The GCN4 bZIP targets noncognate gene regulatory sequences: quantitative investigation of binding at full and half sites

We previously reported that a basic region/leucine zipper (bZIP) protein, a hybrid of the GCN4 basic region and C/EBP leucine zipper, not only recognizes cognate target sites AP-1 (5'-TGACTCA-3') and cAMP-response element (CRE) (5'-TGACGTCA-3') but also binds selectively to noncognate DNA sites: C/EBP (CCAAT/enhancer binding protein, 5'-TTGCGCAA), XRE1 (xenobiotic response element, 5'-TTGCGTGA), HRE (HIF response element, 5'-GCACGTAG), and E-box (5'-CACGTG). In this work, we used electrophoretic mobility shift assay (EMSA) and circular dichroism (CD) for more extensive characterization of the binding of wt bZIP dimer to noncognate sites as well as full- and half-site derivatives, and we examined changes in flanking sequences. Quantitative EMSA titrations were used to measure dissociation constants of this hybrid, wt bZIP, to DNA duplexes: Full-site binding affinities gradually decrease from cognate sites AP-1 and CRE with Kd values of 13 and 12 nM, respectively, to noncognate sites with Kd values of 120 nM to low microM. DNA-binding selectivity at half sites is maintained; however, half-site binding affinities sharply decrease from the cognate half site (Kd = 84 nM) to noncognate half sites (all Kd values > 2 microM). CD shows that comparable levels of alpha-helical structure are induced in wt bZIP upon binding to cognate AP-1 or noncognate sites. Thus, noncognate sites may contribute to preorganization of stable protein structure before binding target DNA sites. This work demonstrates that the bZIP scaffold may be a powerful tool in the design of small, alpha-helical proteins with desired DNA recognition properties.     

The positive regulatory function of the 5''-proximal open reading frames in GCN4 mRNA can be mimicked by heterologous, short coding sequences.

Translational control of GCN4 expression in the yeast Saccharomyces cerevisiae is mediated by multiple AUG codons present in the leader of GCN4 mRNA, each of which initiates a short open reading frame of only two or three codons. Upstream AUG codons 3 and 4 are required to repress GCN4 expression in normal growth conditions; AUG codons 1 and 2 are needed to overcome this repression in amino acid starvation conditions. We show that the regulatory function of AUG codons 1 and 2 can be qualitatively mimicked by the AUG codons of two heterologous upstream open reading frames (URFs) containing the initiation regions of the yeast genes PGK and TRP1. These AUG codons inhibit GCN4 expression when present singly in the mRNA leader; however, they stimulate GCN4 expression in derepressing conditions when inserted upstream from AUG codons 3 and 4. This finding supports the idea that AUG codons 1 and 2 function in the control mechanism as translation initiation sites and further suggests that suppression of the inhibitory effects of AUG codons 3 and 4 is a general consequence of the translation of URF 1 and 2 sequences upstream. Several observations suggest that AUG codons 3 and 4 are efficient initiation sites; however, these sequences do not act as positive regulatory elements when placed upstream from URF 1. This result suggests that efficient translation is only one of the important properties of the 5' proximal URFs in GCN4 mRNA. We propose that a second property is the ability to permit reinitiation following termination of translation and that URF 1 is optimized for this regulatory function.     

Polymorphism in regulatory gene sequences

The extensive polymorphism revealed in non-coding gene-regulatory sequences, particularly in the immune system, suggests that this type of genetic variation is functionally and evolutionarily far more important than has been suspected, and provides a lead to new therapeutic strategies.     

Polymorphism in regulatory gene sequences

The extensive polymorphism revealed in non-coding gene-regulatory sequences, particularly in the immune system, suggests that this type of genetic variation is functionally and evolutionarily far more important than has been suspected, and provides a lead to new therapeutic strategies.     

Yeast proteins can activate expression through regulatory sequences of the amdS gene of Aspergillus nidulans

The upstream regulatory region of the amdS gene of Aspergillus nidulans contains a CCAAT sequence known to be important in setting both basal and derepressed levels of expression. We have investigated whether the CCAAT-binding HAP2/3/4 complex of the yeast Saccharomyces cerevisiae can recognise this sequence in an amdS context. Sequences from the 5′ region of amdS were cloned in front of the CYCI-lacZ fusion gene bearing a minimal promoter and transformed into wild-type and hap2 strains of yeast. This study has indicated that amdS sequences are capable of promoting regulated expression of the fusion gene in response to carbon limitation. The yeast HAP2/3/4 complex can recognise the amdS CCAAT sequence and activate expression from this sequence. In addition, the results indicate that other yeast proteins can also regulate expression from the A. nidulans amdS 5′ sequences under carbon-limiting conditions.     

cis-acting sequences involved in the translational control of GCN4 expression

Four short upstream open reading frames (uORFs) in the mRNA leader are required for the translational control of GCN4 expression in response to amino acid availability. Data are reviewed demonstrating that the fourth (3' proximal) uORF is sufficient to establish the repressed levels of GCN4 expression, while the first uORF functions as a positive regulatory element under starvation conditions to stimulate GCN4 translation. Furthermore, positive and negative trans-acting regulatory factors, the activities of which appear to be modulated according to amino acid availability, exert their effects on GCN4 expression through the uORFs. Direct comparison of the uORFs indicates that there are important nucleotide sequence differences between uORF1 and 4, and that these are located primarily around the termination codons of these elements. Recent findings suggest that the sequences that mediate repression of GCN4 expression are complex, but can be overcome under starvation conditions by ribosomes that have previously translated uORF1.     

Vertebrate DM domain proteins bind similar DNA sequences and can heterodimerize on DNA

Background:  

The DM domain is a zinc finger-like DNA binding motif first identified in the sexual regulatory proteins Doublesex (DSX) and MAB-3, and is widely conserved among metazoans. DM domain proteins regulate sexual differentiation in at least three phyla and also control other aspects of development, including vertebrate segmentation. Most DM domain proteins share little similarity outside the DM domain. DSX and MAB-3 bind partially overlapping DNA sequences, and DSX has been shown to interact with DNA via the minor groove without inducing DNA bending. DSX and MAB-3 exhibit unusually high DNA sequence specificity relative to other minor groove binding proteins. No detailed analysis of DNA binding by the seven vertebrate DM domain proteins, DMRT1-DMRT7 has been reported, and thus it is unknown whether they recognize similar or diverse DNA sequences.     

Cloning of regulatory sequences mediating guard-cell-specific gene expression

This report describes the use of promoter trap lines from the model plant Arabidopsis thaliana to clone regulatory sequences that mediate guard-cell-specific reporter gene expression. Stomatal guard cells represent a highly differentiated cell type within the epidermis of green tissues of higher plants. They control the stomatal aperture in response to different endogenous and environmental signals in order to optimize carbon fixation while minimizing water loss. We screened available promoter trap lines for guard-cell-specific activation of a beta-glucuronidase (uidA) reporter gene in order to obtain marker lines for guard-cell development and to gain access to regulatory pathways leading to gene expression which is restricted to this cell type. From two lines identified we successfully cloned upstream regulatory sequences. For one line, guard-cell-specific promoter activity was confirmed by re-introducing the uidA gene, fused to the newly identified regulatory sequences, into the Arabidopsis nuclear genome. However, DNA sequences downstream of the uidA/T-DNA insertion sites in the original promoter trap lines revealed no obvious coding regions in the corresponding orientation, indicating that we have probably identified 'cryptic' promoters, being active in guard cells.