Pathobiology of the C-cells.

This brief review of the pathobiology of C-cells has stressed cellular and molecular aspects of MTC development. In the genetic forms of MTC, an alteration in one or more genes on chromosome 10, through an as yet unknown series of events, results in initial hyperproliferation of C-cells. Subsequent genetic steps, possibly at other chromosome loci, presumably result in selected clonal transformation of the hyperproliferative C-cells at risk for tumor development. Some of these same molecular events are probably operative in the development of sporadic MTC as well. Once MTC has developed, it has the potential to undergo tumor progression events which result in loss of C-cell differentiation. Studies in a culture model of these events have revealed that activation of signal transduction pathways, similar to those active in differentiation of other neural crest-derived cells, can restore differentiation features of normal C-cells to MTC. Continued identification of the molecular factors mediating this restoration should teach us much about the relationships between general neural crest differentiation and that of normal C-cells. It will also reveal much about the pathobiology of C-cells contributing to each step of MTC development.

Low incidence of loss of chromosome 10 in sporadic and hereditary human medullary thyroid carcinoma.

Genetic linkage has been recently documented between a centromeric region of chromosome 10 and familial multiple endocrine neoplasia type II (MEN II). This syndrome consists of initial thyroid C-cell and adrenal chromaffin cell hyperplasia which result in multifocal medullary thyroid carcinomas and bilateral adrenal pheochromocytomas. Other hereditary cancers, such as retinoblastoma, appear to result from a series of genetic events involving, first the inheritance of a germ line abnormality, and subsequent loss of chromosome loci opposite this initial defect. In these cancers, this loss of the normal alleles in both familial and sporadic cases, is frequently manifest as a reduction to homozygosity for polymorphic DNA markers near the involved locus. It might then be expected that chromosome 10 regions would be lost with high frequency in tumor DNA from patients with MEN II and sporadic medullary thyroid carcinoma (MTC). We now demonstrate that only two of 16 MTC tumors studied by analysis of restriction fragment length polymorphisms for multiple regions of the short and long arms of chromosome 10 showed loci reduced to homozygosity. One of these tumors was from a patient with MEN II and the other from a patient with nonfamilial MTC. Importantly, no such chromosome 10 changes were noted in pheochromocytomas from the patient with MEN II or his sister. These findings strongly suggest that the sequence of genetic events for familial MTC is either different from that for retinoblastoma or that loss of normal alleles opposite the germ line genetic defect occurs by mechanisms other than gross loss of chromosomal material in MTC. A model is proposed suggesting that the mechanism involving loss of alleles opposite one another is operative in hereditary tumors, such as retinoblastoma, which do not arise within a setting of initial polyclonal cellular hyperplasia. In contrast, in tumors such as familial MTC and polyposis coli which arise as individual clones of neoplastic cells from a setting of preexistent polyclonal hyperplasia, the first genetic event may underlie hyperplasia, and additional events, frequently at other chromosomal loci, may cause individual clonal neoplasms.

The molecular biology of medullary thyroid carcinoma. A model for cancer development and progression.

Medullary thyroid carcinoma (MTC) is an important human cancer for the study of molecular abnormalities that underlie initiation of neoplasia and subsequent cellular changes during tumor progression. This tumor can occur in different inherited forms, each mediated by autosomal dominant genetic events. Germline abnormalities on chromosome 10 are linked to at least one type of genetic MTC, multiple endocrine neoplasia type II. Our studies of chromosome 10 in DNA from MTC tumors failed to detect frequent loss of polymorphic DNA markers, suggesting that the genetic mechanisms involved in MTC development may be different from those for other inherited cancers such as retinoblastoma. During tumor progression of MTC, abnormalities develop in expression of the mature phenotype of the endocrine cell from which the tumor arises. In cell culture, chemical modulation or gene insertion can lead to partial correction of these defects in differentiation capacity by activating cellular signaling processes. These studies offer opportunities to dissect the molecular events that regulate endocrine cell differentiation, to determine the precise abnormalities that may underlie the initiation and tumor progression events in MTC and related cancers, and, thereby, to identify new targets for therapeutic intervention.