Comparative analysis of proteins induced by heat shock, salinity, and osmotic stress in the nitrogen-fixing cyanobacterium Anabaena sp. strain L-31.

Heat, salinity, or osmotic stress influenced protein synthesis in nitrogen-fixing Anabaena sp. strain L-31. Salinity and osmotic stresses were identical and specifically induced 15 polypeptides. Four polypeptides were unique to heat shock, and four other polypeptides were induced under every stress. The results demonstrate a commonality and a stress specificity of protein synthesis regulation.     

Salinity-stress-induced proteins in two nitrogen-fixing Anabaena strains differentially tolerant to salt.

Salinity altered the protein synthesis patterns in two cyanobacterial strains: Anabaena torulosa, a salt-tolerant brackish water strain, and Anabaena sp. strain L-31, a salt-sensitive freshwater strain. The cyanobacterial response to salinity was very rapid, varied with time, and was found to be correlated with the external salt (NaCl) concentration during stress. Salinity induced three prominent types of modification. First, the synthesis of several proteins was inhibited, especially in the salt-sensitive strain; second, the synthesis of certain proteins was significantly enhanced; and third, synthesis of a specific set of proteins was induced de novo by salinity stress. Proteins which were selectively synthesized or induced de novo during salt stress, tentatively called the salt-stress proteins, were confined to an isoelectric pI range of 5.8 to 7.5 and were distributed in a molecular mass range of 12 to 155 kilodaltons. These salt-stress proteins were unique to each Anabaena strain, and their expression was apparently regulated coordinately during exposure to salt stress. In Anabaena sp. strain L-31, most of the salt-stress-induced proteins were transient in nature and were located mainly in the cytoplasm. In A. torulosa, salt-stress-induced proteins were evenly distributed in the membrane and cytoplasmic fractions and were persistent, being synthesized at high rates throughout the period of salinity stress. These initial studies reveal that salinity-induced modification of protein synthesis, as has been demonstrated in higher plant species, also occurs in cyanobacteria and that at least some of the proteins preferentially synthesized during salt stress may be important to cyanobacterial osmotic adaptation.     

A role for osmotic stress-induced proteins in the osmotolerance of a nitrogen-fixing cyanobacterium, Anabaena sp. strain L-31.

The molecular basis of tolerance to osmotic stress was investigated with a cyanobacterium, Anabaena sp. strain L-31. The inherent osmotolerance of this strain (50% growth inhibition at 350 mM sucrose) was enhanced by adaptation with 100 mM sucrose for 30 min. Addition of 10 mM KNO3 during growth also conferred significant osmoprotection, but addition of 3 mM NH4Cl did not. Exposure of cells to 350 mM sucrose induced the expression of at least 12 osmotic-stress-induced proteins (OSPs) within 30 min, in the molecular mass range of 11.5 to 84 kDa. Exposure of cells to 100 mM sucrose or to 10 mM nitrate also induced all the OSPs, but addition of ammonium did not. The observed correspondence between the presence of OSPs and osmotolerance strongly suggests a role for OSPs in osmotolerance of Anabaena sp. strain L-31.     

A cya deletion mutant of Escherichia coli develops thermotolerance but does not exhibit a heat-shock response

An adenyl cyclase deletion mutant (cya) of E. coli failed to exhibit a heat-shock response even after 30 min at 42 degrees C. Under these conditions, heat-shock protein synthesis was induced by 10 min in the wild-type strain. These results suggest that synthesis of heat-shock proteins in E. coli requires the cya gene. This hypothesis is supported by the finding that a presumptive cyclic AMP receptor protein (CRP) binding site exists within the promoter region of the E. coli htpR gene. In spite of the absence of heat-shock protein synthesis, when treated at 50 degrees C, the cya mutant is relatively more heat resistant than wild type. Furthermore, when heat shocked at 42 degrees C prior to exposure at 50 degrees C, the cya mutant developed thermotolerance. These results suggest that heat-shock protein synthesis is not essential for development of thermotolerance in E. coli.     

Alpha subunit of eukaryotic translational initiation factor-2 is a heat-shock protein

The use of ultra high resolution giant two-dimensional gel electrophoresis has expanded the number of recognizable heat-shock proteins to 68 inductions in rat thymic lymphocytes, many of which are among the less abundant cellular proteins (Maytin, E. V., Colbert, R. A., and Young, D. A. (1985) J. Biol. Chem. 260, 2384-2392). Previous studies also show that cells receiving a prior heat shock recover more rapidly from the inhibition of protein synthesis induced by a second heat shock. In this report we use a monoclonal antibody to identify the alpha subunit of eukaryotic initiation factor-2 (eIF-2 alpha) as a heat-shock protein. Its relative rate of synthesis increases approximately 40% in the 2nd h and 5-fold in the 4th h of a continuous heat shock and is stimulated more dramatically, 15-fold, in the 3rd h of recovery from a 1-h heat shock. These results suggest that the induction of eIF-2 alpha in the heat-shock response may be important for restoring the cell's ability to initiate protein synthesis. In addition to identifying a function for one of the heat-shock proteins, our findings draw attention to the likelihood that other low-abundance heat-shock proteins may play critical roles in the heat-shock response.     

Isolation, sequence, and expression in Escherichia coli of an unusual thioredoxin gene from the cyanobacterium Anabaena sp. strain PCC 7120.

