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. 1987 Dec 1;6(12):3633–3639. doi: 10.1002/j.1460-2075.1987.tb02695.x

Insulin-like growth factor I in cultured rat astrocytes: expression of the gene, and receptor tyrosine kinase.

R Ballotti 1, F C Nielsen 1, N Pringle 1, A Kowalski 1, W D Richardson 1, E Van Obberghen 1, S Gammeltoft 1
PMCID: PMC553831  PMID: 2828033

Abstract

Gene expression, receptor binding and growth-promoting activity of insulin-like growth factor I (IGF I) was studied in cultured astrocytes from developing rat brain. Northern blot analysis of poly(A)+ RNAs from astrocytes revealed an IGF I mRNA of 1.9 kb. Competitive binding and receptor labelling techniques revealed two types of IGF receptor in astroglial cells. Type I IGF receptors consist of alpha-subunits (Mr 130,000) which bind IGF I with significantly higher affinity than IGF II, and beta-subunits (Mr 94,000) which show IGF I-sensitive tyrosine kinase activity. Type II IGF receptors are monomers (Mr 250,000) which bind IGF II with three times higher affinity than IGF I. Both types of IGF receptor recognize insulin weakly. DNA synthesis measured by cellular thymidine incorporation was stimulated 2-fold by IGF I and IGF II. IGF I was more potent than IGF II, and both were significantly more potent than insulin. Our findings suggest that IGF I is synthesized in fetal rat astrocytes and acts as a growth promoter for the same cells by activation of the type I IGF receptor tyrosine kinase. We propose that IGF I acts through autocrine or paracrine mechanisms to stimulate astroglial cell growth during normal brain development.

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