Chronic Low‐Level Lead Exposure Impairs Embryonic to Adult Conversion of the Neural Cell Adhesion Molecule

Cookman, Gillian R.; King, William; Regan, Ciaran M.

doi:10.1111/j.1471-4159.1987.tb02879.x

Cited by 69 publications

(25 citation statements)

References 32 publications

(24 reference statements)

Supporting

Mentioning

Contrasting

Unclassified

Order By: Relevance

“…Effects on gross brain structure have not been evident in studies directed at understanding underlying neuropathology associated with low-level lead exposure. Instead, the effects most consistently noted are those on synaptogenesis and dendritic arborization (42)(43)(44)(45)(46), in vivo physiological examinations of synaptic plasticity (47)(48)(49), and decrements in myelination (50,51). Changes in glutamate and y-aminobutyric acid synthesis and release (52,53) and the glutamate N-methyl-Daspartate (NMDA) receptor levels and binding affinities have also been reported in association with low-level lead exposure (54).…”

Section: Distinctive Neural Systems Havementioning

confidence: 99%

Workshop to identify critical windows of exposure for children's health: neurobehavioral work group summary.

Adams

Barone

LaMantia

et al. 2000

Environ Health Perspect

View full text Add to dashboard Cite

This paper summarizes the deliberations of a work group charged with addressing specific questions relevant to risk estimation in developmental neurotoxicology. We focused on eight questions. a) Does it make sense to think about discrete windows of vulnerability in the development of the nervous system? If it does, which time periods are of greatest importance? b) Are there cascades of developmental disorders in the nervous system? For example, are there critical points that determine the course of development that can lead to differences in vulnerabilities at later times? c) Can information on critical windows suggest the most susceptible subgroups of children (i.e., age groups, socioeconomic status, geographic areas, race, etc.)? d) What are the gaps in existing data for the nervous system or end points of exposure to it? e) What are the best ways to examine exposure-response relationships and estimate exposures in vulnerable life stages? f) What other exposures that affect development at certain ages may interact with exposures of concern? g) How well do laboratory animal data predict human response? h) How can all of this information be used to improve risk assessment and public health (risk management)? In addressing these questions, we provide a brief overview of brain development from conception through adolescence and emphasize vulnerability to toxic insult throughout this period. Methodological issues focus on major variables that influence exposure or its detection through disruptions of behavior, neuroanatomy, or neurochemical end points. Supportive evidence from studies of major neurotoxicants is provided. Key words: abnormal neurological development, behavioral teratology, behavioral testing methodology, delayed neurotoxicity, developmental disorders, developmental neurotoxicology, environmental health, neurobiological substrates of function, neuronal plasticity. -Environ Health Perspect 1 08(suppl 3): 535-544 (2000). http.//ehpnetl.niehs.nih.gov/docs/2000/suppl-3/535-544adams/abstract.html

show abstract

Section: Distinctive Neural Systems Havementioning

confidence: 99%

Workshop to identify critical windows of exposure for children's health: neurobehavioral work group summary.

Adams

Barone

LaMantia

et al. 2000

Environ Health Perspect

View full text Add to dashboard Cite

show abstract

“…These include effects on the hem biosynthesis, the nervous system, the kidneys and reproduction as well as on cardiovascular, hepatic, endocrinal and gastrointestinal functions. In conditions of low-level and long-term lead exposure, such as those found in the general population, the most critical effects are exerted on hem biosynthesis and the nervous system (Cookman et al, 1987;Freedman et al, 1990;Goyer, 1993;Juberg et al, 1997;Press, 1977). The cord blood concentration of lead represents the accumulated dose over the pregnancy period and to capture the early cognitive outcomes of lead exposure in the womb, we have chosen the Fagan test for measuring the intelligence of infants, which is a well recognized test of infant intelligence and has been found to be a predictor of later cognitive outcome Fagan et al, 1986;Fagan and Detterman, 1992).…”

Section: Introductionmentioning

confidence: 99%

Prenatal low-level lead exposure and developmental delay of infants at age 6 months (Krakow inner city study)

