Involvement of the pituitary-specific transcription factor pit-1 in somatolactotrope cell growth and death: an approach using dominant-negative pit-1 mutants.

The anterior pituitary-specific transcription factor Pit-1 was initially identified and cloned as a transactivator of the prolactin (PRL) and GH genes and later as a regulator of the TSHb gene. It was found to be a major developmental regulator, because natural Pit-1 gene mutations cause a dwarf phenotype in mice and cause combined pituitary hormone deficiency associated with pituitary hypoplasia in humans. To further investigate the growth-promoting effects of Pit-1, we used a strategy based on the use of dominant-negative Pit-1 mutants as an alternative means of inactivating endogenous Pit-1 functions. R271W, a Pit-1 mutant identified in one allele in patients with severe combined pituitary hormone deficiency, and Pit-1Delta1-123, a deletion mutant in which only the DNA binding domain of Pit-1 is conserved, were generated, and their ability to abolish the effects of the endogenous native Pit-1 in the differentiated proliferating somatolactotrope GH4C1 cell line was investigated. Enforced expression of the dominant-negative mutants in GH4C1 cells using recombinant lentiviral vectors decreased the levels of expression of known Pit-1 target genes such as PRL and GH, abolished the hormone release, and reduced cell viability by decreasing the growth rate and inducing apoptosis via a caspase-independent pathway. These results show for the first time that the growth-promoting effects of Pit-1 are at least partly due to the fact that this transcription factor prevents apoptotic cell death.

Competition between calnexin and BiP in the endoplasmic reticulum can lead to the folding or degradation of human thyroperoxidase.

Previous studies on the fate of human thyroperoxidase (hTPO) molecules have shown that, after being synthesized, these glycoproteins interact with calnexin and calreticulin and that only some of them are able to acquire a partially folded structure. The aim of the present study was to further investigate the potential role of BiP, another major protein chaperon. Co-immunoprecipitation experiments showed the occurrence of interactions between hTPO and BiP. Pulse-chase studies showed that, when hTPO was expressed in a Chinese hamster ovary cell line overexpressing 5 times more BiP than the parent cells, the rate of hTPO recognized by a monoclonal antibody directed against a conformational structure decreased by 50% after 5 h of chase. Overexpression of the BiP-ATPase mutant G37T also led to a decrease in the correct folding rate of hTPO. When this protein was pulsed in the presence of 35S-(Met + Cys) and the reducing agent dithiotreitol and then chased in a culture medium without dithiothreitol, a 2.5-fold decrease in the correct folding rate was observed in cells overexpressing BiP, whereas co-overexpression of calnexin and Erp57 led to an increase in both the unfolded and partially folded form of hTPO after the pulse step. All of these findings show that BiP and calnexin have opposite effects on the folding behavior of hTPO and that the action of specific molecular chaperones may therefore crucially determine the fate of glycoproteins.

Endoproteolytic cleavage of human thyroperoxidase: role of the propeptide in the protein folding process.

Human thyroperoxidase (hTPO), the key enzyme involved in thyroid hormone synthesis, is synthesized in the form of a 933-amino acid polypeptide that subsequently undergoes posttranslational modifications such as N- and O-glycosylation and heme fixation. In the present study, it was established that the N-terminal part of hTPO is cleaved during the maturation of the enzyme. In the first set of experiments performed in this study, Chines hamster ovary (CHO) cells transfected with hTPO cDNA generated four different species after deglycosylation, namely a 98-kDa species, which corresponds to the full-length deglycosylated hTPO, and two 94-kDa and one 92-kDa species, which were truncated in the N-terminal parts. The three latter forms were detected only at the cell surface. A proprotein convertase inhibitor prevented these cleavages, and experiments using monensin and brefeldin A showed that they occurred in a post-endoplasmic reticulum compartment. Site-directed mutagenesis studies were performed in which Arg65 was identified as one of the cleavage sites. In the second part of the study, hTPO from human thyroid glands was purified using a monoclonal antibody recognizing the folded form of hTPO. Amino acid determination showed that the N-terminal part of this protein begins at Thr109. This cleavage process differs from that observed in CHO cells. The fact that this hTPO was endoglucosaminidase H-sensitive indicated that the cleavage of the propeptide occurs in the endoplasmic reticulum. To analyze the role of the hTPO prosequence, cDNAs with and without prosequence (Cys15-Lys108) were transfected into CHO cells. hTPO propeptide deletion drastically decreased the proportion of the folded hTPO form, and under these conditions the cell surface activity disappeared completely. These results strongly suggest that the prosequence plays a crucial role as an intramolecular chaperone, facilitating the folding of hTPO.

