Regulation of nitrogenase messenger RNA synthesis and stability in Klebsiella pneumoniae

Phenotypic heterogeneity driven by nutrient limitation promotes growth in fluctuating environments

Most microorganisms live in environments where nutrients are limited and fluctuate over time. Cells respond to nutrient fluctuations by sensing and adapting their physiological state. Recent studies suggest phenotypic heterogeneity(1) in isogenic populations as an alternative strategy in fluctuating environments, where a subpopulation of cells express a function that allows growth under conditions that might arise in the future(2-9). It is unknown how environmental factors such as nutrient limitation shape phenotypic heterogeneity in metabolism and whether this allows cells to respond to nutrient fluctuations. Here, we show that substrate limitation increases phenotypic heterogeneity in metabolism, and this heterogeneity allows cells to cope with substrate fluctuations. We subjected the N2-fixing bacterium Klebsiella oxytoca to different levels of substrate limitation and substrate shifts, and obtained time-resolved single-cell measurements of metabolic activities using nanometre-scale secondary ion mass spectrometry (NanoSIMS). We found that the level of NH4(+) limitation shapes phenotypic heterogeneity in N2 fixation. In turn, the N2 fixation rate of single cells during NH4(+) limitation correlates positively with their growth rate after a shift to NH4(+) depletion, experimentally demonstrating the benefit of heterogeneity. The results indicate that phenotypic heterogeneity is a general solution to two important ecological challenges-nutrient limitation and fluctuations-that many microorganisms face.

Characterization of the Staphylococcus aureus heat shock, cold shock, stringent, and SOS responses and their effects on log-phase mRNA turnover

Despite its being a leading cause of nosocomal and community-acquired infections, surprisingly little is known about Staphylococcus aureus stress responses. In the current study, Affymetrix S. aureus GeneChips were used to define transcriptome changes in response to cold shock, heat shock, stringent, and SOS response-inducing conditions. Additionally, the RNA turnover properties of each response were measured. Each stress response induced distinct biological processes, subsets of virulence factors, and antibiotic determinants. The results were validated by real-time PCR and stress-mediated changes in antimicrobial agent susceptibility. Collectively, many S. aureus stress-responsive functions are conserved across bacteria, whereas others are unique to the organism. Sets of small stable RNA molecules with no open reading frames were also components of each response. Induction of the stringent, cold shock, and heat shock responses dramatically stabilized most mRNA species. Correlations between mRNA turnover properties and transcript titers suggest that S. aureus stress response-dependent alterations in transcript abundances can, in part, be attributed to alterations in RNA stability. This phenomenon was not observed within SOS-responsive cells.

Modulation of pigment profiles of Calothrix elenkenii in response to environmental changes

Cyanobacteria are versatile tetrapyrrole synthesizers that can regulate their tetrapyrrole content and composition in response to environmental signals. The present investigation analyses the interplay between light and dark regimes (continuous light, light-dark cycles (16:8) and continuous darkness) and aerobic, air-tight, and anaerobic environments (argon-enriched), on the relative composition of various pigments and growth attributes of Calothrix elenkenii as a prelude to exploiting C. elenkenii's bioindustrial potential as a source of pigments. Incubation in an anaerobic environment stimulated hormogonia formation and induced colouration/thickening of cells. Aerobically grown cultures of Calothrix, under continuous illumination produced the maximum amount of total phycobiliproteins and sugars, although chlorophyll accumulation and nitrogenase activity were highest in the light-dark environment. However, the beta-carotene content was observed to vary under anaerobic conditions with different light-dark regimes. This C. elenkenii strain can be a valuable source of pigments under optimized environmental conditions.

Importance of cis determinants and nitrogenase activity in regulated stability of the Klebsiella pneumoniae nitrogenase structural gene mRNA

The Klebsiella pneumoniae nitrogen fixation (nif) mRNAs are unusually stable, with half-lives of 20 to 30 min under conditions favorable to nitrogen fixation (limiting nitrogen, anaerobiosis, temperatures of 30 degrees C). Addition of O2 or fixed nitrogen or temperature increases to 37 degrees C or more result in the dramatic destabilization of the nif mRNAs, decreasing the half-lives by a factor of 3 to 5. A plasmid expression system, independent of nif transcriptional regulation, was used to define cis determinants required for the regulated stability of the 5.2-kb nifHDKTY mRNA and to test the model suggested by earlier work that NifA is required in trans to stabilize nif mRNA under nif-derepressing conditions. O2 regulation of nifHDKTY mRNA stability is impaired in a plasmid containing a deletion of a 499-bp region of nifH, indicating that a site(s) required for the O2-regulated stability of the mRNA is located within this region. The simple model suggested from earlier work that NifA is required for stabilizing nif mRNA under conditions favorable for nitrogen fixation was disproved, and in its place, a more complicated model involving the sensing of nitrogenase activity as a component of the system regulating mRNA stability is proposed. Analysis of nifY mutants and overexpression suggests a possible involvement of the protein in this sensing process.

