DNA binding and DNA bending by the MelR transcription activator protein from Escherichia coli

The Escherichia coli melR gene encodes MelR protein which is a member of the AraC/XylS family of bacterial transcription activators. The function of MelR was investigated by making a targeted deletion in the melR gene of the Escherichia coli chromosome. MelR is a transcription activator essential for melibiose- dependent expression of the melAB operon which is needed for bacterial growth with melibiose as a carbon source. To investigate the interactions of MelR at the melAB promoter, both full length MelR and a shortened derivative, MelR173, containing the C-terminal DNA-binding domain, were purified as fusions to glutathione- S -transferase. Circular permutation studies show that both full-length MelR and MelR173 induce an apparent bend upon binding to target sites at the melAB promoter. Bound full-length MelR, but not MelR173, can oligomerise to form larger complexes that are likely to be involved in transcription activation.

Impaired lysogenisation of the Escherichia coli rpoA341 mutant by bacteriophage lambda is due to the inability of CII to act as a transcriptional activator

The C-terminus of the alpha subunit of Escherichia coli RNA polymerase is known to function in transcriptional activation at certain promoters. This region was previously shown to be necessary for full activation of the pE promoter by the phage lambda CII protein in vitro. In this work we investigated the inability of phage lambda to follow the lysogenic pathway in cells carrying the point mutation rpoA341 (a change of lysine 271 to glutamic acid). We found that neither overexpression of the cII gene nor stabilisation of the CII protein by the can1 mutation or by cIII gene overexpression was able to suppress the block in lysogenisation. In contrast, the lambda cin1 phage, which carries a CII-independent promoter for the expression of the cI gene, was able to efficiently lysogenise the rpoA341 mutant strain. Furthermore, the rpoA341 mutation prevented the activation of pE-lacZ and pI-lacZ transcriptional fusions by CII. Therefore we conclude that transcriptional activation by the cII gene product is abolished by the rpoA341 mutation, most probably due to impaired interaction between the CII activator and mutant RNA polymerase. The inability of RNA polymerase to respond to CII results in the impairment of lysogenisation of the rpoA341 mutant by phage lambda.

An RNA polymerase alpha subunit mutant impairs N-dependent transcriptional antitermination in Escherichia coli

We show that the rpoA341 mutation in the gene encoding the alpha subunit of Escherichia coli RNA polymerase results in a decreased level of transcripts originating from the lytic promoters PL and PR of infecting lambda phage. However, using lacZ fusions we demonstrate that initiation of transcription from both PL and PR is not impaired in the rpoA341 host. Rather, it is the level of the longer, antiterminated PL- and PR-derived transcripts which is altered: the activity of beta-galactosidase in bacteria harbouring a source of N and a PL-nutL-tL1-tI-lacZ or PR-nutR-tR1-lacZ fusion is considerably lower in the rpoA341 mutant relative to the rpoA+ strain. In the absence of the antiterminator protein N no difference is observed in the level of longer PR-derived transcripts between wild-type (rpoA+) and mutant (rpoA341) hosts. Although synthesis of N appears to be similar in both phage-infected rpoA+ and rpoA341 cells, overexpression of the N gene leads to restoration of wild-type levels of the longer PL- and PR-derived transcripts in the mutant host. While this mutation does not appear to affect vegetative phage growth in nus+ backgrounds, in combination with certain nus mutations it retards lytic development. Therefore, we conclude that the rpoA341 mutation specifically interferes with the function of the N-antitermination complex, suggesting that the C-terminal domain of the RNA polymerase alpha subunit may play an important role in N-dependent transcriptional antitermination.

A nested set of C-terminal deletions of the alpha subunit of Escherichia coli RNA polymerase define regions concerned with assembly, proteolysis, stabilization and transcriptional activation in vivo

BACKGROUND

The alpha subunit of eubacterial RNA polymerase comprises an N-terminal assembly domain and a mobile C-terminal domain which provides an activation contact site for class I transcription activators. One particular C-terminal alpha mutant, rpoA341, impairs the response of Escherichia coli RNA polymerase to several activators, including MelR.

