Timothy C. Hallstrom

Expression of an ATP-binding cassette transporter-encoding gene (YOR1) is required for oligomycin resistance in Saccharomyces cerevisiae.

Semidominant mutations in the PDR1 or PDR3 gene lead to elevated resistance to cycloheximide and oligomycin. PDR1 and PDR3 have been demonstrated to encode zinc cluster transcription factors. Cycloheximide resistance mediated by PDR1 and PDR3 requires the presence of the PDR5 membrane transporter-encoding gene. However, PDR5 is not required for oligomycin resistance. Here, we isolated a gene that is necessary for PDR1- and PDR3-mediated oligomycin resistance. This locus, designated YOR1, causes a dramatic elevation in oligomycin resistance when present in multiple copies. A yor1 strain exhibits oligomycin hypersensitivity relative to an isogenic wild-type strain. In addition, loss of the YOR1 gene blocks the elevation in oligomycin resistance normally conferred by mutant forms of PDR1 or PDR3. The YOR1 gene product is predicted to be a member of the ATP-binding cassette transporter family of membrane proteins. Computer alignment indicates that Yor1p shows striking sequence similarity with multidrug resistance-associated protein, Saccharomyces cerevisiae Ycf1p, and the cystic fibrosis transmembrane conductance regulator. Use of a YOR1-lacZ fusion gene indicates that YOR1 expression is responsive to PDR1 and PDR3. While PDR5 expression is strictly dependent on the presence of PDR1 or PDR3, control of YOR1 expression has a significant PDR1/PDR3-independent component. Taken together, these data indicate that YOR1 provides the link between transcriptional regulation by PDR1 and PDR3 and oligomycin resistance of yeast cells.

An E2F1-Dependent Gene Expression Program that Determines the Balance between Proliferation and Cell Death

The Rb/E2F pathway regulates the expression of genes essential for cell proliferation but that also trigger apoptosis. During normal proliferation, PI3K/Akt signaling blocks E2F1-induced apoptosis, thus serving to balance proliferation and death. We now identify a subset of E2F1 target genes that are specifically repressed by PI3K/Akt signaling, thus distinguishing the E2F1 proliferative or apoptotic function. RNAi-mediated inhibition of several of these PI3K-repressed E2F1 target genes, including AMPK alpha 2, impairs apoptotic induction by E2F1. Activation of AMPK alpha 2 with an AMP analog further stimulates E2F1-induced apoptosis. We also show that the presence of the E2F1 apoptotic expression program in breast and ovarian tumors coincides with good prognosis, emphasizing the importance of the balance in the E2F1 proliferation/apoptotic program.

Specificity in the activation and control of transcription factor E2F-dependent apoptosis

Previous work has demonstrated a role for the E2F1 gene product in signaling apoptosis, both as a result of the deregulation of the Rb/E2F pathway as well as in response to DNA damage. We now show that the ability of cells to suppress the apoptotic potential of E2F1, as might occur during the course of normal cellular proliferation, requires the action of the Ras–phosphoinositide 3-kinase–Akt signaling pathway. In addition, we also identify a domain within the E2F1 protein, previously termed the marked-box domain, that is essential for the apoptotic activity of E2F1 and that distinguishes the E2F1 protein from E2F3. We also show that the E2F1-marked-box domain is essential for the induction of both p53 and p73 accumulation. Importantly, a role for the marked-box domain in the specificity of E2F1-mediated apoptosis coincides with recent work demonstrating a role for this domain in achieving specificity in the activation of transcription. We conclude that the unique capacity of E2F1 to trigger apoptosis reflects a specificity of transcriptional activation potential, and that this role for E2F1 is regulated through the action of the Akt protein kinase.

