Temperature-sensitive mutations in the bacteriophage Mu c repressor locate a 63-amino-acid DNA-binding domain.

Phage Mu's c gene product is a cooperative regulatory protein that binds to a large, complex, tripartite 184-bp operator. To probe the mechanism of repressor action, we isolated and characterized 13 phage mutants that cause Mu to undergo lytic development when cells are shifted from 30 to 42 degrees C. This collection contained only four mutations in the repressor gene, and all were clustered near the N terminus. The cts62 substitution of R47----Q caused weakened specific DNA recognition and altered cooperativity in vitro. A functional repressor with only 63 amino acids of Mu repressor fused to a C-terminal fragment of beta-galactosidase was constructed. This chimeric protein was an efficient repressor, as it bound specifically to Mu operator DNA in vitro and its expression conferred Mu immunity in vivo. A DNA looping model is proposed to explain regulation of the tripartite operator site and the highly cooperative nature of repressor binding.     

Modulation of phage Mu repressor DNA binding and degradation by distinct determinants in its C-terminal domain

Rapid degradation of the bacteriophage Mu immunity repressor can be induced in trans by mutant, protease-hypersensitive repressors (Vir) with an altered C-terminal domain (CTD). Genetic and biochemical analysis established that distinct yet overlapping determinants in the wild-type repressor CTD modulate Vir-induced degradation by Escherichia coli ClpXP protease and DNA binding by the N-terminal DNA-binding domain (DBD). Although deletions of the repressor C-terminus resulted in both resistance to ClpXP protease and suppression of a temperature-sensitive DBD mutation (cts62), some cysteine-replacement mutations in the CTD elicited only one of the two phenotypes. Some CTD mutations prevented degradation induced by Vir and resulted in the loss of intrinsic ClpXP protease sensitivity, characteristic of wild-type repressor, and at least two mutant repressors protected Vir from proteolysis. One protease-resistant mutant became susceptible to Vir-induced degradation when it also contained the cts62 mutation, which weakens DNA binding but apparently facilitates conversion to a protease-sensitive conformation. Conversely, this CTD mutation was able to suppress temperature sensitivity of DNA binding by the cts62 repressor. The results suggest that determinants in the CTD not only provide a cryptic ClpX recognition motif but also direct CTD movement that exposes the motif and modulates DNA binding.     

Efficient Mu transposition requires interaction of transposase with a DNA sequence at the Mu operator: implications for regulation

Phage Mu transposition is initiated by the Mu DNA strand-transfer reaction, which generates a branched DNA structure that acts as a transposition intermediate. A critical step in this reaction is formation of a special synaptic DNA-protein complex called a plectosome. We find that formation of this complex involves, in addition to a pair of Mu end sequences, a third cis-acting sequence element, the internal activation sequence (IAS). The IAS is specifically recognized by the N-terminal domain of Mu transposase (MuA protein). Neither the N-terminal domain of MuA protein nor the IAS is required for later reaction steps. The IAS overlaps with the sequences to which Mu repressor protein binds in the Mu operator region; the Mu repressor directly inhibits the Mu DNA strand-transfer reaction by interfering with the interaction between MuA protein and the IAS, providing an additional mode of regulation by the repressor.     

Inhibition of bacteriophage Mu transposition by Mu repressor and Fis

In this paper we show that the Escherichia coli protein Fis has a regulatory function in Mu transposition in the presence of Mu repressor. Fis can lower the transposition frequency of a mini-Mu 3–80-fold, but only if the Mu repressor is expressed simultaneously. In this novel type of regulation of transposition by the concerted action of Fis and repressor, the IAS, the internal activating sequence, is also involved as deletion of this site leads to the loss of the Fis effect. As the IAS contains strong repressor binding sites these are probably the target for the repressor in the observed negative regulation by Fis and repressor. However, the role of Fis and repressor is not only to inactivate the IAS, since a 4bp insertion in the IAS, which changes the spacing of the repressor-binding site, abolishes the enhancing function of the IAS but leaves the repressor-Fis effect intact. A likely target for Fis in this regulation is a strong Fis-binding site, which is located adjacent to the L2 transposase-binding site. However, when this Fis-binding sequence was substituted by a random sequence and Fis no longer showed specific binding to this site, the Fis effect was still observed. Although it is still possible that Fis can function by binding to this non-specific site in a particular complex, it seems more likely that Fis is directly or indirectly involved in determining the level of the repressor.     