RESULTS

The in vivo properties of a set of C-terminally truncated alpha variants were investigated. Derivatives of 230 amino acids or longer were assembled into functional RNA polymerase. However, derivatives greater than 271 residues in length were sensitised to proteolysis near K271. Deletion of only 13 C-terminal amino acids impaired the response to CRP at a class I promoter whereas the complete removal of the alpha C-terminal domain did not prevent complementation of MelR-dependent PmelAB activity in the rpoA341 mutant.

CONCLUSIONS

Our results refine the C-terminal limit of the alpha assembly domain to between residues 221 and 230. The 13 extreme C-terminal amino acids are exposed in the holoenzyme and participate in the protection of an otherwise proteolytically sensitive bond near K271. Their presence is also essential for transcription activation at class I CRP-dependent promoters. The rpoA341-mediated substitution, K271E, does not define an activation contact site for MelR.

Drastically decreased transcription from CII-activated promoters is responsible for impaired lysogenization of the Escherichia coli rpoA341 mutant by bacteriophage lambda

It was demonstrated previously that a mutation, rpoA341, in the gene encoding the alpha subunit of Escherichia coli RNA polymerase prevents lysogenization by bacteriophage lambda. The rpoA341 allele is known to be responsible for impaired transcription of some positively regulated E. coli chromosomal operons. Here we demonstrate that the inhibition of lysogenization of the rpoA341 mutant is a result of drastically decreased transcription from positively regulated phage promoters. We were unable to detect any transcripts originating from the CII-activated pE, pI and paQ promoters (important for lysogenic development) in the phage-infected rpoA341 mutant, in contrast to an otherwise isogenic rpoA+ strain. The results are discussed in the light of other reports showing that activation of the pE promoter by CII protein in vitro is decreased only about fivefold when the native alpha subunit is replaced by truncated alpha polypeptides.

Retention of low copy number human papillomavirus DNA in cultured cutaneous and mucosal wart keratinocytes

Cultured wart keratinocytes have previously been described as having a limited proclivity to maintain episomal human papillomavirus (HPV) DNA. To investigate the nature of episome loss, and to determine keratinocyte-specific factors involved in it, we have examined a large series of anogenital and oral wart keratinocyte cultures, tracing episomal copy number with culture passage. We report that a higher proportion of oral wart keratinocytes maintain episomal HPV DNA to first passage (70% compared with 37% of anogenital wart cultures) when screened by slot blot hybridization. Furthermore, oral wart keratinocytes maintain episomal HPV copy through a greater number of passages (60% positive at passage 2 compared with 2% of anogenital wart cultures) with this technique. When anogenital cultures were examined at first passage for HPV infection by PCR with Southern blot hybridization of the product, a further 34% were found to be HPV-positive. To determine the mechanism of loss of episomal DNA from these cultures we examined the relative HPV copy number in cells which adhered to the culture vessel following passage and in those which did not adhere. Those which remained floating contained episomal HPV at high copy number whereas those which adhered were negative by slot blotting. The adherent cells, however, remained positive by PCR at subsequent passages until senescence. We conclude that a subpopulation of HPV-positive keratinocytes may be maintained in culture through serial passage until senescence.

Involvement of the Escherichia coli RNA polymerase alpha subunit in transcriptional activation by the bacteriophage lambda CI and CII proteins

Escherichia coli cells harbouring the rpoA341 mutation produce an RNA polymerase which transcribes inefficiently certain operons subject to positive control. Here, we demonstrate that the rpoA341 allele also prevents lysogenization of the host strain by bacteriophage lambda, a process dependent upon the action of two phage-encoded activators. This phenomenon was shown to arise from an inability to establish an integrated prophage rather than a failure to maintain the lysogenic state. The inability of the rpoA341 host to support lysogenization could be completely reversed by CII-independent expression of int and cI in trans. These results led us to propose that the inhibition of lysogenization arises from a defective interaction between the phage lambda transcriptional activator CII and the mutant RNA polymerase at the phage promoters pI and pE. Finally, we also provide genetic evidence for impaired transcription of the cI gene from the CI-activated promoter, pM in the rpoA341 background.

Acute renal failure secondary to myoglobinuria

Acute Renal Failure (ARF) secondary to rhabdomyolysis and myoglobinuria was seen in four patients. In three, this was secondary to trauma and the fourth patient had an inflammatory myositis. All 4 patients had total recovery of renal function.

