Functionality of purified sigma(N) (sigma(54)) and a NifA-like protein from the hyperthermophile Aquifex aeolicus

The genome sequence of the extremely thermophilic bacterium Aquifex aeolicus encodes alternative sigma factor sigma(N) (sigma(54), RpoN) and five potential sigma(N)-dependent transcriptional activators. Although A. aeolicus possesses no recognizable nitrogenase genes, two of the activators have a high degree of sequence similarity to NifA proteins from nitrogen-fixing proteobacteria. We identified five putative sigma(N)-dependent promoters upstream of operons implicated in functions including sulfur respiration, nitrogen assimilation, nitrate reductase, and nitrite reductase activity. We cloned, overexpressed (in Escherichia coli), and purified A. aeolicus sigma(N) and the NifA homologue, AQ_218. Purified A. aeolicus sigma(N) bound to E. coli core RNA polymerase and bound specifically to a DNA fragment containing E. coli promoter glnHp2 and to several A. aeolicus DNA fragments containing putative sigma(N)-dependent promoters. When combined with E. coli core RNA polymerase, A. aeolicus sigma(N) supported A. aeolicus NifA-dependent transcription from the glnHp2 promoter. The E. coli activator PspFDeltaHTH did not stimulate transcription. The NifA homologue, AQ_218, bound specifically to a DNA sequence centered about 100 bp upstream of the A. aeolicus glnBA operon and so is likely to be involved in the regulation of nitrogen assimilation in this organism. These results argue that the sigma(N) enhancer-dependent transcription system operates in at least one extreme environment, and that the activator and sigma(N) have coevolved.

Low resolution structure of the sigma54 transcription factor revealed by X-ray solution scattering

The sigma54 RNA polymerase holoenzyme functions in enhancer-dependent transcription. The structural organization of the sigma54 subunit of bacterial RNA polymerase in solution is analyzed by synchrotron x-ray scattering. Scattering patterns are collected from the full-length protein and from a large fragment able to bind the core RNA polymerase, and their low resolution shapes are restored using two ab initio shape determination techniques. The sigma54 subunit is a highly elongated particle, and the core binding fragment can be unambiguously positioned inside the full-length protein. The boomerang-like shape of the core binding fragment is similar to that of the atomic model of a fragment of the Escherichia coli sigma70 protein, indicating that, although the sigma54 and sigma70 factors are unrelated by primary sequence, they may share some structural similarity. Potential DNA binding surfaces of sigma54 are also predicted by comparison with the sigma54 core binding fragment.

Two roles for integration host factor at an enhancer-dependent nifA promoter

Control of transcription in prokaryotes often involves direct contact of regulatory proteins with RNA polymerase. For the sigma54 RNA polymerase, regulatory proteins bound to distally located enhancers engage the polymerase via DNA looping. The sigma54-dependent nifA promoter of Herbaspirillum seropedicae (Hs) is activated under nitrogen-limiting growth conditions. Potential enhancers for the nitrogen control activators NTRC and NIFA and binding sites for integration host factor (IHF) and sigma54-holoenzyme were identified. DNA footprinting experiments showed that these sites functioned for protein binding. Their involvement in the promoter regulation was explored. In vitro, activation of the Hs nifA promoter by NTRC is stimulated by the DNA bending protein IHF. In marked contrast, activation by NIFA is greatly reduced by IHF, thus diminishing potentially destabilizing autoactivation of the nifA promoter by NIFA. Additionally, high levels of NIFA appear to limit NTRC-dependent activation. This inhibition is IHF dependent. Therefore, IHF acts positively and negatively at the nifA promoter to restrict transcription activation to NTRC and one signal transduction pathway.

c-Myb modulates transcription of the alpha-smooth muscle actin gene in activated hepatic stellate cells