Identification of E-Box Factor TFE3 as a Functional Partner for the E2F3 Transcription Factor

ABSTRACT Various studies have demonstrated a role for E2F proteins in the control of transcription of genes involved in DNA replication, cell cycle progression, and cell fate determination. Although it is clear that the functions of the E2F proteins overlap, there is also evidence for specific roles for individual E2F proteins in the control of apoptosis and cell proliferation. Investigating protein interactions that might provide a mechanistic basis for the specificity of E2F function, we identified the E-box binding factor TFE3 as an E2F3-specific partner. We also show that this interaction is dependent on the marked box domain of E2F3. We provide evidence for a role for TFE3 in the synergistic activation of the p68 subunit gene of DNA polymerase α together with E2F3, again dependent on the E2F3 marked box domain. Chromatin immunoprecipitation assays showed that TFE3 and E2F3 were bound to the p68 promoter in vivo and that the interaction of either E2F3 or TFE3 with the promoter was facilitated by the presence of both proteins. In contrast, neither E2F1 nor E2F2 interacted with the p68 promoter under these conditions. We propose that the physical interaction of TFE3 and E2F3 facilitates transcriptional activation of the p68 gene and provides strong evidence for the specificity of E2F function.

Coordinate control of sphingolipid biosynthesis and multidrug resistance in Saccharomyces cerevisiae

Multiple or pleiotropic drug resistance often occurs in the yeast Saccharomyces cerevisiae through genetic activation of the Cys6-Zn(II) transcription factors Pdr1p and Pdr3p. Hyperactive alleles of these proteins cause overproduction of target genes that include drug efflux pumps, which in turn confer high level drug resistance. Here we provide evidence that both Pdr1p and Pdr3p act to regulate production of an enzyme involved in sphingolipid biosynthesis in S. cerevisiae. The last step in formation of the major sphingolipid in the yeast plasma membrane, mannosyldiinositol phosphorylceramide, is catalyzed by the product of the IPT1 gene, inositol phosphotransferase (Ipt1p). Transcription of the IPT1 gene is responsive to changes in activity of Pdr1p and Pdr3p. A single Pdr1p/Pdr3p response element is present in the IPT1 promoter and is required for regulation by these factors. Loss of IPT1 has complex effects on drug resistance of the resulting strain, consistent with an important role for mannosyldiinositol phosphorylceramide in normal plasma membrane function. Direct assay for lipid contents of cells demonstrates that changes in sphingolipid composition correlate with changes in the activity of Pdr3p. These data suggest that Pdr1p and Pdr3p may act to modulate the lipid composition of membranes in S. cerevisiae through activation of sphingolipid biosynthesis along with other target genes.

Regulation of Transcription Factor Pdr1p Function by an Hsp70 Protein in Saccharomyces cerevisiae

ABSTRACT Multiple or pleiotropic drug resistance in the yeastSaccharomyces cerevisiae requires the expression of several ATP binding cassette transporter-encoding genes under the control of the zinc finger-containing transcription factor Pdr1p. The ATP binding cassette transporter-encoding genes regulated by Pdr1p include PDR5 and YOR1, which are required for normal cycloheximide and oligomycin tolerances, respectively. We have isolated a new member of the PDR gene family that encodes a member of the Hsp70 family of proteins found in this organism. This gene has been designated PDR13 and is required for normal growth. Overexpression of Pdr13p leads to an increase in both the expression of PDR5 and YOR1 and a corresponding enhancement in drug resistance. Pdr13p requires the presence of both the PDR1 structural gene and the Pdr1p binding sites in target promoters to mediate its effect on drug resistance and gene expression. A dominant, gain-of-function mutant allele ofPDR13 was isolated and shown to have the same phenotypic effects as when the gene is present on a 2μm plasmid. Genetic and Western blotting experiments indicated that Pdr13p exerts its effect on Pdr1p at a posttranslational step. These data support the view that Pdr13p influences pleiotropic drug resistance by enhancing the function of the transcriptional regulatory protein Pdr1p.

Balancing the decision of cell proliferation and cell fate

The control of cellular proliferation is key in the proper development of a complex organism, the maintenance of tissue homeostasis, and the ability to respond to various hormonal and other inducers. Key in the control of proliferation is the retinoblastoma (Rb) protein which regulates the activity of a family of transcription factors known as E2Fs. The E2F proteins are now recognized to regulate the expression of a large number of genes associated with cell proliferation including genes encoding DNA replication as well as mitotic activities. What has also become clear over the past several years is the intimate relationship between the control of cell proliferation and the control of cell fate, particularly the activation of apoptotic pathways. Central in this connection is the Rb/E2F pathway that not only provides the primary signals for proliferation but at the same time, connects with the p53-dependent apoptotic pathway. This review addresses this inter-connection and the molecular mechanisms that control the decision between proliferation and cell death.