Type II paralysis or intermediate syndrome following organophosphorous poisoning

Three cases of type II paralysis or intermediate syndrome following organophosphorous poisoning are reported. Two patients had an initial improvement followed by development of paralysis of neck flexors, cranial nerves, proximal muscles of the limbs and respiratory muscles, which occurred 48 to 96 hours after the poisoning. All the patients recovered completely.

Association between the herpes simplex virus major DNA-binding protein and alkaline nuclease

Herpes simplex virus encodes seven proteins which have been shown to be both necessary and sufficient for in vitro replication of origin-containing plasmids. We have shown previously that one of these proteins, the major DNA-binding protein mDBP, forms a complex with alkaline nuclease, which is not one of the seven essential proteins. In this study, we have employed immunological reagents and a series of deletion mutants to investigate this complex further. We have determined the regions of mDBP which are important in the formation of this complex, and we have shown that the intranuclear locations of alkaline nuclease and major DNA-binding protein overlap.

Escherichia coli rpoA mutation which impairs transcription of positively regulated systems

The rpoA341 (phs) mutation of Escherichia coli results in decreased expression of several positively regulated operons and has been mapped to within or very near the rpoA gene encoding the alpha subunit of RNA polymerase. We have shown that plasmid-directed synthesis of the wild-type alpha subunit can complement the defective phenotypes associated with this mutation consistent with its proposed location within rpoA. This mutation was mapped by marker rescue to within a 182bp region near the 3' end of rpoA and was subsequently transferred to a plasmid by recombination in vivo. DNA sequence analysis revealed that the RpoA341 phenotype was the result of the substitution of lysine 271 by glutamate within the alpha polypeptide. We discuss this result in relation to our current understanding of the functional organization of the alpha subunit.

High level expression of DNA polymerases from herpesviruses

The DNA polymerase genes of human cytomegalovirus (HCMV) and varicella-zoster virus (VZV) were inserted separately into the polyhedrin gene of Autographa californica nuclear polyhedrosis virus (AcNPV) by cotransfection of Spodoptera frugiperda (SF9) cells with baculovirus transfer vectors carrying the genes and AcNPV infectious DNA. Infection of SF9 cells with the recombinant viruses resulted in expression from the polyhedrin promoter of proteins of the expected Mrs. These proteins possessed DNA polymerase activities similar to that of the enzymes induced by the respective herpesvirus in infected cells, and were identified as HCMV and VZV DNA polymerase using inhibitors and specific antisera reactive with each enzyme.

Identification of an enhancer element for the endosperm-specific expression of high molecular weight glutenin

Genes encoding high molecular weight (HMW) glutenin, a wheat seed storage protein, are expressed only in the developing endosperm. It was previously demonstrated that sequences essential for endosperm-specific transcription reside within 436 base pairs upstream of the initiation codon for HMW glutenin translation. We have further analyzed this region by testing the ability of a series of truncated HMW glutenin promoter fragments to enhance transcription from an adjacent heterologous promoter. The activity of these hybrid promoters was determined by measuring the expression of a linked beta-glucuronidase (GUS) reporter gene in transgenic tobacco plants. An HMW glutenin promoter fragment spanning nucleotides -375 to -45 relative to the transcription start site was found to stimulate GUS expression in tobacco seeds when inserted in either orientation upstream of the heterologous promoter. Furthermore, this fragment could also potentiate transcription when located 3' to the GUS reporter gene. Stimulation of GUS gene expression in transgenic tobacco seeds did not occur until 9 days to 12 days after anthesis, coincident with the onset of storage protein synthesis in the developing tobacco and wheat seed, and was confined to the endosperm tissue. By testing progressively shorter promoter fragments, the enhancer element responsible for this pattern of expression was localized to a 40-base pair region some 170 base pairs upstream of the start site for HMW glutenin transcription.