The role of mRNA degradation in the regulated expression of bacterial photosynthesis genes

Regulation of gene expression in bacteria, as in eukaryotic cells, is often achieved by variation of mRNA levels. Since the steady state levels of mRNA depend on both the rate of synthesis and the rate of decay, both mechanisms are important for gene regulation. After considerable effort undertaken over many years to understand the regulation of transcription, mRNA degradation has recently gained increasing attention as an important step in the regulation of some bacterial genes, and many investigations have addressed the mechanisms involved in mRNA decay. The puf mRNA of Rhodobacter capsulatus encoding pigment binding proteins has become a model system to study decay of a polycistronic mRNA and the role of mRNA degradation in gene expression. Individual segments of the polycistronic puf mRNA display extremely different half-lives. These differences in stability of mRNA segments are involved in the differential expression of puf encoded genes and consequently contribute to the stoichiometry of light-harvesting I and reaction centre complexes that results in optimal growth. In addition, control of mRNA stability is involved in the oxygen-dependent regulation of photosynthesis genes. High oxygen tension results in decreased stability of the reaction-centre specific puf mRNA segment, most likely by affecting the rate of endonucleolytic cleavage within the reaction centre coding region. The results obtained from studying puf mRNA degradation in R. capsulatus and Escherichia coli suggest that a specific distribution of decay promoting and decay impeding mRNA elements along the polycistronic mRNA is responsible for the different half-lives of individual puf segments.

Transcriptional analysis of the fix ABCXORF1 region of Azorhizobium caulinodans suggests post-transcriptional processing of the fix ABCXORF1 mRNA

We report here the transcriptional analysis of the fixABCXORF1 region of Azorhizobium caulinodans. This led to the identification of a 0.9 kb transcript covering fixX and ORF1, which was synthesized only under conditions of nitrogen fixation. The 5' end of this transcript was mapped by primer extension and S1 nuclease protection analyses and shown to be located 70 +/- 1 nucleotides upstream of the fixX start codon. By means of transcriptional fixX- and ORF1-lacZ fusions, it was shown that fixX and ORF1 were most probably transcribed from the fixA promoter and that expression of fixX and ORF1 was dependent on NifA activation. This suggests that the 0.9 kb mRNA results from post-transcriptional processing of a large mRNA covering fixA,B,C,X and ORF1. In addition, ORF1 mutants were constructed and were shown not to be impaired in nitrogenase activity.

Differential stability of mRNA species of Alcaligenes eutrophus soluble and particulate hydrogenases

The functional half-lives of Alcaligenes eutrophus hydrogenase mRNAs were determined by physiological studies. Evidence was obtained for a functional half-life of about 1 h for the soluble NAD-linked hydrogenase (HoxS) mRNA and 14 min for the particulate hydrogenase (HoxP) mRNA. The synthesis of active HoxS continued for about 4 h, albeit at a decreasing rate after inhibition of transcription, e.g., by rifampin. In this strain, the mRNA of HoxS appeared to be stable, while the mRNA of HoxP did not. Different species of hoxS mRNA were detected by the Northern (RNA) hybridization technique using as a probe plasmid pCH139 carrying hoxS structural genes. The sizes of the major hoxS mRNA species were 7.6, 6.2, 5.0, and 0.9 kb. The chemical half-lives of these species ranged from 1 h (5.0-kb mRNA) to 7 h (0.9-kb mRNA). Evidence for a specific cleavage of the 6.2-kb transcript yielding the 0.9-kb species was obtained from RNA-DNA hybridizations with subcloned hoxS DNA. The chemical half-life of total hoxP mRNA was 8 min.