Expression of alpha-smooth muscle actin (alpha-SMA) defines the phenotype of activated (myofibroblastic) hepatic stellate cells. These cells, but not quiescent stellate cells, have a high level of alpha-SMA and c-Myb expression, as well as increased c-Myb-binding activities to the proximal alpha-SMA E box. Therefore, we analyzed the role of c-Myb in alpha-SMA transcription and stellate cell activation. Activated primary rat stellate cells displayed a high expression of the -724 and -271 alpha-SMA/luciferase (LUC) chimeric genes, which contain c-Myb binding sites (-223/-216 bp). Alpha-SMA/LUC minigenes with mutation (-219/-217 bp), truncation (-224 bp), or deletion (-191 bp) of the c-Myb binding site were not efficiently transcribed. Transfection of wild-type c-Myb into quiescent stellate cells, which do not express endogenous c-Myb, induced a approximately 10-fold stimulation of -724 alpha-SMA/LUC expression. Conversely, expression of either a dominant-negative c-Myb basic domain mutant (Cys(43) --> Asp) or a c-Myb antisense RNA blocked transcription from the -724 alpha-SMA/LUC or -271 alpha-SMA/LUC in activated cells. Moreover, transfection of c-myb antisense, but not sense, RNA inhibited both expression of the endogenous alpha-SMA gene and stellate cell activation, whereas transfection of c-myb stimulated alpha-SMA expression in quiescent stellate cells. These findings suggest that c-Myb modulates the activation of stellate cells and that integrity of the redox sensor Cys(43) in c-Myb is required for this effect.

Detection of molecular alignment in confined films

Optical second harmonic generation was used to study the in-plane alignment of self-assembled silane monolayers attached to a glass surface under mechanical loading. The measurements allow correlation of the macroscopic forces acting on the monolayer with the average orientation and the azimuthal molecular alignment of the terminal molecular entity. Compression and shear forces lead to an alignment of the initially randomly oriented molecules on a macroscopic length scale. The change in azimuthal alignment of molecules under mechanical stress was found to be irreversible on the time scale of 12 hours, whereas changes of the molecular tilt angle were reversible.

Phosphorylation of rat serine 105 or mouse threonine 217 in C/EBP beta is required for hepatocyte proliferation induced by TGF alpha

We report that TGF alpha induces activation of the p90 ribosomal S kinase (RSK), which results in the phosphorylation of rat C/EBP beta on Ser-105 and of mouse C/EBP beta on Thr-217 and concomitantly stimulates proliferation in differentiated hepatocytes. Moreover, C/EBP beta-/- mouse hepatocytes respond to TGF alpha when wild-type C/EBP beta is reexpressed, whereas they remain refractory to the growth effect of TGF alpha when expressing phosphoacceptor mutants rat C/EBP beta Ala-105 or mouse C/EBP beta Ala-217. In contrast, C/EBP beta-/- hepatocytes expressing the phosphorylation mimic mutants, rat C/EBP beta Asp-105 or mouse C/EBP beta Glu-217, exhibited marked proliferation in the absence of TGF alpha. Thus, a site-specific phosphorylation of the transcription factor C/EBP beta is critical for hepatocyte proliferation induced by TGF alpha and other stimuli that activate RSK.

The C-terminal 12 amino acids of sigma(N) are required for structure and function

The sigma(N) protein is an alternative sigma subunit of bacterial RNA polymerase. We investigated the role of a 12-amino-acid "tail" at the C-terminus of Klebsiella pneumoniae sigma(N), which was predicted to be largely surface-exposed and to be mostly loop (that is not alpha-helical or beta-strand). Deletion of this tail from N-terminal hexahistidine-tagged sigma(N) led to loss of sigma(N)-dependent transcription activity in vivo. We overexpressed and purified this deletion-mutant protein for in vitro characterization. The purified deleted protein showed decreased RNA polymerase core- and DNA-binding activities compared to the full-length protein and transcription activity was greatly impaired. Furthermore, evidence from circular dichroism and protease digestion experiments together suggested that deletion of the C-terminus tail resulted in a loss of conformational constraint in the protein. We discuss a possible structural role for the 12 amino acids at the C-terminus of sigma(N).