Identification of an enhancer element for the endosperm-specific expression of high molecular weight glutenin

Genes encoding high molecular weight (HMW) glutenin, a wheat seed storage protein, are expressed only in the developing endosperm. It was previously demonstrated that sequences essential for endosperm-specific transcription reside within 436 base pairs upstream of the initiation codon for HMW glutenin translation. We have further analyzed this region by testing the ability of a series of truncated HMW glutenin promoter fragments to enhance transcription from an adjacent heterologous promoter. The activity of these hybrid promoters was determined by measuring the expression of a linked beta-glucuronidase (GUS) reporter gene in transgenic tobacco plants. An HMW glutenin promoter fragment spanning nucleotides -375 to -45 relative to the transcription start site was found to stimulate GUS expression in tobacco seeds when inserted in either orientation upstream of the heterologous promoter. Furthermore, this fragment could also potentiate transcription when located 3' to the GUS reporter gene. Stimulation of GUS gene expression in transgenic tobacco seeds did not occur until 9 days to 12 days after anthesis, coincident with the onset of storage protein synthesis in the developing tobacco and wheat seed, and was confined to the endosperm tissue. By testing progressively shorter promoter fragments, the enhancer element responsible for this pattern of expression was localized to a 40-base pair region some 170 base pairs upstream of the start site for HMW glutenin transcription.

[Evaluation of medical education at the McMaster University, Canada, based on the case method concept]

Students of three different levels and the chairman of the MD-Program evaluated the educational system of McMaster University, Canada, using the six criteria of the case method as defined by Renschler. This analysis provided a very differentiated evaluation of the McMaster curriculum, demonstrating a systematic progress of learning methods from the second to the last phase. The instrument showed differences in the ratings of the demonstrative lectures between the chairman and the students. Free access to patients and responsibility, gradually growing during the 3-year program, are important features of the educational system. The problem-based system provides a unique integration of acquiring theoretical knowledge in the basic sciences through clinical problem solving which was highly rated in all analysed phases. Ratings given by the interviewed students for evaluation of documented work were lower than expected by the chairman and the authors. The results are discussed in relationship to the McMaster Philosophy and to the conditions of studying medicine in America and in Germany.

Production of antibodies of predetermined specificity against herpes simplex virus DNA polymerase and their use in characterization of the enzyme

Peptides from preselected regions of the herpes simplex virus DNA polymerase were used to generate monospecific antisera to defined regions of the enzyme. The antisera were used to localize the polymerase within the infected cell and to determine the time of synthesis during productive infection. Comparison with a neutralizing polyclonal antiserum was used to show the specificity of the peptide antisera. By using the antisera the stabilities of the DNA polymerase, the alkaline nuclease, and the major DNA-binding protein were determined, and the state of phosphorylation of the DNA polymerase was compared with each of these proteins.

S4-alpha mRNA translation repression complex. I. Thermodynamics of formation

Expression of the four ribosomal proteins from the Escherichia coli alpha operon (S4, S11, S13, and L17) is regulated at the level of translation by the binding of S4 to the alpha mRNA. Using a filter binding assay and alpha mRNA sequences prepared by in-vitro transcription, previous work located the S4 target site within the approximately 100-base leader sequence. We have extended this work to include fragments of the alpha leader with six different 5' end points and four different 3' end points. A core region between bases 23 and 69 (numbering from the first nucleotide of the E. coli transcript) binds S4 with an affinity of approximately 2 microM-1. Regions of weak interactions are located in the 22 nucleotides 5' and the 70 nucleotides 3' to this core; they increase the S4 affinity to approximately 13 microM-1. Studies of S4-alpha mRNA binding under different conditions have revealed the following. (1) Specific and non-specific binding show the same dependence on K+ concentration, with delta log+ K/delta log [K+] approximately 4 in most potassium salts. With KCl and KBr, much weaker salt dependence of specific complex formation is observed suggesting that the protein responds to the correct RNA substrate by binding halide anions. (2) Increasing the MgCl2 concentration between 1 and 4 mM enhances binding by a factor of 4, with no further effects up to 20 mM. About five Mg2+ are taken up by the complex with an average binding constant of approximately 600 M-1 each. Renaturation of the RNA in the presence of MgCl2 is also required to obtain full binding. These effects are seen only with alpha mRNA extending beyond the initiation codon; S4 binding to the alpha leader sequence itself is insensitive to Mg2+. (3) The association kinetics are fast and probably diffusion controlled. (4) Formation of the complex is entirely entropy driven.

