A differential proteomic approach to identify proteins associated with thyroid cell transformation.

Tumour suppressor p53 is a transcription factor essential for DNA damage checkpoints during cellular response to stress. Mutations in the p53 gene are the most common genetic alterations found in human tumours; most pathogenetic modifications are missense mutations that abolish the p53 DNA-binding function. In the same cell type, distinct p53 missense mutations may determine different phenotypes. The PC Cl3 cell line retains several markers of thyroid differentiation in vitro. Introduction of the V143A mutant p53 allele, which abolishes the p53 DNA-binding function, leads to loss of differentiation markers as well as TSH dependency for growth. Conversely, PC Cl3 cells transfected with the S392A mutant p53 allele, presenting the mutation located outside the DNA-binding domain, show only loss of TSH dependency for growth. To identify molecular differences existing between PC Cl3 cell lines transformed by the V143A and the S392A mutant alleles, a differential proteomic approach was used. Two-dimensional gel electrophoresis analyses indicated that expression of a significant portion of protein species was modified by both p53 mutants. In fact, compared with wild-type PC Cl3 cells, modification of expression in V143A mutant cells occurred in 23.6% of the entire protein species. Conversely, modification of S392A mutant cells affected 14.0% of total proteins. Among these components, 8.3% were common to both mutants. Several of these proteins were identified by mass spectrometry procedures; some proteins, such as HSP90 and T-complex proteins, are already known to be related to p53 function.

Missense mutations of human homeoboxes: A review.

The homeodomain (encoded by the homeobox) is the DNA-binding domain of a large variety of transcriptional regulators involved in controlling cell fate decisions and development. Mutations of homeobox-containing genes cause several diseases in humans. A variety of missense mutations giving rise to human diseases have been described. These mutations are an excellent model to better understand homeodomain molecular functions. To this end, homeobox missense mutations giving rise to human diseases are reviewed. Seventy-four independent homeobox mutations have been observed in 17 different genes. In the same genes, 30 missense mutations outside the homeobox have been observed, indicating that the homeodomain is more easily affected by single amino acids changes than the rest of the protein. Most missense mutations have dominant effects. Several data indicate that dominance is mostly due to haploinsufficiency. Among proteins having the homeodomain as the only DNA-binding domain, three "hot spot" regions can be delineated: 1) at codon encoding for Arg5; 2) at codon encoding for Arg31; and 3) at codons encoding for amino acids of recognition helix. In the latter, mutations at codons encoding for Arg residues at positions 52 and 53 are prevalent. In the recognition helix, Arg residues at positions 52 and 53 establish contacts with phosphates in the DNA backbone. Missense mutations of amino acids that contribute to sequence discrimination (such as those at positions 50 and 54) are present only in a minority of cases. Similar data have been obtained when missense mutations of proteins possessing an additional DNA-binding domain have been analyzed. The only exception is observed in the POU1F1 (PIT1) homeodomain, in which Arg58 is a "hot spot" for mutations, but is not involved in DNA recognition.

Mitochondrial localization of APE/Ref-1 in thyroid cells.

Mutations of mitochondrial DNA (mtDNA) are associated with different human diseases, including cancer and aging. Reactive oxygen species produced during oxidative phosphorylation are a major source of mtDNA damage. It is not clear, however, whether DNA repair mechanisms, able to abolish effects due to oxidative damage, are present in mitochondria. APE/Ref-1 is a nuclear protein possessing both redox activity (by which activates, "in vitro", the DNA-binding functions of several transcription factors) and DNA repair activity over apurinic/apyrimidinic sites. Immunohistochemical evidences indicate that in follicular thyroid cells, APE/Ref-1 is located in both nucleus and cytoplasm. Electronmicroscopy immunocytochemistry performed in the rat thyroid FRTL-5 cell line, indicates that part of the cytoplasmatic APE/Ref-1 is located in mitochondria. The presence of APE/Ref-1 inside mitochondria is further demonstrated by western blot analysis after cell fractionation. In the Kimol cell line (which is derived from FRTL-5, transformed by the Ki-ras oncogene) the amount of mitochondrial APE/Ref-1 is reduced by three to fourfold with respect to the normal FRTL-5 cells. These results suggest that: (i) a machinery capable of repairing DNA damaged by oxidative stress is present in mitochondria and (ii) mtDNA repair mechanisms may be impaired during cell transformation.