Cell transplantation is commonly used in studies of CNS development, tumor biology, and gene therapy. Fluorescent dyes and the E. coli lacZ reporter gene are used to identify transplanted cells in host tissues. The usefulness of these methods depends on host autofluorescence and beta-galactosidase (beta-Gal) activity. Our interest in the CNS vasculature led us to examine vascular autofluorescence and beta-Gal activity in postnatal and adult rat brains. Brains were perfusion-fixed (3.7% paraformaldehyde), cryoprotected, and cryostat-sectioned (12 microns). Autofluorescent vessel profiles were quantitated in sections using rhodamine filter sets and beta-Gal-positive vessels were quantitated under bright-field after incubation of sections with X-Gal chromogenic substrate for 1-18 hr at 37 degrees C. Multifocal vessel autofluorescence appeared in postnatal Day (PND) 18 Lewis rats (0.6 +/- 0.4 vessels/field) and increased tenfold in adults (6.8 +/- 0.3/field). The numbers of beta-Gal-positive vessels in PND 18 and adult sections incubated with X-Gal for 18 hr were 21.1 +/- 1.7 and 119 +/- 17, respectively. Host beta-Gal staining was similar to that produced by implanted endothelial cells expressing the bacterial lacZ reporter gene. Reducing incubation times in X-Gal to less than 4 hr eliminated endogenous staining and retained lacZ-specific staining. The presence of vascular autofluorescence and endogenous beta-Gal activity must be considered when either fluorescence- or lacZ-dependent cell markers are used in rat brain.

Phospholipid metabolism in neural microvascular endothelial cells after exposure to lead in vitro.

Lead (Pb2+) is known to alter the permeability of brain capillaries. A possible mechanism for this alteration may be related to the ability of Pb2+ to substitute for Ca2+. Products derived from phospholipid metabolism, namely eicosanoids and diacylglycerol, control endothelial permeability, are partly regulated by intracellular Ca2+, and thus may be sensitive to Pb2+. We asked in this study whether Pb2+ increased arachidonic acid release or stimulated phosphatidylcholine breakdown in an in vitro model of brain capillaries, namely cultured bovine retinal endothelial (BRE) cells. Pb2+ stimulated arachidonic acid release and phosphatidylcholine and phosphatidylinositol metabolism in the presence of ionomycin, but not by itself. More arachidonic acid was released than phosphorylcholine in BRE cells stimulated with ionomycin and Pb2+, but the magnitudes of these responses were similar in cells exposed to ionomycin plus Ca2+. Ionomycin plus Pb2+ or plus Ca2+ resulted in the activation of phospholipase A2, since an increase in lysophosphatidylcholine and arachidonic acid was observed. Protein kinase C was not required for arachidonic acid release because release was observed in cells with a down-regulated enzyme. Ionomycin plus other metals (La3+, Cd2+, or Mg2+) did not result in arachidonic acid release, but Cd2+ or Co2+ inhibited arachidonic acid release by more than 80% when cells were exposed to ionomycin with either Pb2+ or Ca2+. Thapsigargin or maitotoxin plus Ca2+ increased arachidonic acid release that was inhibited by the receptor-dependent calcium channel antagonist SK&F 96365 but not by the voltage-dependent calcium channel antagonist nifedipine. However, thapsigargin or maitotoxin plus Pb2+ failed to stimulate arachidonic release. Since in this in vitro model Pb2+ stimulated phospholipid metabolism solely in the presence of an ionophore, the increase in permeability observed in Pb(2+)-exposed animals is probably not due to a release of metabolites of arachidonic acid.

Regulation of in vitro glia-induced microvessel morphogenesis by urokinase.

Plasminogen activators (PAs) regulate a variety of processes involved in tissue morphogenesis and differentiation. We used a coculture system in which microvascular endothelial cells are induced by glial cells to form capillary-like structures in order to examine the role of urokinase-type PA (uPA) during microvessel morphogenesis within the central nervous system (CNS). Endothelia-derived uPA activity decreased sevenfold within glial-endothelial cocultures when capillary-like structures were formed. Incubation of cocultures with concentrations of phorbol 12-myristate 13-acetate (0.1 and 1.0 nM) that induced endothelial uPA activity (45-210%) inhibited endothelial differentiation (25-70%). Furthermore, incubation of cocultures with proteolytically active low molecular weight uPA (5-500 IU/ml) inhibited endothelial differentiation (37-75%), whereas the amino terminal cell-binding fragment of uPA had minimal effect. Inhibition of plasminogen activation in cocultures with the serine protease/plasmin inhibitors aprotinin and soybean trypsin inhibitor increased glia-induced capillary-like structure formation (96-98%). These findings establish a paracrine/autocrine function for urokinase and its inhibitors in regulating endothelial responses to perivascular glia and provide insight into mechanisms of microvascular reactions to CNS pathology.

Dexamethasone reduces vascular density and plasminogen activator activity in 9L rat brain tumors.

