Interactions between BRD4S, LOXL2, and MED1 drive cell cycle transcription in triple-negative breast cancer.

Triple-negative breast cancer (TNBC) often develops resistance to single-agent treatment, which can be circumvented using targeted combinatorial approaches. Here, we demonstrate that the simultaneous inhibition of LOXL2 and BRD4 synergistically limits TNBC proliferation in vitro and in vivo. Mechanistically, LOXL2 interacts in the nucleus with the short isoform of BRD4 (BRD4S), MED1, and the cell cycle transcriptional regulator B-MyB. These interactions sustain the formation of BRD4 and MED1 nuclear transcriptional foci and control cell cycle progression at the gene expression level. The pharmacological co-inhibition of LOXL2 and BRD4 reduces BRD4 nuclear foci, BRD4-MED1 colocalization, and the transcription of cell cycle genes, thus suppressing TNBC cell proliferation. Targeting the interaction between BRD4S and LOXL2 could be a starting point for the development of new anticancer strategies for the treatment of TNBC.

On the molecular relationships between high-zinc tolerance and aconitase (Aco1) in Saccharomyces cerevisiae.

Zinc is an essential metal for all organisms, as it participates in the structure and/or function of many proteins. However, zinc excess is as deleterious to cells as zinc deficiency. A genome-wide study of the transcriptomic response to high zinc in S. cerevisiae performed in our laboratory allowed the identification of a zinc hyper-tolerant deletion mutant (pif1Δ), which lacks the Pif1 DNA helicase. Further molecular characterization of this strain phenotype revealed that the lack of Pif1 leads to increased iron accumulation, redistribution of the aconitase protein to mitochondria, and also a loss of aconitase activity, despite normal Aco1 protein levels being present, probably due to the epistasis in protecting mtDNA between PIF1 and ACO1. The results presented in this work focus now on the characterization of different features related to the Aco1 protein and activity in yeast and the tolerance to high zinc. Hence, multiple phenotypic traits related to metal metabolism, namely Aco1 protein content and activity levels, succinate dehydrogenase activity, citrate levels, metal content, BPS influence in cultures, and the range of transcription of some iron metabolism related genes, have been analyzed for several strains, some of them constructed to this end, including BY4741, the deletants pif1Δ and aco1Δ, and the aco1 mutants aco1Δ-d4, aco1-C448S, aco1-R476S and aco1-R668S. Overall, lack of Aco1 enzymatic activity in mitochondria, citrate accumulation and lack of activity of [Fe-S] enzymes, e.g. succinate dehydrogenase, appear to be direct molecular indicators of increased zinc tolerance in S. cerevisiae.

Is MtnE, the fifth Drosophila metallothionein, functionally distinct from the other members of this polymorphic protein family?

Metallothioneins (MTs) are a super-family of small, Cys-rich, non-homologous proteins that bind metal ions through the formation of metal-thiolate bonds. Although universally ubiquitous, they exhibit distinct metal-binding preferences, either for divalent (Zn-thioneins) or monovalent (Cu-thioneins) metal ions. Drosophila constitutes a bizarre exception, since it is currently the only case of metazoans synthesizing only Cu-thioneins, which are similar to the paradigmatic yeast Cup1 protein. Until recently, the Drosophila MT system was assumed to be composed of 4 isoforms (MtnA, MtnB, MtnC and MtnD), all of them responsive to heavy metal load through the dMTF1 transcription factor. The significance of this polymorphism has been analyzed in depth both at genomic and proteomic levels. Singularly, a fifth MT isoform was recently annotated and named MtnE. The analysis of the MtnE expression pattern revealed some differential traits with regard to the other MTs. We analyze here the peculiarities of the metal binding abilities of the MtnE polypeptide and compare them with those of the other Drosophila MTs determined through the same rationale. Characterization by ESI-MS spectrometry and CD and UV-visible spectrophotometry of the Zn(II)-, Cd(II)- and Cu(I)-MtnE complexes obtained by recombinant synthesis demonstrates that MtnE is the least metal-specific isoform of the Drosophila MTs, and therefore it could play a role when/where a broad spectrum of metal coordination abilities are advantageous in terms of physiological needs.

Comparative genomics analysis of metallothioneins in twelve Drosophila species.

Metallothioneins (MTs) are a superfamily of Cys-rich polypeptides that bind heavy metal ions, both for physiological and detoxification purposes. They are present in all organisms, but their origin is probably polyphyletic, so that MT evolutionary studies are rather scarce. We present a thorough search and analysis of the MT coding sequences in the 12 Drosophila genomes completely sequenced, taking as reference the features reported for D. melanogaster, where four isogenes (MtnA to MtnD) are known and deeply characterized. We include a fifth isoform in this study, named MtnE, and recently annotated. The MTs polymorphism pattern is essentially the same for the 12 Drosophila species. Invariably, a MtnA form and an MtnB-cluster, comprising the MtnB-to-MtnE forms in tandem array, are observed. The whole set of genes are kept in the same synteny element (Muller E), but implicated in rearrangement events (mainly inversions), encompassing all or some of the isogenes. Gene exon/intron architecture, and cDNA and protein sequences appear highly conserved through Drosophila speciation, concordantly with an essential function for MT isoforms in flies, even for those previously considered as minor products. Data presented here will be comprehensively analyzed to provide a valuable guide for future MT evolutionary, structure and function studies.

Lack of DNA helicase Pif1 disrupts zinc and iron homoeostasis in yeast.

The Saccharomyces cerevisiae gene PIF1 encodes a conserved eukaryotic DNA helicase required for both mitochondrial and nuclear DNA integrity. Our previous work revealed that a pif1Δ strain is tolerant to zinc overload. In the present study we demonstrate that this effect is independent of the Pif1 helicase activity and is only observed when the protein is absent from the mitochondria. pif1Δ cells accumulate abnormal amounts of mitochondrial zinc and iron. Transcriptional profiling reveals that pif1Δ cells under standard growth conditions overexpress aconitase-related genes. When exposed to zinc, pif1Δ cells show lower induction of genes encoding iron (siderophores) transporters and higher expression of genes related to oxidative stress responses than wild-type cells. Coincidently, pif1Δ mutants are less prone to zinc-induced oxidative stress and display a higher reduced/oxidized glutathione ratio. Strikingly, although pif1Δ cells contain normal amounts of the Aco1 (yeast aconitase) protein, they completely lack aconitase activity. Loss of Aco1 activity is also observed when the cell expresses a non-mitochondrially targeted form of Pif1. We postulate that lack of Pif1 forces aconitase to play its DNA protective role as a nucleoid protein and that this triggers a domino effect on iron homoeostasis resulting in increased zinc tolerance.