Epstein-Barr virus-encoded RK-BARF0 protein expression

The cellular localization of the Epstein-Barr virus-encoded RK-BARF0 protein was analyzed by fluorescence microscopy and immunoblotting. The recombinant RK-BARF0 protein was found to be tightly bound to nuclear structures, whereas 16- to 20-kDa RK-BARF0 derivatives, generated by differential splicing of the RK-BARF0 transcript, were present throughout the cell. Moreover, a previously generated anti-RK-BARF0 rabbit serum was found to cross-react with cellular proteins, showing that the previously identified 30- to 35-kDa membrane-associated proteins do not represent RK-BARF0.

Systematic analysis of sigma54 N-terminal sequences identifies regions involved in positive and negative regulation of transcription

The conserved amino-terminal region of sigma 54 (Region I) contains sequences that allow response to activator proteins, and inhibit initiation in the absence of activator. Alanine-scanning mutagenesis has been used to systematically define Region I elements that contribute to each of these functions. Amino acid residues from 6 to 50 were substituted with alanine in groups of three consecutive residues, making a total of 15 mutants. Mutants were tested for their ability to mediate activation in vivo, and in vitro, and to support transcription in the absence of activator in vitro. Most mutations located between residues 15 and 47 altered sigma function, while mutations between residues 6 and 14, and 48-50 had little effect. The defective mutants ala 15-17, 42-44, and 45-47 define new amino acids required for normal sigma function. In general, there is an inverse correlation between the levels of activated and activator-independent transcription, suggesting that the two functions are linked. When activated, the defective sigma mutants, except for ala 24-26, formed heparin-resistant open complexes similar to wild-type sigma. Mutant ala 24-26 formed heparin-unstable open complexes, suggesting that this mutation interferes with a different step in the initiation pathway.

Functions of the sigma(54) region I in trans and implications for transcription activation

Control of transcription frequently involves the direct interaction of activators with RNA polymerase. In bacteria, the formation of stable open promoter complexes by the sigma(54) RNA polymerase is critically dependent on sigma(54) amino Region I sequences. Their presence correlates with activator dependence, and removal allows the holoenzyme to engage productively with melted DNA independently of the activator. Using purified Region I sequences and holoenzymes containing full-length or Region I-deleted sigma(54), we have explored the involvement of Region I in transcription activation. Results show that Region I in trans inhibits a reversible conformational change in the holoenzyme believed to be polymerase isomerization. Evidence is presented indicating that the holoenzyme (and not the promoter DNA per se) is one interacting target used by Region I in preventing polymerase isomerization. Activator overcomes this inhibition in a reaction requiring nucleotide hydrolysis. Region I in trans is able to inhibit activated transcription by the holoenzyme containing full-length sigma(54). Inhibition appeared to be noncompetitive with respect to the activator, suggesting that a direct activator interaction occurs with parts of the holoenzyme outside Region I. Stabilization of isomerized holoenzyme bound to melted DNA by Region I in trans occurs largely independently of the initiating nucleotide, suggesting a role for Region I in maintaining the open complex.

The sigma 54 DNA-binding domain includes a determinant of enhancer responsiveness

The bacterial sigma54 protein associates with core RNA polymerase to form a holoenzyme that functions in enhancer-dependent transcription. Isomerization of the sigma54 polymerase and its engagement with melted DNA in open promoter complexes requires nucleotide hydrolysis by an enhancer-binding activator. We show that a single amino acid substitution, RA336, in the Klebsiella pneumoniae sigma54 C-terminal DNA-binding domain allows the holoenzyme to isomerize, engage with stably melted DNA and to transcribe from transiently melting DNA without an activator. Activator responsiveness for the formation of stable open complexes remained intact. The activator-independent transcription phenotype of RA336 is shared with mutants in amino-terminal Region I sequences. Thus, in sigma54, two distinct domains function for enhancer responsiveness. A sigma54-DNA contact mediated by R336 appears to be part of a network of interactions necessary for maintaining the transcriptionally inactive state of the holoenzyme. We suggest activator functions to change these interactions and facilitate open complex formation through promoting polymerase isomerization.

