Analysis of the SWI4/SWI6 protein complex, which directs G1/S-specific transcription in Saccharomyces cerevisiae

MCB elements and the regulation of DNA replication genes in yeast

In eukaryotic organisms, genes involved in DNA replication are often subject to some form of cell cycle control. In the yeast Saccharomyces cerevisiae, most of the DNA replication genes that have been characterized to date are regulated at the transcriptional level during G1 to S phase transition. A cis-acting element termed the MluI cell cycle box (or MCB) conveys this pattern of regulation and is common among more than 20 genes involved in DNA synthesis and repair. Recent findings indicate that the MCB element is well conserved among fungi and may play a role in controlling entry into the cell division cycle. It is evident from studies in higher systems, however, that transcriptional regulation is not the only form of control that governs the cell-cycle-dependent expression of DNA replication genes. Moreover, it is unclear why this general pattern of regulation exists for so many of these genes in various eukaryotic systems. This review summarizes recent studies of the MCB element in yeast and briefly discusses the purpose of regulating DNA replication genes in the eukaryotic cell cycle.

Domains of p85cdc10 required for function of the fission yeast DSC-1 factor

p85cdc10 is a component of the S.pombe DSC-1 complex, which is thought to mediate periodic transcription of genes in late G1. In order to understand the role of p85cdc10 in the function of this complex, we have analysed which domains of p85cdc10 are required for biological activity and the formation of a stable DSC-1 complex in vitro, both in cdc10 temperature sensitive and null backgrounds. No DSC-1 activity is found in the absence of p85cdc10 and the activity of the complex is reduced or absent in all cdc10ts mutants tested. Full biological activity and rescue of a cdc10::ura4+ null allele requires the N-terminal domain, the cdc10/SWI6 repeats and the helical C-terminal region. In the absence of p85cdc10, both the C-terminal and cdc10/SWI6 repeat domains are required for DSC-1 activity in vitro. In a cdc10ts background, rescue of DSC-1 activity and complementation of mutants, requires only expression of the C-terminal domain, though the presence of the cdc10/SWI6 motifs enhances its activity. The N-terminal domain, alone, or in combination with the cdc10/SWI6 motifs, does not have biological activity, and does not restore DSC-1 activity. We conclude that both the C-terminal domain of p85cdc10 is critical for formation of the DSC-1 complex and that the cdc10/SWI6 motifs also play a role, perhaps by stabilizing the complex. Our data also suggest that the S.pombe DSC-1 complex contains more than one molecule of p85cdc10.

Multiple SWI6-dependent cis-acting elements control SWI4 transcription through the cell cycle

The Saccharomyces cerevisiae SWI4 gene encodes an essential transcription factor which controls gene expression at the G1/S transition of the cell cycle. SWI4 transcription itself is cell cycle regulated, and this periodicity is crucial for the normal cell cycle regulation of HO and at least two of the G1 cyclins. Since the regulation of SWI4 is required for normal cell cycle progression, we have characterized cis- and trans-acting regulators of SWI4 transcription. Deletion analysis of the SWI4 promoter has defined a 140-bp region which is absolutely required for transcription and can function as a cell cycle-regulated upstream activating sequence (UAS). The SWI4 UAS contains three potential MluI cell cycle boxes (MCBs), which are known cell cycle-regulated promoter elements. Deletion of all three MCBs in the SWI4 UAS decreases the level of SWI4 mRNA 10-fold in asynchronous cultures but does not abolish periodicity. These data suggest that MCBs are involved in SWI4 UAS activity, but at least one other periodically regulated element must be present. Since SWI6 is known to bind to MCBs and regulate their activity, the role of SWI6 in SWI4 expression was analyzed. Although the MCBs cannot account for the full cell cycle regulation of SWI4, mutations in SWI6 eliminate the normal periodicity of SWI4 transcription. This suggests that the novel cell cycle-regulated element within the SWI4 promoter is also SWI6 dependent. The constitutive transcription of SWI4 in SWI6 mutant cells occurs at an intermediate level, which indicates that SWI6 is required for the full activation and repression of SWI4 transcription through the cell cycle. It also suggests that there is another pathway which can activate SWI4 transcription in the absence of SWI6. The second activator may also target MCB elements, since SWI4 transcription drops dramatically when they are deleted.

Multiple SWI6-dependent cis-acting elements control SWI4 transcription through the cell cycle

The Saccharomyces cerevisiae SWI4 gene encodes an essential transcription factor which controls gene expression at the G1/S transition of the cell cycle. SWI4 transcription itself is cell cycle regulated, and this periodicity is crucial for the normal cell cycle regulation of HO and at least two of the G1 cyclins. Since the regulation of SWI4 is required for normal cell cycle progression, we have characterized cis- and trans-acting regulators of SWI4 transcription. Deletion analysis of the SWI4 promoter has defined a 140-bp region which is absolutely required for transcription and can function as a cell cycle-regulated upstream activating sequence (UAS). The SWI4 UAS contains three potential MluI cell cycle boxes (MCBs), which are known cell cycle-regulated promoter elements. Deletion of all three MCBs in the SWI4 UAS decreases the level of SWI4 mRNA 10-fold in asynchronous cultures but does not abolish periodicity. These data suggest that MCBs are involved in SWI4 UAS activity, but at least one other periodically regulated element must be present. Since SWI6 is known to bind to MCBs and regulate their activity, the role of SWI6 in SWI4 expression was analyzed. Although the MCBs cannot account for the full cell cycle regulation of SWI4, mutations in SWI6 eliminate the normal periodicity of SWI4 transcription. This suggests that the novel cell cycle-regulated element within the SWI4 promoter is also SWI6 dependent. The constitutive transcription of SWI4 in SWI6 mutant cells occurs at an intermediate level, which indicates that SWI6 is required for the full activation and repression of SWI4 transcription through the cell cycle. It also suggests that there is another pathway which can activate SWI4 transcription in the absence of SWI6. The second activator may also target MCB elements, since SWI4 transcription drops dramatically when they are deleted.