Nuclear Gln3 Import Is Regulated by Nitrogen Catabolite Repression Whereas Export Is Specifically Regulated by Glutamine.

Gln3, a transcription activator mediating nitrogen-responsive gene expression in Saccharomyces cerevisiae, is sequestered in the cytoplasm, thereby minimizing nitrogen catabolite repression (NCR)-sensitive transcription when cells are grown in nitrogen-rich environments. In the face of adverse nitrogen supplies, Gln3 relocates to the nucleus and activates transcription of the NCR-sensitive regulon whose products transport and degrade a variety of poorly used nitrogen sources, thus expanding the cell's nitrogen-acquisition capability. Rapamycin also elicits nuclear Gln3 localization, implicating Target-of-rapamycin Complex 1 (TorC1) in nitrogen-responsive Gln3 regulation. However, we long ago established that TorC1 was not the sole regulatory system through which nitrogen-responsive regulation is achieved. Here we demonstrate two different ways in which intracellular Gln3 localization is regulated. Nuclear Gln3 entry is regulated by the cell's overall nitrogen supply, i.e., by NCR, as long accepted. However, once within the nucleus, Gln3 can follow one of two courses depending on the glutamine levels themselves or a metabolite directly related to glutamine. When glutamine levels are high, e.g., glutamine or ammonia as the sole nitrogen source or addition of glutamine analogues, Gln3 can exit from the nucleus without binding to DNA. In contrast, when glutamine levels are lowered, e.g., adding additional nitrogen sources to glutamine-grown cells or providing repressive nonglutamine nitrogen sources, Gln3 export does not occur in the absence of DNA binding. We also demonstrate that Gln3 residues 64-73 are required for nuclear Gln3 export.

The phage Mu middle promoter Pm contains a partial UP element.

There are three phases of transcription during lytic development of bacteriophage Mu: early, middle, and late. Transcription from the middle phase promoter Pm requires the activator protein Mor. In the presence of Mor, transcription from Pm is carried out by the Escherichia coli RNA polymerase holoenzyme containing σ(70). A Mor dimer binds to two 5-bp inverted repeats within a 16-bp element centered at -43.5 in Pm, replacing the normal -35 element contacted by RNA polymerase (RNAP). In this study random and targeted mutagenesis of the sequence upstream (-88 to -52) of the Mor binding site was performed to determine whether Pm also contains an UP element for binding of the RNAP α subunit, thereby stimulating transcription. The results demonstrated that mutations upstream of -57 had no effect on Pm activity in vivo, assayed by expression of lacZ fused downstream of a wild-type or mutant Pm. Mutations at positions -57 through -52 led to decreased transcription from Pm, consistent with the presence of an UP element. In DNase I footprinting and gel mobility shift assays, paired mutations at positions -55 and -54 did not affect Mor binding but decreased the synergistic binding of Mor with histidine tagged α (His-α), indicating that His-α binds to Pm in a sequence- and/or structure-specific manner. Taken together, these results demonstrate that Pm has a strong proximal UP element subsite, but lacks a distal subsite.

Unusual interaction of RNA polymerase with the bacteriophage Mu middle promoter Pm in the absence of its activator protein Mor.

The bacteriophage Mu Mor activator protein is absolutely required for transcription from the Mu middle promoter P(m). However, when RNA polymerase (RNAP) was incubated with P(m) DNA in the absence of Mor, a band at promoter position -51 was hypersensitive to DNase I cleavage, demonstrating an interaction of RNAP with the promoter DNA. The hypersensitivity was similar at four different lengths of P(m) DNA assayed from -62 to +10, -62 to +46, -96 to +10, and -96 to +46. The hypersensitivity occurred equally well at 5 °C, 15 °C, and 30 °C, indicating that it did not require open complex formation, which only occurred at 30 °C. The -51 hypersensitivity at 5 °C and 15 °C was eliminated by the addition of heparin, consistent with the possibility that it arose by formation of unstable closed complexes of RNAP bound to P(m) DNA. Generation of the hypersensitive band required the complete RNAP with its αCTDs, but neither the αCTD nor intact α were sufficient for the interaction and resulting hypersensitivity. There was no correlation between the level of hypersensitivity observed in vitro and the level of Pm activity in vivo, as assayed by the Mor-dependent production of ß-galactosidase from a P(m)-lacZ fusion. In an "order of addition" experiment, preincubation of P(m) DNA with Mor followed by addition of RNAP led to the fastest open complex formation, whereas preincubation of P(m) DNA with RNAP gave the slowest. These results support the conclusion that Mor recruits RNAP to P(m) rather than reposition a prebound RNAP, as occurs for C-dependent repositioning of RNAP at the Mu late promoter Pmom .

A domain in the transcription activator Gln3 specifically required for rapamycin responsiveness.

