Thyroid hormone stimulates hepatic lipid catabolism via activation of autophagy.

For more than a century, thyroid hormones (THs) have been known to exert powerful catabolic effects, leading to weight loss. Although much has been learned about the molecular mechanisms used by TH receptors (TRs) to regulate gene expression, little is known about the mechanisms by which THs increase oxidative metabolism. Here, we report that TH stimulation of fatty acid ß-oxidation is coupled with induction of hepatic autophagy to deliver fatty acids to mitochondria in cell culture and in vivo. Furthermore, blockade of autophagy by autophagy-related 5 (ATG5) siRNA markedly decreased TH-mediated fatty acid ß-oxidation in cell culture and in vivo. Consistent with this model, autophagy was altered in livers of mice expressing a mutant TR that causes resistance to the actions of TH as well as in mice with mutant nuclear receptor corepressor (NCoR). These results demonstrate that THs can regulate lipid homeostasis via autophagy and help to explain how THs increase oxidative metabolism.

Clinically reported heterozygous mutations in the PINK1 kinase domain exert a gene dosage effect.

Mutations in the gene encoding phosphatase and tensin homolog (PTEN)-induced kinase 1 (PINK1) have been associated with the loss of dopaminergic neurons characteristic of familial and sporadic Parkinson disease. We developed an in vitro system of stable human dopaminergic neuronal cell lines coexpressing an equivalent copy of normal and mutant PINK1 to simulate "heterozygous" and "homozygous" states in patients. Mutants in the N-terminus, C-terminus, and kinase domain were generated and cloned into a two-gene mammalian expression vector to generate stable mammalian expression cell lines producing an equivalent copy number of wild-type/mutant PINK1. The cell lines were subjected to oxidative stress and the rate of apoptosis and change in mitochondrial membrane potential (DeltaPsi(m)) were assessed. Cell lines expressing kinase and C-terminus mutants exhibited a greater rate of apoptosis and decrease in DeltaPsi(m), and increased time-dependent cell loss when subjected to oxidative stress compared to the wild-type. Cell lines expressing two copies of kinase mutants exhibited a greater apoptosis rate and DeltaPsi(m) decrease than those expressing one copy of the mutant. In time-dependent experiments, there was a significant difference between "homozygous," "heterozygous," and wild-type cell lines, with decreasing cell survival in cell lines expressing mutant copies of PINK1 compared to the wild-type. We provided the first experimental evidence that clinically reported PINK1 heterozygous mutations exert a gene dosage effect, suggesting that haploinsufficiency of PINK1 is the most likely mechanism that increased the susceptibility to dopaminergic cellular loss.

Evidence for selective expression of the p53 codon 72 polymorphs: implications in cancer development.

Polymorphism at codon 72 of p53 results in either the arginine or proline form of p53, whose functional significance in carcinogenesis is controversial. We have investigated if the expression of these p53 polymorphs is selectively regulated, using mRNA from peripheral blood of healthy Asian (Chinese) and the Caucasian (Polish) arginine/proline (arg/pro) heterozygote subjects. Asians were found to preferentially express the pro allele whereas the Caucasians preferentially express the arg allele. On the contrary, about 75% of the heterozygote Chinese breast cancer patients preferentially expressed the arg allele, which rarely contained any somatic mutations. Moreover, histologically normal tissues from Chinese heterozygote breast cancer patients showed selective expression of the arg allele, in contrast to the preferential expression of the pro allele in heterozygote healthy normal breast tissues. Together, the data suggest that the expression of the different p53 polymorphs is selectively regulated in different ethnic populations, and that the arg allele is activated during cancer development in Asians. Thus, the expression status of the p53 polymorphs, rather than the genotypic status, might be a useful indicator for cancer susceptibility.

Evaluation of the combined effect of p53 codon 72 polymorphism and hotspot mutations in response to anticancer drugs.

Mutations in p53 are common events during carcinogenesis and have been suggested to affect sensitivity to chemotherapy. Recently, the common polymorphism at codon 72, resulting in either an arginine (72R) or proline (72P) residue, was shown to differentially affect the response to anticancer drugs. Here, we have generated isogenic lung cancer cell lines to evaluate the effect of six p53 hotspot mutations (R175H, G245S, R248W, R249S, R273H, and R282W) in conjunction with the codon 72 polymorphism, for their response to a variety of anticancer drugs, either alone or in combination. The data indicate that 72R mutations do not confer general resistance to cisplatin, etoposide, gemcitabine, vinblastine, and taxol. For doxorubicin, cells expressing 249-72R were more resistant than the 249-72P cells. Combined treatment with cisplatin + etoposide resulted in an additive effect in cells expressing most 72R and 72P mutations, except for the 175-72R cells which were refractory to combined treatment. However, combined treatment with cisplatin + gemcitabine resulted in the absence of an additive effect in cells expressing the 273-72R and 282-72R mutants, unlike their 72P counterparts. Nonetheless, all p53 mutants (72R or 72P) equally inhibited p73-mediated transcriptional activity in lung cancer cells, suggesting that the selective resistance conferred by some 72R mutants to certain drugs is probably due to other p73-independent effects of these mutants. Together, the data show that the status of codon 72 polymorphism and p53 mutations can be used as a means for prediction of treatment response, although variables for each cancer type requires detailed evaluation.