Derepression of bacteriophage mu transposition functions by truncated forms of the immunity repressor

To trigger bacteriophage Mu transposition and replication in response to physiological signals, its immunity repressor must be synchronously inactivated. Two repressor mutants (Vir), which have an altered C-terminal domain and are highly susceptible to degradation by ClpXP protease, confer a dominant negative phenotype by promoting degradation of the wild-type repressor. To search for other modified repressors that can induce Mu derepression in vivo and to determine what part of the inducing repressor molecules are needed to target the unmodified repressor population, repressor peptides with nested deletions starting at the C-terminal end were constructed. Such peptides with a C-terminal ssrA degradation tag promoted a sharp reduction in cellular levels of full-length unmodified repressor, a process largely dependent upon the clpP protease function. Only the repressor DNA-binding domain, located at the N-terminal end, was required in tagged peptides to target unmodified repressor. In addition, some repressor peptides containing the DNA-binding domain promoted derepression without the clpP function, being able to promote repressor inactivation without promoting its degradation. None of the modified repressors could promote derepression if immunity was established by a mutant repressor lacking 18 residues at its C-terminal end. The results indicate that inducing repressor peptides influence the function of the C-terminal domain of the intact repressor, a domain that regulates its degradation and DNA binding. They suggest the possibility that tagged repressor molecules, produced by stalled ribosomes, can be inducers of transposition under starvation conditions.     

Interaction of negative (CytT) and positive (cAMP-CRP) regulation in the promoter region of the uridine phosphorylase (udp) gene in Escherichia coli K-12

Interaction of negative (CytR) and positive (cAMP-CRP) control in the promoter region of the uridine phosphorylase (udp) gene of Escherichia coli has been studied by using udp-lac operon fusions in which the structural lacZ gene is expressed from the wild type promoter udpP+ or from mutant promoters udpP1 and udpP18. The specific activity of beta-galactosidase was examined in these fusions in cytR+ and cytR- backgrounds after introduction of specific mutations in crp locus, crp* and crp(a) altering interaction of CRP protein with catabolite-sensitive promoters. The data obtained using crp* mutation confirm the proposed model of the udp gene regulation, according to which CytR repressor protein interferes with CRP binding site in the promoter-operator region of the udp gene and thereby prevents the positive action of cAMP-CRP complex on the udp expression. Additional data in favor of this model were obtained using crp(a) mutation which most probably alters the structure of CRP protein in such a way that it exhibits more high affinity to the udp promoter, as compared to the CytR repressor protein. Indeed, taken by itself, the crp(a) mutation did not lead to any increase in the expression of udpP+-lac fusion under the conditions of cAMP limitation (on glucose-grown cells), in spite of whether or not the CytR repressor was present. However, when combined with the ptsG mutation or when cells were grown on succinate medium, complete constitutive expression of udpP+-lac fusion is observed, even in the presence of the cytR gene product. The effect of the crp(a) mutation was virtually the same in strains harboring udpP1-lac fusion. These data are in accordance with suggestion that udpP1 is a mutation in the site of the promoter-operator region that responds to the cytR gene product, while the corresponding binding site for CRP protein is still unaltered in this mutant. On the other hand, the crp(a) mutation causes only slight alteration in the expression of udpP18-lac fusion, providing additional evidence that udpP18 mutation seems to comprise a modification of the promoter-operator region, where binding sites for CRP and CytR proteins overlap.     

Isolation of Erwinia chrysanthemi kduD mutants altered in pectin degradation.

Mutants of Erwinia chrysanthemi impaired in pectin degradation were isolated by chemical and Mu d(Ap lac) insertion mutagenesis. A mutation in the kduD gene coding for 2-keto-3-deoxygluconate oxidoreductase prevented the growth of the bacteria on polygalacturonate as the sole carbon source. Analysis of the kduD::Mu d(Ap lac) insertions indicated that kduD is either an isolated gene or the last gene of a polycistronic operon. Some of the Mu d(Ap lac) insertions were kduD-lac fusions in which beta-galactosidase synthesis reflected kduD gene expression. In all these fusions, beta-galactosidase activity was shown to be sensitive to catabolite repression by glucose and to be inducible by polygalacturonate, galacturonate, and other intermediates of polygalacturonate catabolism. Galacturonate-mediated induction was prevented by a mutation which blocked its metabolism to 2-keto-3-deoxygluconate. 2-Keto-3-deoxygluconate appeared to be the true inducer of kduD expression resulting from galacturonate degradation. 5-Keto-4-deoxyuronate or 2,5-diketo-3-deoxygluconate were the true inducers, originating from polygalacturonate cleavage. These three intermediates also appeared to induce pectate lyases, oligogalacturonate lyase, and 5-keto-4-deoxyuronate isomerase synthesis.     

肌苷和鸟苷生产菌中嘌呤核苷合成途径三段基因序列的分析

为了研究肌苷和鸟苷生产菌中与产苷有关的嘌呤核苷合成途径的遗传背景,选择了pur操纵子的启动子序列、编码SAMP合成酶的purA基因和编码GMP合成酶的guaA基因,设计合适的引物,分别从野生菌、一株肌苷低产菌和肌苷鸟苷高产菌中扩增出相应片段,经克隆和测序后,对它们进行比较和分析。分析结果表明两株生产菌的purA基因发生了1个碱基缺失,导致阅读框发生移码突变;而鸟苷高产菌在pur操纵子的启动子部分和操纵子抑制蛋白结合区域发生了近10％的突变,可能影响整个操纵子的表达调控。