Differential expression of thyroperoxidase mRNA splice variants in human thyroid tumors.

The levels of human thyroperoxidase (hTPO) mRNA expression and the rates of hTPO mRNA with alternatively spliced exons 10, 14, and 16 were analyzed in normal, benign, and malignant thyroid tissues (13 normal thyroid tissues, 9 adenomas, 4 papillary carcinomas, 11 follicular variant of papillary carcinomas, 16 minimally invasive follicular carcinomas, 6 widely invasive follicular carcinomas) using a semi-quantitative reverse-transcription polymerase chain reaction procedure. The level of hTPO mRNA decreased in the follicular variant of papillary carcinomas and in minimally invasive follicular carcinomas and was more heterogeneous in the other pathological tissues than in normal tissues. Based on the mean values recorded, the splicing of exons 10 and 16 increased by at least 50% in all the carcinomas, as well as in the benign tissues in the case of exon 10. By contrast, no significant increase was observed in the splicing of exon 14 except in the case of the follicular variant of papillary carcinomas. In conclusion, the results of this study show that the splicing of hTPO increases in benign and malignant thyroid tissues. This event might partly explain the decrease in both the quantity and the level of activity of hTPO observed in thyroid cancer due to the loss of stability of the spliced isoforms. In addition, an increase in the alternative splicing of other mRNAs may contribute to the process of malignancy.

Increasing diversity of human thyroperoxidase generated by alternative splicing. Characterized by molecular cloning of new transcripts with single- and multispliced mRNAs.

The human thyroperoxidase (hTPO) gene is composed of 17 exons. The longest complete cDNA sequence determined so far contains a full-length hTPO (TPO1) encoding a 933-amino acid polypeptide. Several mRNA species encoding for hTPO isoforms are present in normal thyroid tissues, including TPO2 with exon 10 deleted and TPOzanelli with exon 16 deleted. In the present study, we established the existence of two new single-spliced transcripts, TPO4 and TPO5, lacking exons 14 and 8, respectively. Upon transfecting the TPO4 cDNA into Chinese hamster ovary cells, it was observed that TPO4 is able to reach the cell surface, is enzymatically active, and is able to be recognized by a panel of 12 monoclonal antibodies directed against hTPO, whereas TPO5 does not fold correctly and is unable to reach the cell surface. In normal tissues, the expression of TPO4 mRNA was examined by performing quantitative reverse transcription PCR. This deleted TPO mRNA amounted to 32 +/- 11% of the total TPO mRNAs. In the same tissues, the TPO2, TPOzanelli, and TPO5 amounted to 35 +/- 12%, 36 +/- 14%, and approximately 10%, respectively. The sum of these four species (not including TPO1) was more than 100%, possibly due to the presence of multispliced mRNAs. This possibility was tested, and three new variants were identified: TPO2/3, lacking exons 10 and 16, TPO2/4, lacking exons 10 and 14, and an unexpected variant, TPO6, corresponding to the deletion of exons 10, 12, 13, 14, and 16. In conclusion, these results indicate the existence of five new transcripts. One of them, TPO4, codes for an enzymatically active protein, whereas TPO5 is unable to fold correctly. The functional significance of the other newly spliced mRNA variants still remains to be elucidated, but these results might help to explain the heterogeneity of the hTPO purified from the thyroid gland.