Jędrychowski¹,

Perera²,

Jankowski³

et al. 2008

International Journal of Hygiene and Environmental Health

View full text Add to dashboard Cite

The purpose of the study was to assess the neurocognitive status of 6-month-old infants whose mothers were exposed to low but varying amounts of lead during pregnancy. Lead levels in the cord blood were used to assess environmental exposure and the Fagan Test of Infant Intelligence (FTII) assessed visual recognition memory (VRM). The cohort consisted of 452 infants of mothers who gave birth to babies at 33-42 weeks of gestation between January 2001 and March 2003. The overall mean lead level in the cord blood was 1.42 μg/dl (95% CI: 1.35-1.48). We found that VRM scores in 6 month olds were inversely related to lead cord blood levels (Spearman correlation coefficient −0.16, p = 0.007). The infants scored lower by 1.5 points with an increase by one unit (1 μg/dl) of lead concentration in cord blood. In the lower exposed infants (≤1.67 μg/ dl) the mean Fagan score was 61.0 (95% CI: 60.3-61.7) and that in the higher exposed group (>1.67 μg/dl) was 58.4 (95% CI: 57.3-59.7). The difference of 2.5 points was significant at the p = 0.0005 level. The estimated risk of scoring the high-risk group of developmental delay (FTII classification 3) due to higher lead blood levels was two-fold greater (OR = 2.33, 95% CI: 1.32-4.11) than for lower lead blood levels after adjusting for potential confounders (gestational age, gender of the child and maternal education). As the risk of the deficit in VRM score (Fagan group 3) in exposed infants attributable to Pb prenatal exposure was about 50%, a large portion of cases with developmental delay could be prevented by reducing maternal blood lead level below 1.67 μg/dl. Although the negative predictive value of the chosen screening criterion (above 1.67 μg/dl) was relatively high (89%) its positive predictive value was too low (22%), so that the screening program based on the chosen cord blood lead criterion was recommended.

show abstract

“…In the embryonic nervous system in vivo, there is a developmentally-regulated decrease in sialyl-T activity which corresponds well with the onset of cell--cell adhesion and synaptogenesis [3,20,2 I] with subsequent alterations in the developmental expression of sialoglycoproteins causing an upset in neuronal patterning with consequent mental deficits [22,23]. Sialyl-T activity decreased significantly in parallel with the attainment of confluency in both the neuro-2A neuroblastma and C6 gtioma cell lines (Fig.…”

Section: Resultsmentioning

confidence: 99%

The control of sialyltransferase activity in tumor‐cell lines derived from different tissues is multifactorial

Coughlan

Breen

1995

FEBS Letters

View full text Add to dashboard Cite

The activities of the sialyltransferase enzymes and the resulting expression of sialoglycoproteins were examined in tumor cells derived from different tissues in order to gain a greater understanding of the factors controlling the cell glycosylation state. Cell-cell contact, which is dependent on cell confluency state, was shown to influence glycosylation in the neurallyderived mouse neuro-2A neuroblastoma and the C6 glioma cell lines. Both showed a relatively high level of cell sialyltransferase activity under sub-confluent conditions with activity decreasing upon the formation of cell-cell contacts associated with confluency. A parallel decrease in the expression of sialoglycoproteins, as determined by lectin blot analysis, was also observed under these conditions. In contrast, the H411e hepatoma cell line showed an increase in enzyme activity with confluency with the susceptibility of the enzyme in this cell line to glucocorticoid induction only being detected in sub-confluent cell cultures. The number of trypsinisation cycles of the cells was also shown to affect the enzyme activity of the neuro-2A and C6 cells with an increase in enzyme activity coincident with passage number being observed in the neuro-2A cells, and a decrease in the C6 glioma cell line. Trypsinisation had no effect on enzyme activity in the H411e cells. These results demonstrate that the control of sialyitransferase activity in tumor cells is multifactorial with the tissue of origin playing a key role.Key words: Sialyltransferase; Glycoprotein; Neuroblastoma; Hepatoma; Glioma; Sialic acid each transfer being catalysed by an individual sialyl-T isozyme [4]. Sialic acid can in addition be transferred to sialic acid residues in c~2,8 linkages to form polysialic acid chains (PSA) of up to 50 residues in length, which are expressed in a developmentally regulated manner on the neural cell adhesion molecule, NCAM [5]. The expression of protein-bound sialic acid is altered in certain tumor cell lines where it acts to influence cell adhesivity and consequently the invasive or metastatic potential of the cell [6]. Tumor cells with significant metastatic potential tend to have a high sialyl-T activity [7], and treatment of adenocarcinoma cells with an enzyme inhibitor was demonstrated to decrease metastasis [8].While the role of cellular transcription factors and oncogenes [9], and also external agents such as glucocorticoids and cytokines [10][11][12] in the control of sialyl-T activity have been well characterised, the role of cell-cell interaction in this process has not been addressed. As cell adhesion molecule (CAM) mediated cell-cell contact can activate a cellular signalling mechanism [13] and has previously been demonstrated to influence the expression of cell surface adhesion ligands [14], it was of interest to examine the effect of cell-cell contact on both basal sialyl-T expression in cell lines derived from different tissues and also to observe the enzyme susceptibility to regulation by external factors such as corticosteroids u...

show abstract

Chronic Low‐Level Lead Exposure Impairs Embryonic to Adult Conversion of the Neural Cell Adhesion Molecule

Cited by 69 publications

References 32 publications

Workshop to identify critical windows of exposure for children's health: neurobehavioral work group summary.

Workshop to identify critical windows of exposure for children's health: neurobehavioral work group summary.

Prenatal low-level lead exposure and developmental delay of infants at age 6 months (Krakow inner city study)

The control of sialyltransferase activity in tumor‐cell lines derived from different tissues is multifactorial

Contact Info

Product

Resources

About