Nitrogen-responsive control of Gln3 localization is implemented through TorC1-dependent (rapamycin-responsive) and TorC1-independent (nitrogen catabolite repression-sensitive and methionine sulfoximine (Msx)-responsive) regulatory pathways. We previously demonstrated amino acid substitutions in a putative Gln3 α-helix(656-666), which are required for a two-hybrid Gln3-Tor1 interaction, also abolished rapamycin responsiveness of Gln3 localization and partially abrogated cytoplasmic Gln3 sequestration in cells cultured under nitrogen-repressive conditions. Here, we demonstrate these three characteristics are not inextricably linked together. A second distinct Gln3 region (Gln3(510-589)) is specifically required for rapamycin responsiveness of Gln3 localization, but not for cytoplasmic Gln3 sequestration under repressive growth conditions or relocation to the nucleus following Msx addition. Aspartate or alanine substitution mutations throughout this region uniformly abolish rapamycin responsiveness. Contained within this region is a sequence with a predicted propensity to form an α-helix(583-591), one side of which consists of three hydrophobic amino acids flanked by serine residues. Substitution of aspartate for even one of these serines abolishes rapamycin responsiveness and increases rapamycin resistance without affecting either of the other two Gln3 localization responses. In contrast, alanine substitutions decrease rapamycin resistance. Together, these data suggest that targets in the C-terminal portion of Gln3 required for the Gln3-Tor1 interaction, cytoplasmic Gln3 sequestration, and Gln3 responsiveness to Msx addition and growth in poor nitrogen sources are distinct from those needed for rapamycin responsiveness.

Genetic analysis of phage Mu Mor protein amino acids involved in DNA minor groove binding and conformational changes.

Gene expression during lytic development of bacteriophage Mu occurs in three phases: early, middle, and late. Transcription from the middle promoter, P(m), requires the phage-encoded activator protein Mor and the bacterial RNA polymerase. The middle promoter has a -10 hexamer, but no -35 hexamer. Instead P(m) has a hyphenated inverted repeat that serves as the Mor binding site overlapping the position of the missing -35 element. Mor binds to this site as a dimer and activates transcription by recruiting RNA polymerase. The crystal structure of the His-Mor dimer revealed three structural elements: an N-terminal dimerization domain, a C-terminal helix-turn-helix DNA-binding domain, and a ß-strand linker between the two domains. We predicted that the highly conserved residues in and flanking the ß-strand would be essential for the conformational flexibility and DNA minor groove binding by Mor. To test this hypothesis, we carried out single codon-specific mutagenesis with degenerate oligonucleotides. The amino acid substitutions were identified by DNA sequencing. The mutant proteins were characterized for their overexpression, solubility, DNA binding, and transcription activation. This analysis revealed that the Gly-Gly motif formed by Gly-65 and Gly-66 and the ß-strand side chain of Tyr-70 are crucial for DNA binding by His-tagged Mor. Mutant proteins with substitutions at Gly-74 retained partial activity. Treatment with the minor groove- and GC-specific chemical chromomycin A(3) demonstrated that chromomycin prevented His-Mor binding but could not disrupt a pre-formed His-Mor·DNA complex, consistent with the prediction that Mor interacts with the minor groove of the GC-rich spacer in the Mor binding site.

Identification of the J and K genes in the bacteriophage Mu genome sequence.

Bacteriophage Mu was the first transposable phage to be discovered and still serves as the model for a large family of related transposable phages and prophages. The Mu genome sequence is known (NC-000929.1 GI:9633494), but not all of the genes have been assigned to the ORFs in the genome sequence. For this paper, we have sequenced an approximately 3-kb DNA region containing four predicted ORFs, Mup35-Mup38, from lysogens containing amber mutant prophages defective in either the J or the K gene. Amber mutations in prophages with J gene mutations mapped to the Mup36 ORF, and those in the K gene were found in Mup37, identifying the ORFs corresponding to these genes.

Regional mutagenesis of the gene encoding the phage Mu late gene activator C identifies two separate regions important for DNA binding.

Lytic development of bacteriophage Mu is controlled by a regulatory cascade and involves three phases of transcription: early, middle and late. Late transcription requires the host RNA polymerase holoenzyme and a 16.5-kDa Mu-encoded activator protein C. Consistent with these requirements, the four late promoters P(lys), P(I), P(P) and P(mom) have recognizable -10 hexamers but lack typical -35 hexamers. The C protein binds to a 16-bp imperfect dyad-symmetrical sequence element centered at -43.5 and overlapping the -35 region. Based on the crystal structure of the closely related Mor protein, the activator of Mu middle transcription, we predict that two regions of C are involved in DNA binding: a helix-turn-helix region and a beta-strand region linking the dimerization and helix-turn-helix domains. To test this hypothesis, we carried out mutagenesis of the corresponding regions of the C gene by degenerate oligonucleotide-directed PCR and screened the resulting mutants for their ability to activate a P(lys)-galK fusion. Analysis of the mutant proteins by gel mobility shift, beta-galactosidase and polyacrylamide gel electrophoresis assays identified a number of amino acid residues important for C DNA binding in both regions.

