Arnoud J. Kal

Differential Targeting of Two Distinct SWI/SNF-Related Drosophila Chromatin-Remodeling Complexes

ABSTRACT The SWI/SNF family of ATP-dependent chromatin-remodeling factors plays a central role in eukaryotic transcriptional regulation. In yeast and human cells, two subclasses have been recognized: one comprises yeast SWI/SNF and human BAF, and the other includes yeast RSC and human PBAF. Therefore, it was puzzling that Drosophila appeared to contain only a single SWI/SNF-type remodeler, the Brahma (BRM) complex. Here, we report the identification of two novel BRM complex-associated proteins: Drosophila Polybromo and BAP170, a conserved protein not described previously. Biochemical analysis established that Drosophila contains two distinct BRM complexes: (i) the BAP complex, defined by the presence of OSA and the absence of Polybromo and BAP170, and (ii) the PBAP complex, containing Polybromo and BAP170 but lacking OSA. Determination of the genome-wide distributions of OSA and Polybromo on larval salivary gland polytene chromosomes revealed that BAP and PBAP display overlapping but distinct distribution patterns. Both complexes associate predominantly with regions of open, hyperacetylated chromatin but are largely excluded from Polycomb-bound repressive chromatin. We conclude that, like yeast and human cells, Drosophila cells express two distinct subclasses of the SWI/SNF family. Our results support a close reciprocity of chromatin regulation by ATP-dependent remodelers and histone-modifying enzymes.

Peroxisomal beta-oxidation of polyunsaturated fatty acids in Saccharomyces cerevisiae: isocitrate dehydrogenase provides NADPH for reduction of double bonds at even positions.

The β‐oxidation of saturated fatty acids in Saccharomyces cerevisiae is confined exclusively to the peroxisomal compartment of the cell. Processing of mono‐ and polyunsaturated fatty acids with the double bond at an even position requires, in addition to the basic β‐oxidation machinery, the contribution of the NADPH‐dependent enzyme 2,4‐dienoyl‐CoA reductase. Here we show by biochemical cell fractionation studies that this enzyme is a typical constituent of peroxisomes. As a consequence, the β‐oxidation of mono‐ and polyunsaturated fatty acids with double bonds at even positions requires stoichiometric amounts of intraperoxisomal NADPH. We suggest that NADP‐dependent isocitrate dehydrogenase isoenzymes function in an NADP redox shuttle across the peroxisomal membrane to keep intraperoxisomal NADP reduced. This is based on the finding of a third NADP‐dependent isocitrate dehydrogenase isoenzyme, Idp3p, next to the already known mitochondrial and cytosolic isoenzymes, which turned out to be present in the peroxisomal matrix. Our proposal is strongly supported by the observation that peroxisomal Idp3p is essential for growth on the unsaturated fatty acids arachidonic, linoleic and petroselinic acid, which require 2,4‐dienoyl‐CoA reductase activity. On the other hand, growth on oleate which does not require 2,4‐dienoyl‐CoA reductase, and NADPH is completely normal in Δidp3 cells.

Pip2p: a transcriptional regulator of peroxisome proliferation in the yeast Saccharomyces cerevisiae.

In Saccharomyces cerevisiae, peroxisomes are the exclusive site for the degradation of fatty acids. Upon growth with the fatty acid oleic acid as sole carbon source, not only are the enzymes of beta‐oxidation and catalase A induced, but also the peroxisomal compartment as a whole increases in volume and the number of organelles per cell rises. We previously identified a cis‐acting DNA sequence [oleate response element (ORE)] involved in induction of genes encoding peroxisomal proteins. The aim of our investigation was to test whether a single mechanism acting via the ORE coordinates the events necessary for the proliferation of an entire organelle. Here we report the cloning and characterization of the oleate‐specific transcriptional activator protein Pip2p (pip: peroxisome induction pathway). Pip2p contains a typical Zn(2)‐Cys(6) cluster domain and binds to OREs. A pip2 deletion strain is impaired in growth on oleate as sole carbon source and the induction of beta‐oxidation enzymes is abolished. Moreover, only a few, small peroxisomes per cell can be detected. These results indicate that fatty acids activate Pip2p, which in turn activates the transcription of genes encoding beta‐oxidation components and acts as the crucial activator of peroxisomes.