Regulation of alpha operon gene expression in Escherichia coli. A novel form of translational coupling

The alpha operon of Escherichia coli contains the genes for ribosomal proteins S13, S11, S4, RNA polymerase subunit alpha, and r-protein L17, in this order. Previous studies have shown that translation of all four ribosomal proteins is regulated by S4, and that binding of S4 to the mRNA at the start site for S13 translation is probably responsible for the regulation of translation of S13, S11 and S4. The alpha gene is "unique" in that it is located between the genes for two ribosomal proteins (S4 and L17) and yet appears to be regulated independently of them. In the present studies, we have measured the synthesis rates of all the alpha operon proteins under a variety of physiological conditions. Our results confirm that alpha gene expression is regulated independently of the co-transcribed ribosomal protein genes and is relatively insensitive to translational feedback repression by S4. S1 nuclease analysis of alpha operon mRNA failed to reveal the presence of any unique transcription start or mRNA cleavage that leads to separation of the alpha cistron from preceding ribosomal protein cistrons. Therefore, it appears that differential regulation of alpha synthesis takes place at the level of mRNA translation. We have also carried out a deletion analysis of the alpha operon leader and identified a region of the alpha operon leader mRNA that is required for regulation by S4. Furthermore, deletion of this region results in increased synthesis of L17 together with S13, S11 and S4, whereas alpha synthesis did not increase significantly. Therefore, we conclude that interaction of S4 with this single target site results in translational repression of not only the proximal three cistrons for S13, S11 and S4 but also that of the last cistron, L17, without affecting the intervening alpha cistron.

Intravascular metabolism of lipoprotein cholesteryl esters in African green monkeys: differential fate of doubly labeled cholesteryl oleate

High density lipoproteins (HDL), doubly labeled with [3H]cholesteryl oleate and cholesteryl [14C]oleate, were reinjected to study HDL cholesteryl ester metabolism in African green monkeys. The transfer of labeled HDL cholesteryl ester to low density lipoprotein (LDL) was rapid and equilibration of the [3H]cholesteryl oleate and cholesteryl [14C]oleate specific activities in LDL and HDL occurred within 90 min after reinjection. The apparent rates of disappearance from the circulation of the two moieties of the cholesteryl ester were different. In the same four animals, the residence time for the turnover of plasma [3H]cholesterol averaged 6.1 days while the residence time for the removal of cholesteryl [14C]oleate from plasma was approximately 2.1 days. These results suggest that for some lipoprotein cholesteryl esters removed from plasma, the cholesterol moiety subsequently reappeared in plasma. The difference between the rate of decay of the 14C-labeled fatty acid moiety, which represents all of the cholesteryl ester removed from plasma (0.48 pools/day) and the decay of the 3H-labeled cholesterol moiety, which represents the sum of cholesteryl ester removal and cholesterol reappearance (0.16 pools/day), is the fraction of the cholesteryl ester pool recycled per day (0.32 pools/day or 22.5 mg/kg per day). In other words, approximately 68% of the cholesterol moiety that was removed from plasma as cholesteryl oleate reappeared in the plasma cholesterol pool. These studies support the concept that an efficient reutilization cycle for plasma cholesterol occurs, i.e., the cholesteryl ester molecule can exit and the cholesterol moiety can re-enter plasma without effective equilibration of the cholesterol moiety with extravascular cholesterol pools.

Translational regulation of the L11 ribosomal protein operon of Escherichia coli: mutations that define the target site for repression by L1

The L11 ribosomal protein operon of Escherichia coli contains the genes for L11 and L1 and is feedback regulated by the translational repressor L1. The mRNA target site for this repression is located close to the Shine-Dalgarno sequence for the first cistron, rp1K (L11). By use of a random mutagenesis procedure we have isolated and characterized a series of point mutations in the L11 leader mRNA which eliminate or greatly diminish the regulation by L1. The mutations define a region essential for translational regulation upstream of the L11 Shine-Dalgarno sequence and identify a region of structural homology with the L1 binding site on 23S rRNA. These results are also consistent with the previously proposed model for the secondary structure of the L11 leader mRNA.

Secondary attachment site for bacteriophage lambda in the guaB gene of Escherichia coli

lambda gua transducing bacteriophages were used to identify and sequence the secondary attachment site for lambda in the guaB gene of Escherichia coli. The sequence matched the primary core sequence at nine positions, and a putative integrase binding-site overlapped the left core-arm junction. Recombinational crossover occurred between nucleotides -3 and +2 of the core region.