Crystallization and preliminary X-ray analysis of phage Mu activator protein C in a complex with promoter DNA.

Bacteriophage Mu C protein is an activator of the four Mu late promoters that drive the expression of genes encoding DNA-modification as well as phage head and tail morphogenesis proteins. This report describes the purification and cocrystallization of wild-type and selenomethionine-substituted C protein with a synthetic late promoter P(sym), together with preliminary X-ray diffraction data analysis using SAD phasing. The selenomethionine peak data set was collected from a single crystal which diffracted to 3.1 A resolution and belonged to space group P4(1) or P4(3), with unit-cell parameters a = 68.9, c = 187.6 A and two complexes per asymmetric unit. The structure will reveal the amino acid-DNA interactions and any conformational changes associated with DNA binding.

Binding of the C-terminal domain of the alpha subunit of RNA polymerase to the phage mu middle promoter.

The C-terminal domain of the alpha subunit (alpha CTD) of Escherichia coli RNA polymerase is often involved in transcriptional regulation. The alpha CTD typically stimulates transcription via interactions with promoter UP element DNA and transcriptional activators. DNase I footprinting and gel mobility shift assays were used to look for potential interaction of the alpha CTD with the phage Mu middle promoter P(m) and its activator protein Mor. Binding of RNA polymerase to P(m) in the presence of Mor resulted in production of a DNase I footprint downstream of Mor due to open complex formation and generation of a second footprint just upstream of the Mor binding site. Generation of the upstream footprint did not require open complex formation and also occurred in reactions in which the alpha CTD or His-alpha proteins were substituted for RNA polymerase. In gel mobility shift assays, the formation of a supershifted ternary complex demonstrated that Mor and His-alpha bind synergistically to P(m) DNA. Gel shift assays with short DNA fragments demonstrated that only the Mor binding site and a single upstream alpha CTD binding site were required for ternary complex formation. These results suggest that the alpha CTD plays a role in P(m) transcription by binding to P(m) DNA just upstream from Mor and making protein-protein interactions with Mor that stabilize the binding of both proteins.

Complete genomic sequence of bacteriophage B3, a Mu-like phage of Pseudomonas aeruginosa.

Bacteriophage B3 is a transposable phage of Pseudomonas aeruginosa. In this report, we present the complete DNA sequence and annotation of the B3 genome. DNA sequence analysis revealed that the B3 genome is 38,439 bp long with a G+C content of 63.3%. The genome contains 59 proposed open reading frames (ORFs) organized into at least three operons. Of these ORFs, the predicted proteins from 41 ORFs (68%) display significant similarity to other phage or bacterial proteins. Many of the predicted B3 proteins are homologous to those encoded by the early genes and head genes of Mu and Mu-like prophages found in sequenced bacterial genomes. Only two of the predicted B3 tail proteins are homologous to other well-characterized phage tail proteins; however, several Mu-like prophages and transposable phage D3112 encode approximately 10 highly similar proteins in their predicted tail gene regions. Comparison of the B3 genomic organization with that of Mu revealed evidence of multiple genetic rearrangements, the most notable being the inversion of the proposed B3 immunity/early gene region, the loss of Mu-like tail genes, and an extreme leftward shift of the B3 DNA modification gene cluster. These differences illustrate and support the widely held view that tailed phages are genetic mosaics arising by the exchange of functional modules within a diverse genetic pool.

Crystal structure of the Mor protein of bacteriophage Mu, a member of the Mor/C family of transcription activators.

Transcription from the middle promoter, Pm, of bacteriophage Mu requires the phage-encoded activator protein Mor and bacterial RNA polymerase. Mor is a sequence-specific DNA-binding protein that mediates transcription activation through its interactions with the C-terminal domains of the alpha and sigma subunits of bacterial RNA polymerase. Here we present the first structure for a member of the Mor/C family of transcription activators, the crystal structure of Mor to 2.2-A resolution. Each monomer of the Mor dimer is composed of two domains, the N-terminal dimerization domain and C-terminal DNA-binding domain, which are connected by a linker containing a beta strand. The N-terminal dimerization domain has an unusual mode of dimerization; helices alpha1 and alpha2 of both monomers are intertwined to form a four-helix bundle, generating a hydrophobic core that is further stabilized by antiparallel interactions between the two beta strands. Mutational analysis of key leucine residues in helix alpha1 demonstrated a role for this hydrophobic core in protein solubility and function. The C-terminal domain has a classical helix-turn-helix DNA-binding motif that is located at opposite ends of the elongated dimer. Since the distance between the two helix-turn-helix motifs is too great to allow binding to two adjacent major grooves of the 16-bp Mor-binding site, we propose that conformational changes in the protein and DNA will be required for Mor to interact with the DNA. The highly conserved glycines flanking the beta strand may act as pivot points, facilitating the conformational changes of Mor, and the DNA may be bent.