Changes in gene expression during nitrogen starvation in Anabaena variabilis ATCC 29413

When the filamentous, nitrogen-fixing cyanobacterium Anabaena variabilis ATCC 29413 was subjected to nitrogen starvation under aerobic conditions, a complex series of events was initiated which resulted in heterocyst formation and derepression of the ability to fix dinitrogen. Using DNA-RNA hybridization techniques, we monitored the expression of several genes during nitrogen starvation and correlated changes in the mRNA levels with changes in enzyme activity, protein levels, and morphology. Nitrogenase mRNA was first observed after about 8.5 h of nitrogen starvation, as was nitrogenase activity. Late proheterocysts were present at that time. The level of nitrogenase mRNA increased for 5 to 6 h and then leveled off. Phycocyanin and allophycocyanin mRNA levels decreased rapidly within 1 h of nitrogen starvation; the levels increased later, as nitrogen starvation was alleviated, first by protein breakdown and then by nitrogen fixation. The average half-life of A. variabilis mRNA was determined by pulse-labeling techniques to be 16 to 18 min. Hybridization analysis showed that cpc and apc mRNAs also had half-lives of 16 to 18 min; the half-lives were not significantly different under nitrogen starvation conditions. Our results support the idea that the changes induced by nitrogen starvation are primarily the result of transcriptional regulation.

How is nitrogenase regulated by oxygen?

Oxygen can be either beneficial or detrimental for diazotrophy in organisms capable of an aerobic catabolism. It supports the production of a substrate for nitrogenase (ATP), but it can also inhibit the activity and repress the synthesis of this enzyme. Here, aspects of the relevant physiology are reviewed with particular emphasis on those relating to the mechanism of O2 regulation of nitrogenase synthesis.

Regulation of nitrogenase gene expression in anaerobic cultures of Anabaena variabilis

Derepression of nitrogenase gene expression was studied at the mRNA and enzyme activity levels in anaerobic cultures of Anabaena variabilis 29413. Cells, previously grown with ammonium chloride, were incubated in the absence of fixed nitrogen compounds under an Ar atmosphere with dichlorophenyldimethyl-urea present to inhibit oxygen evolution. The appearance of nitrogenase mRNA (measured by dot blot hybridization analysis) and nitrogenase activity (measured as acetylene-reducing activity) was followed, and the cells were also observed by phase-contrast microscopy. Nitrogenase mRNA could be detected after 1.5 to 2.0 h of nitrogen starvation; enzyme activity appeared about 1 h later. Although enzyme activity increased for many hours, mRNA levels reached a steady state rapidly. Neither heterocysts nor proheterocysts formed under these conditions; however, the cells were observed to shrink and become chlorotic. When anaerobic, derepressed cultures were exposed to oxygen, nitrogenase mRNA levels decreased very rapidly.

Regulation of nitrogenase synthesis in histidine auxotrophs of Klebsiella pneumoniae with altered levels of adenylate nucleotides

A histidine auxotrophic (hisA) mutant of Klebsiella pneumoniae is phenotypically Nif- when grown with 20 micrograms of histidine ml-1 but Nif+ when supplied with histidine at 100 micrograms ml-1. Reversion to Nif+ at 20 micrograms of histidine ml-1 occurs phenotypically by the addition of 2-thiazolyl-DL-alanine or genetically by mutation in hisG; 2-thiazolyl-DL-alanine inhibits and hisG encodes phosphoribosyl phosphotransferase, the first enzyme of the histidine biosynthetic pathway which consumes ATP. Physiological studies of the hisA mutant JS85 showed that after removal of NH4+ from a culture of the mutant grown with 20 micrograms of histidine ml-1, synthesis of nitrogenase polypeptides occurred at a rate similar to that in the wild type for about 3 h and acetylene reduction activity reached about 10% of the fully derepressed wild-type level. Shortly thereafter the concentration of intracellular adenylates decreased; in particular, ATP fell to about 10% of normal levels. Also, nitrogenase proteins (nifHDK products) and the nifJ gene product stopped being synthesized. These effects were not due to impairment of growth or protein synthesis by histidine starvation. Inhibition of phosphoribosyl phosphotransferase with 2-thiazolyl-DL-alanine restored nitrogenase activity and synthesis, indicating that the effect of the hisA mutation on nif expression was probably a consequence of lowered energy resources that occurred during anaerobic N starvation. The loss of ATP was not associated with nitrogenase synthesis or activity, since hisA nifA and hisA nifH double mutants underwent a loss of ATP in derepressing conditions. Transcription from the nifL, nifN, and nifH promoters was examined in hisA strains with Mu d(Ap lac) fusions in these nif genes. Transcription was not significantly influenced under conditions where adenylates were decreased in concentration. Also nif mRNA apparently accumulated in cultures unable to synthesize nitrogenase, suggesting that translational control of nif gene product synthesis occurs under unfavorable energetic conditions.