Angiogenesis, a process dependent upon perivascular proteolysis, is required for solid tumor growth and is inhibited by certain steroids including glucocorticoids. We examined the relationship between tumor growth and vessel density in experimental rat brain 9L glial tumors following chronic treatment with the glucocorticoid dexamethasone. Tumor growth was inhibited by intraperitoneal administration of 3 mg/kg/day dexamethasone. Maximal cross-sectional areas of post-implantation day 9 tumors were 4.6 +/- 1.0 mm2 in dexamethasone-treated animals and 17.0 +/- 3.4 mm2 in controls (P < 0.01). Microvessel density assessed by laminin immunohistochemistry was 59% lower in dexamethasone-treated tumors (P < 0.01). Plasminogen activator (PA) activity, a proteolytic enzyme related to endothelial migration and vessel growth, was 4.2 +/- 0.9 IU/micrograms protein in dexamethasone-treated tumors and 9.0 +/- 1.0 IU/micrograms protein in control tumors (P < 0.01). Exposure of cultured 9L and central nervous system microvessel endothelial cells to dexamethasone concentrations comparable to those achieved in vivo had no effect on cell growth, but reduced the PA activity of culture supernatant fractions by 78% and 99%, respectively. These findings suggest that inhibition of proteolytic steps involved in vessel growth may underlie, in part, the mechanism by which glucocorticoids decrease brain tumor growth.

Evidence that lead acts as a calcium substitute in second messenger metabolism.

Our investigations of the ability of lead to substitute for calcium in several intracellular regulatory events are reviewed in the context of the neurotoxicity produced by this heavy metal. We found that lead activates calmodulin dependent phosphodiesterase, calmodulin inhibitor sensitive potassium channels, and calmodulin independent protein kinase C (PKC). Because of sensitivity in the picomolar range, the activation of PKC by lead may be more biologically relevant than its activation of calmodulin which requires high nanomolar levels of the toxicant. We also found that inhibition of capillary-like structure formation in co-cultures of neural endothelial cells with astrocytes by lead was similar to that produced by phorbol esters, known stimulators of PKC. This functional event supports the hypothesis that PKC activation underlies some aspects of lead neurotoxicity. Taken together these studies implicate second messenger metabolism and protein kinase activation as potential sites for the disruptive action of lead upon nervous system function. These reactions could contribute to the subtle defects in brain function associated with low level poisoning.

Inhibition of astroglia-induced endothelial differentiation by inorganic lead: a role for protein kinase C.

Microvascular endothelial function in developing brain is particularly sensitive to lead toxicity, and it has been hypothesized that this results from the modulation of protein kinase C (PKC) by lead. We examined the effects of inorganic lead on an in vitro model of central nervous system endothelial differentiation in which astroglial cells induce central nervous system endothelial cells to form capillary-like structures. Capillary-like structure formation within C6 astroglial-endothelial cocultures was inhibited by lead acetate with 50% maximal inhibition at 0.5 microM total lead. Inhibition was independent of effects on cell viability or growth. Under conditions that inhibited capillary-like structure formation, we found that lead increased membrane-associated PKC in both C6 astroglial and endothelial cells. Prolonged exposure of C6 cells to 5 microM lead for up to 16 h resulted in a time-dependent increase in membranous PKC as determined by immunoblot analysis. Membranous PKC increased after 5-h exposures to as little as 50 nM lead and was maximal at approximately 1 microM. Phorbol esters were used to determine whether PKC modulation was causally related to the inhibition of endothelial differentiation by lead. Phorbol 12-myristate 13-acetate (10 nM) inhibited capillary-like structure formation by 65 +/- 5%, whereas 4 alpha-phorbol 12,13-didecanoate was without effect. These findings suggest that inorganic lead induces cerebral microvessel dysfunction by interfering with PKC modulation in microvascular endothelial or perivascular astroglial cells.

Effect of elevated ambient glucose upon polyphosphoinositide turnover in bovine retinal endothelial cells and rat astrocytes.

We investigated the turnover of polyphosphoinositides in bovine retinal microvascular endothelial cells and rat astrocytes cultured in the presence of high ambient concentrations of glucose in order to study the possible involvement of this pathway in the pathogenesis of diabetic retinopathy. a 35-45% decrease in the amount of 32P incorporated into phosphatidylinositol(4)phosphate (PIP) and phosphatidyl-inositol(4,5)biphosphate (PIP2) occurred in rat astrocytes but not bovine retinal endothelial cells grown for 14 +/- 3 days in a medium with an elevated (28 mM) glucose concentration. Incorporation of 32P into phosphatidylinositol, phosphatidylcholine, phosphatidylserine and phosphatidylethanolamine was not altered by these conditions. A 39-45% decrease in 32P incorporated into PIP/PIP2 was also found in rat astrocytes grown in 28 mM glucose which were detergent solubilized and incubated with [32P]ATP. Exposure to elevated concentrations of glucose decreased the amount of PIP/PIP2 cleaved by ionomycin or fluoroaluminate treatment, but did not disturb phospholipase C activity. Thus, the lower level of PIP/PIP2, induced by exposure to elevated concentrations of glucose, appears due to changes in phospholipid substrate levels, or polyphosphoinositide kinase activity, rather than a decrease in ATP levels or phospholipase C activity. These results suggest that high ambient glucose levels alter second-messenger generation by astrocytes. In turn, cellular interactions dependent upon these second messengers and important for maintenance of normal microvessel function in the retina may be disrupted.