Androgens Suppress EZH2 Expression Via Retinoblastoma (RB) and p130-Dependent Pathways: A Potential Mechanism of Androgen-Refractory Progression of Prostate Cancer

Androgens and the androgen receptor are important for both normal prostate development and progression of prostate cancer (PCa). However, the underlying mechanisms are not fully understood. The Polycomb protein enhancer of zeste homolog 2 (EZH2) functions as an epigenetic gene silencer and plays a role in oncogenesis by promoting cell proliferation and invasion. EZH2 has been implicated in human PCa progression, because its expression is often elevated in hormone-refractory PCa. Here, we demonstrated that expression of EZH2 is lower in androgen-sensitive LNCaP PCa cells compared with Rf and C4-2 cells, two androgen-refractory sublines that are derived from LNCaP cells. Androgen ablation by castration increased the level of EZH2 proteins in LNCaP xenografts in mice. In contrast, treatment of LNCaP cells in culture with the synthetic androgen methyltrieolone (R1881) at doses of 1 nm or higher suppressed EZH2 expression. Moreover, our data suggest that androgen repression of EZH2 requires a functional androgen receptor and this effect is mediated through the retinoblastoma protein and its related protein p130. We further showed that androgen treatment not only increases expression of EZH2 target genes DAB2IP and E-cadherin but also affects LNCaP cell migration. Our results reveal that androgens function as an epigenetic regulator in prostatic cells by repression of EZH2 expression through the retinoblastoma protein and p130-dependent pathways. Our findings also suggest that blockade of EZH2 derepression during androgen deprivation therapy may represent an effective tactic for the treatment of androgen-refractory PCa.

Divergent Transcriptional Control of Multidrug Resistance Genes in Saccharomyces cerevisiae

Improper control of expression of ATP binding cassette transporter-encoding genes is an important contributor to acquisition of multidrug resistance in human tumor cells. In this study, we have analyzed the function of the promoter region of theSaccharomyces cerevisiae YOR1 gene, which encodes an ATP binding cassette transporter protein that is required for multidrug tolerance in S. cerevisiae. Deletion analysis of aYOR1-lacZ fusion gene defines three important transcriptional regulatory elements. Two of these elements serve to positively regulate expression of YOR1, and the third element is a negative regulatory site. One positive element corresponds to a Pdr1p/Pdr3p response element, a site required for transcriptional control by the homologous zinc finger transcription factors Pdr1p and Pdr3p in other promoters. The second positive element is located between nucleotides −535 and −299 and is referred to as UASYOR1 (where UAS is upstream activation sequence). Interestingly, function of UASYOR1 is inhibited by the downstream negative regulatory site. Promoter fusions constructed between UASYOR1 and the PDR5 promoter, another gene under Pdr1p/Pdr3p control, are active, whereas analogous promoter fusions constructed with the CYC1 promoter are not. This suggests the possibility that UASYOR1 has promoter-specific sequence requirements that are satisfied by another Pdr1p/Pdr3p-regulated gene but not by a heterologous promoter.

Hyperactive forms of the Pdr1p transcription factor fail to respond to positive regulation by the Hsp70 protein Pdr13p

Multidrug resistance in Saccharomyces cerevisiae is commonly associated with the overproduction of ATP‐binding cassette transporter proteins such as Pdr5p or Yor1p. The Cys6‐Zn(II)2 cluster‐containing transcription factors Pdr1p and Pdr3p are key regulators of expression of these pleiotropic drug resistance (PDR) loci. Previous experiments have demonstrated that the Hsp70 protein encoded by the PDR13 gene is a positive regulator of Pdr1p function. We have examined the mechanism underlying the control of Pdr1p by Pdr13p. Expression of deletion, insertion and amino acid substitution mutant variants of Pdr1p suggest that the centre region of the transcription factor is the target for Pdr13p‐mediated positive regulation. Immunological and fusion protein analyses demonstrate that Pdr13p is located in the cytoplasm, while Pdr1p is found in the nucleus. Biochemical fractionation experiments indicate that Pdr13p is associated with a high‐molecular‐weight complex and suggest the association of some fraction of Pdr13p with ribosomes.