The upstream region of the FOX3 gene encoding peroxisomal 3-oxoacyl-coenzyme A thiolase in Saccharomyces cerevisiae contains ABF1- and replication protein A-binding sites that participate in its regulation by glucose repression.

Expression of the FOX3 gene, which encodes yeast peroxisomal 3-oxoacyl-coenzyme A thiolase, can be induced by oleate and repressed by glucose. Previously, we have shown that induction was mediated by an oleate response element. Just upstream of this element a negatively acting control region that mediated glucose repression was found. In order to study this negative control region, we carried out DNA-binding assays and analyzed phenotypes of mutations in this region and in the trans-acting factor CAR80, which is identical to UME6. DNA-binding assays showed that two multifunctional yeast proteins, ABF1 and RP-A, interacted with the negative control element independently of the transcriptional activity of the FOX3 gene. ABF1 and RP-A, the latter being identical to BUF, were able to bind to DNA independently of one another but also simultaneously. The phenotypes of mutations in either DNA-binding sites of ABF1, RP-A, or both, which affected the DNA binding of these factors in vitro, indicated that these sites and the proteins that interact with them participate in glucose repression. The involvement of the RP-A site in glucose repression was further supported by our observation that the CAR80 gene product, which is required for repression mediated by the RP-A site, was essential for maintenance of glucose repression. In addition to the RP-A site in the FOX3 promoter, similar sequences were observed in other genes involved in peroxisomal function. RP-A proved to bind to all of these sequences, albeit with various affinities. From these results it is concluded that the ABF1 and RP-A sites are being required in concert to mediate glucose repression of the FOX3 gene. In addition, coordinated regulation of expression of genes involved in peroxisomal function in response to glucose is mediated by proteins associated with the RP-A site, probably RP-A and CAR80.

Expression of genes encoding peroxisomal proteins in Saccharomyces cerevisiae is regulated by different circuits of transcriptional control

In Saccharomyces cerevisiae induction of the FOX3 gene, encoding peroxisomal 3-oxoacyl-CoA thiolase, by growth on oleate as sole carbon source, is exerted via the cis-acting DNA element designated oleate response element (ORE) (Einerhand et al. (1991) Eur. J. Biochem. 200, 113-122). The transcription factor(s) binding to this upstream activation site (UAS) are still unknown, however. Induction of another peroxisomal enzyme, citrate synthase (CIT2) is dependent on the products of two genes called RTG1 and RTG2 (Liao and Butow (1993) Cell 72, 61-71). In the present study we have investigated whether RTG1 controls other genes coding for peroxisomal proteins, and whether such control takes place via the ORE. A number of genes coding for a variety of peroxisomal proteins such as: thiolase and catalase (peroxisomal matrix proteins), PAS3p (a peroxisomal membrane protein) and PAS10p (a protein involved in the import of peroxisomal proteins) were studied in their response to RTG1. Although the RTG1 and 2 products proved to be required for the increase in number and volume of peroxisomes upon induction by oleate, the single promoter output of the chosen set of genes remained practically unchanged in a rtg1 mutant strain. In addition gel retardation experiments indicated that RTG1 does not bind to the ORE. The behavior of genes coding for the various proteins also varied during repression, derepression and induction, indicating that probably a number of proteins are involved in tuning the output of each gene to cellular demand.

In silicio search for genes encoding peroxisomal proteins in Saccharomyces cerevisiae

The biogenesis of peroxisomes involves the synthesis of new proteins that after, completion of translation, are targeted to the organelle by virtue of peroxisomal targeting signals (PTS). Two types of PTSs have been well characterized for import of matrix proteins (PTS1 and PTS2). Induction of the genes encoding these matrix proteins takes place in oleate-containing medium and is mediated via an oleate response element (ORE) present in the region preceding these genes. The authors have searched the yeast genome for OREs preceding open reading frames (ORFs), and for ORFs that contain either a PTS1 or PTS2. Of the ORFs containing an ORE, as well as either a PTS1 or a PTS2, many were known to encode bona fide peroxisomal matrix proteins. In addition, candidate genes were identified as encoding putative new peroxisomal proteins. For one case, subcellular location studies validated the in silicio prediction. This gene encodes a new peroxisomal thioesterase.