Posttranscriptional control of Klebsiella pneumoniae nif mRNA stability by the nifL product

Posttranscriptional control of nif mRNA stability was demonstrated by functional and chemical analyses, using specific probes for four nif transcripts. In the wild type, nif transcripts (except nifLA) were stable during derepression, with half-lives of approximately 30 min. They were dramatically destabilized by O2 or elevated temperature (41 degrees C) and to a lesser extent by NH4+. In contrast, the nifLA message was not particularly stable, and posttranscriptional control was not evident. In NifL- strains, both forms of analysis indicated that the nifL product was involved in nif mRNA destabilization in the presence of O2 and NH4+.

Temperature sensitivity of a nifA-like gene in Enterobacter cloacae

Nitrogen fixation (nif) genes of Enterobacter cloacae, a rhizosphere diazotroph of rice plants, were identified by using cloned Klebsiella pneumoniae nif gene fragments as probes for molecular hybridization. The product of a nifA-like gene of E. cloacae appeared less temperature sensitive than the K. pneumoniae nifA gene product. This result correlates with the fact that E. cloacae can fix nitrogen at 39 degrees C, while K. pneumoniae cannot.

Control of Klebsiella pneumoniae nif mRNA synthesis

Four probes, each specific for a single nif transcript, were used for an analysis of the regulation of nif mRNA synthesis. Transcription of the nifLA operon was repressed by NH4+ but not by amino acids, O2, or temperatures above 37 degrees C. The nifA gene product was required for the activation of transcription of the other nif operons but not nifLA. Synthesis of the other nif transcripts was rapidly turned off by the addition of O2, NH4+, serine, or glutamine. These regulatory effects required the nifL product. However, the nifL product was not required for the cessation of synthesis of these transcripts at elevated temperatures.

A molecular genetic study of nif expression in Klebsiella pneumoniae at the level of transcription, translation and nitrogenase activity

A comprehensive study of nif expression in Klebsiella pneumoniae at the level of transcription, translation and nitrogenase activity during derepression and repression by NH+4 and O2 revealed that (1) transcription and translation rates remained coupled under all conditions; (2) these rates reached a peak during derepression and then decreased to a low level; (3) the transcription profile of nifLA had two peaks; the first was at 1 h before and the second coincided with that of the other operons; and (4) the peaks of nif transcription coincided with a trough in the profile of stringent regulation of RNA synthesis. Our results provide strong evidence that nif-specific repression by NH+4 and O2 occurs exclusively by transcription inhibition and that repression by O2 is independent of transcriptional regulation of the nifLA operon. We have also found evidence which together with the results of previous work shows that O2 repression of nifA mediated transcription involves the nifL gene product.

In vitro synthesis of the delta-lysin of Staphylococcus aureus

The stability of mRNA for the delta-lysin of Staphylococcus aureus was determined by measuring the residual lysin synthesis after inhibition of DNA-dependent RNA polymerase activity with rifampin. At the late logarithmic-early stationary phase of growth the delta-lysin mRNA was very stable, with a half-life of ca. 20 min. Total cellular RNA was extracted from S. aureus and translated with a modified Escherichia coli S-30 system; delta-lysin was identified amongst the translation products by immunoprecipitation and immunoabsorption. The delta-lysin synthesized in vitro was of a size similar to mature delta-lysin and did not require a signal sequence for secretion from the cell.

Synthesis of pigment-binding protein in toluene-treated Rhodopseudomonas capsulata and in cell-free systems

Pigment-binding protein of the facultatively phototrophic bacterium Rhodospeudomonas capsulata could be selectively synthesized in toluene-treated cells as well as in homologous and heterologous cell-free translation systems by isolated polysomes. It is shown that the pigment-binding polypeptides of the light-harvesting complexes are encoded by messenger RNA of extreme longevity. The dependence of their synthesis on the concomitant synthesis of tetrapyrroles was demonstrated in the toluene-treated cells. The large Mr-28 000 polypeptide of the reaction center and the Mr-10 000 pigment-binding polypeptide of the light-harvesting complex II were found to be synthesized by free (water-soluble) polysomes without a cleavable 'leader' or 'signal' peptide [reviewed by W. Wickner (1979) Annu. Rev. Biochem. 48, 23-45]. The Mr-10 000 polypeptide, as synthesized in vitro, was studied in more detail. Unlike the membrane-assembled polypeptide in vivo it was insoluble in an organic solvent mixture (chloroform/methanol 1:1, v/v). After detergent denaturation in the presence of membrane isolated from the organism it became organic-solvent-soluble. Obviously the polypeptide could be induced to assume alternative conformations in which its apolar residues were either exposed to the solvent or buried within. These findings, in agreement with Wickner's hypothesis, indicate that the Mr-10 000 polypeptide may enter the lipid bilayer by a 'membrane-triggered' conformational change.