Involvement of the sigmaN DNA-binding domain in open complex formation

sigmaN (sigma54) RNA polymerase holoenzyme closed complexes isomerize to open complexes in a reaction requiring nucleoside triphosphate hydrolysis by enhancer binding activator proteins. Here, we characterize Klebsiella pneumoniae sigmaN mutants, altered in the carboxy DNA-binding domain (F354A/F355A, F402A, F403A and F402A/F403A), that fail in activator-dependent transcription. The mutant holoenzymes have altered activator-dependent interactions with promoter sequences that normally become melted. Activator-dependent stable complexes accumulated slowly in vitro (F402A) and to a reduced final level (F403A, F402A/F403A, F354A/F355A). Similar results were obtained in an assay of activator-independent stable complex formation. Premelted templates did not rescue the mutants for stable preinitiation complex formation but did for deleted region I sigmaN, suggesting different defects. The DNA-binding domain substitutions are within sigmaN sequences previously shown to be buried upon formation of the wild-type holoenzyme or closed complex, suggesting that, in the mutants, alteration of the sigmaN-core and sigmaN-DNA interfaces has occurred to change holoenzyme activity. Core-binding assays with the mutant sigmas support this view. Interestingly, an internal deletion form of sigmaN lacking the major core binding determinant was able to assemble into holoenzyme and, although unable to support activator-dependent transcription, formed a stable activator-independent holoenzyme promoter complex on premelted DNA templates.

Limited proteolysis of the IGF binding protein-2 (IGFBP-2) by a specific serine protease activity in early breast milk

IGF in milk possibly promote maturation of the gastrointestinal tract in newborns. We studied the composition of milk samples derived from 99 healthy women at regular intervals during a period beginning 3 d and ending 6 mo after birth. The concentrations measured by RIA on d 3 were 10.7+/-0.4 ng/mL for IGF-II, 1.9+/-0.1 ng/mL for IGF-I, 100+/-5 ng/mL for IGF binding protein-3 (IGFBP-3), and 2163+/-108 ng/mL for IGFBP-2. All factor concentrations decreased by up to 70% in the course of the 6 mo. The most striking finding was an IGFBP-2-specific protease activity. Protease assays performed by incubation of 125I-IGFBP-2 with milk yielded fragments of 14, 16, 23, and 25 kD. 125I-IGFBP-3 was not cleaved. Proteolysis occurred only in milk from mothers until 4 wk postpartum and could be visualized by immunoblots. Since the affinity of the fragments to 125I-IGF-II was low, they were not demonstrable by ligand blot. Inhibitor studies and pH optimizing classified the IGFBP-2 protease as an Me2(+)-dependent serine protease with a pH optimum of 7 to 8. The proteolytic activity of further milk proteins, known as IGFBP proteases, was analyzed. Epidermal growth factor receptor peptide and prostate-specific antigen did not cleave IGFBP-2, although the protease activity correlated (r = 0.84, p < 0.00003) with the prostate-specific antigen concentration in milk. The y-nerve growth factor cleaved 125I-IGFBP-2, but in a completely different manner than the milk protease. In conclusion, the IGFBP-2 protease in milk is most probably a kallikrein. The specific proteolysis of IGF/IGFBP-2 complexes may increase the biologic availability of IGF in early milk. This mechanism may promote growth of the maternal breast epithelium and maturation of the gastrointestinal tract of newborns.

