Beta 2-microglobulin expression in human embryonal neuroblastoma reflects its developmental regulation.

Class I major histocompatibility complex (MHC) antigen expression in neuroblastoma may play a role in the oncogenicity of this embryonal tumor of childhood. Since N-myc amplification in neuroblastoma tumors is associated with rapid tumor progression (33) and N-myc decreases Class I MHC antigen expression in rat neuroblastoma cells (21), we quantitated levels of N-myc mRNA and Class I MHC cell surface antigens in a panel of 24 human neuroblastoma cell lines. We found that N-myc expression is not invariably associated with low levels of beta 2-microglobulin (B2M) and Class I MHC antigen expression. As we considered that Class I MHC antigens may be regulated in association with the differentiation stage of the neuroblastoma tumor, we examined the expression of B2M during development of the human adrenal medulla, the tissue of origin of most neuroblastomas. We found that B2M is a marker of differentiated adrenal medullary cells, expressed late during the third trimester of development. Moreover, using morphological and immunological criteria, we found that B2M is expressed in differentiated tumor cells. These data suggest that the expression of B2M in neuroblastoma is associated with the stage of differentiation of the tumor cell and not N-myc expression. Furthermore, these findings suggest that neuroblastomas may correspond to the arrested differentiation of adrenal neuroblasts at different stages of development.

Human neuroblastoma tumor cell lines correspond to the arrested differentiation of chromaffin adrenal medullary neuroblasts.

We have examined the hypothesis that nonhematopoietic malignancies may contain cells corresponding to those which occur during the differentiation of tissue precursors. Neuroblastoma, an embryonal tumor of the adrenal medulla, was studied because of its well described ability to differentiate both in vivo and in vitro. We examined the expression of four genes during development of the human adrenal medulla: tyrosine hydroxylase, chromagranin A, pG2, and beta-2-microglobulin. The sequential expression of these genes by adrenal neuroblasts marks successive stages during maturation of the chromaffin lineage. We also observed a population of neuroblasts during adrenal medullary development that did not express any of these four genes, suggestive of adrenal medullary cells differentiating along nonchromaffin lineage(s). We then evaluated 27 neuroblastoma cell lines for the expression of these genes and found that 24 expressed chromaffin markers, with 19 of these mimicking the pattern of gene expression found during development. Three cell lines did not express tyrosine hydroxylase, chromogranin A, or pG2, consistent with either a very undifferentiated neural crest cell or maturation along a nonchromaffin lineage. These data indicate that neuroblastoma tumor cells correspond to adrenal neuroblasts arrested during morphogenesis of the adrenal medulla and raise the possibility that malignant transformation of cells at different stages of tissue maturation may contribute to the diversity that characterizes tumors of solid tissues.

Acidic fibroblast growth factor accelerates dermal wound healing.

Acidic fibroblast growth factor (aFGF) is a potent mitogen in vitro for many cells of ectodermal and mesodermal embryonic origin including skin-derived epidermal keratinocytes, dermal fibroblasts and vascular endothelial cells. Based on the mitogenic activity for these skin-derived cells, we tested the ability of topically applied aFGF to promote healing of full-thickness dermal wounds in healthy rodents. Low doses of aFGF can produce almost a two-fold maximum acceleration in the rate of closure of full-thickness dermal punch biopsy wounds in young healthy mice and rats. The mitogen also produces a 3 to 4 day acceleration in the time to complete closure in rats. Quantitative histomorphometric analysis of wound tissue shows that aFGF induces a marked stimulation of angiogenesis, granulation tissue formation and the growth of new epithelium, but does not promote dermal contraction. Application of aFGF to linear incisions in rat skin produces a transient increase in wound tensile strength accompanied by enhanced cellularity and deposition of collagen. Therefore, aFGF functions as a pharmacological agent that can accelerate dermal wound healing in rodents and could act therapeutically to promote dermal tissue repair in humans.