Characterisation of holoenzyme lacking sigmaN regions I and II

The sigma-N (sigmaN) protein associates with bacterial core RNA polymerase to form a holoenzyme that is silent for transcription in the absence of enhancer-binding activator proteins. Here we show that the acidic Region II of sigmaN from Klebsiella pneumoniae is dispensable for polymerase isomerisation and trans-cription under conditions where the inhibited state of the holoenzyme is relieved by removal of sigmaN Region I sequences. Holoenzymes lacking Region I or Regions I+II were equally susceptible to the order of addition-dependent inhibition or stabilisation of DNA binding afforded by in trans Region I sequences. Region I+II-deleted [sigma] formed a holoenzyme with a DNA-binding activity more susceptible to inhibition by non-specific DNA than that lacking Region I. Region II sequences appear more closely associated with formation of a holoenzyme and [sigma] proficient in DNA binding than with changes in holoenzyme conformation needed for unmasking a single-strand DNA-binding activity used for open complex for-mation. Region II may therefore function to optimise DNA interactions for an efficient sigma cycle.

Sequences in sigmaN determining holoenzyme formation and properties

Sigma subunits of bacterial RNA polymerases are closely involved in many steps of promoter-specific transcription initiation. Holoenzyme formed with the specialised minor sigma-N (sigmaN) protein binds rare promoters in a transcriptionally inactive state and functions in enhancer-dependent transcription. Using competition and dissociation assays, we show that sigmaN-holoenzyme has a stability comparable to the major sigma70-holoenzyme. Purified partial sequences of sigmaN were prepared and assayed for retention of core RNA polymerase binding activity. Two discrete fragments of sigmaN which both bind the core but with significantly different affinities were identified, demonstrating that the sigmaN interface with core RNA polymerase is extensive. The low affinity segment of sigmaN included region I sequences, an amino terminal domain which mediates activator responsiveness and formation of open promoter complexes. The higher affinity site lies within a 95 residue fragment of region III. We propose that the core to region I contact mediates properties of the sigmaN-holoenzyme important for enhancer responsiveness. Heparin is shown to dissociate sigmaN and core, indicating that disruption of the holoenzyme is involved in the heparin sensitivity of the sigmaN closed complex.

Stability of mutations in a Sphingomonas strain

Sphingomonas sp. strain RW1 is able to mineralise dibenzofuran and dibenzo-p-dioxin. Three mutants were constructed that could not use dibenzofuran or dibenzo-p-dioxin as a carbon source but were able to grow with the succeeding metabolites of the pathway. Two different mutagenic agents were applied, a chemical treatment with 1-methyl-3-nitro-1-nitrosoguanidine, resulting in mutants RW1-N6 and RW1-N7, and a biological insertion mutagenesis with the mini-Tn5 transposon pBSL118, resulting in mutant RW1-M3. Southern blot analysis and PCR experiments confirmed a single insertion of the mini-Tn5 into one of the genes coding for the oxygenase component of the dibenzofuran 4,4a-dioxygenase system. The genetic stability of these mutants was examined after growth with complex medium under nonselective conditions. All three mutants failed to revert to wild-type metabolic functions.

A-type and B-type Epstein-Barr virus differ in their ability to spontaneously enter the lytic cycle

In this study replication of A-type and B-type Epstein-Barr virus (EBV) strains has been assessed. A-type and B-type type lymphoblastoid cell lines (LCLs) were established by infecting B lymphocytes, isolated from five EBV-seropositive donors, with different A-type and B-type virus isolates. The presence of viral capsid antigens (VCA) in these LCLs was determined by immunofluoresence assay and by immunoblotting. All of the B-type EBV strains were capable of spontaneously generating virus regardless of the origin of the donor cells. In contrast the A-type strains, other than strain IARC-BL36, did not readily produce VCA in any of the different donor lymphocytes used. This study demonstrates another biological difference between the two virus types: their ability to spontaneously enter the lytic cycle.