Two sequences with homology to a thioredoxin oligonucleotide probe were detected by Southern blot analysis of Anabaena sp. strain PCC 7120 genomic DNA. One of the sequences was shown to code for a protein with 37% amino acid identity to thioredoxins from Escherichia coli and Anabaena sp. strain PCC 7119. This is in contrast to the usual 50% homology observed among most procaryotic thioredoxins. One gene was identified in a library and was subcloned into a pUC vector and used to transform E. coli strains lacking functional thioredoxin. The Anabaena strain 7120 thioredoxin gene did not complement the trxA mutation in E. coli. Transformed cells were not able to use methionine sulfoxide as a methionine source or support replication of T7 bacteriophage or the filamentous viruses M13 and f1. Sequence analysis of a 720-base-pair TaqI fragment indicated an open reading frame of 115 amino acids. The Anabaena strain 7120 thioredoxin gene was expressed in E. coli, and the protein was purified by assaying for protein disulfide reductase activity, using insulin as a substrate. The Anabaena strain 7120 thioredoxin exhibited the properties of a conventional thioredoxin. It is a small heat-stable redox protein and an efficient protein disulfide reductase. It is not a substrate for E. coli thioredoxin reductase. Chemically reduced Anabaena strain 7120 thioredoxin was able to serve as reducing agent for both E. coli and Anabaena strain 7119 ribonucleotide reductases, although with less efficiency than the homologous counterparts. The Anabaena strain 7120 thioredoxin cross-reacted with polyclonal antibodies to Anabaena strain 7119 thioredoxin. However, this unusual thioredoxin was not detected in extracts of Anabaena strain 7120, and its physiological function is unknown.     

Oxygen inactivation and recovery of nitrogenase activity in cyanobacteria.

Exposure of nitrogen-fixing cultures of Anabaena spp. to 100% oxygen resulted in the rapid decline of nitrogenase activity. When oxygen-treated cells were transferred to 100% argon, nitrogenase activity was quickly restored in a process that required protein synthesis. Anaerobiosis was not essential for the recovery process; in fact, cells of Anabaena sp. strains CA and 1F will recover nitrogenase activity after prolonged incubation in 100% oxygen. Oxygen treatment acted directly on the intracellular nitrogenase and did not affect other metabolic processes. Examination of crude extracts of oxygen-treated Anabaena sp. strain CA indicated that both components of nitrogenase are inactivated. However, several lines of evidence suggest that oxygen treatment does not result in irreversible denaturation of nitrogenase, but rather results in a reversible inactivation which may serve as a protection mechanism. Nitrogenase present in crude extracts from cells of Anabaena sp. strain 1F which had been incubated for a prolonged period in 100% oxygen was less sensitive to oxygen in vitro than was nitrogenase of a crude extract of untreated cells.     

A chimeric Anabaena/ Escherichia coli KdpD protein (Anacoli KdpD) functionally interacts with E. coli KdpE and activates kdp expression in E. coli

The kdpFABC operon, coding for a high-affinity K(+)-translocating P-type ATPase, is expressed in Escherichia coli as a backup system during K(+) starvation or an increase in medium osmolality. Expression of the operon is regulated by the membrane-bound sensor kinase KdpD and the cytosolic response regulator KdpE. From a nitrogen-fixing cyanobacterium, Anabaena sp. strain L-31, a kdpDgene was cloned (GenBank accession no. AF213466) which codes for a KdpD protein (365 amino acids) that lacks both the transmembrane segments and C-terminal transmitter domain and thus is shorter than E. coli KdpD. A chimeric kdpD gene was constructed and expressed in E. coli coding for a protein (Anacoli KdpD), in which the first 365 amino acids of E. coli KdpD were replaced by those from Anabaena KdpD. In everted membrane vesicles, this chimeric Anacoli KdpD protein exhibited activities, such as autophosphorylation, transphosphorylation and ATP-dependent dephosphorylation of E. coli KdpE, which closely resemble those of the E. coli wild-type KdpD. Cells of E. coli synthesizing Anacoli KdpD expressed kdpFABC in response to K(+) limitation and osmotic upshock. The data demonstrate that Anabaena KdpD can interact with the E. coliKdpD C-terminal domain resulting in a protein that is functional in vitro as well as in vivo.     

Expression of the Anabaena sp. strain PCC 7120 xisA gene from a heterologous promoter results in excision of the nifD element.

An 11-kilobase-pair element interrupts the nifD gene in vegetative cells of Anabaena sp. strain PCC 7120. The nifD element normally excises only from the chromosomes of cells that differentiate into nitrogen-fixing heterocysts. The xisA gene contained within the element is required for the excision. Shuttle vectors containing the Escherichia coli tac consensus promoter fused to various 5' deletions of the xisA gene were constructed and conjugated into Anabaena sp. strain PCC 7120 cells. Some of the expression plasmids resulted in excision of the nifD element in a high proportion of vegetative cells. Excision of the element required deletion of an xisA 5' regulatory region which presumably blocks expression in Anabaena sp. strain PCC 7120 vegetative cells but not in E. coli. Strains lacking the nifD element grew normally in medium containing a source of combined nitrogen and showed normal growth and heterocyst development in medium lacking combined nitrogen. The xisA gene was shown to be the only Anabaena gene required for the proper rearrangement in E. coli of a plasmid containing the borders of the nifD element.     

Asymmetric segregation of heat-shock proteins upon cell division in Caulobacter crescentus

Three Caulobacter crescentus heat-shock proteins were shown to be immunologically related to the Escherichia coli heat-shock proteins GroEL, Lon and DnaK. A fourth heat-shock protein was detected with antibody to the C. crescentus RNA polymerase. This 37,000 Mr heat-shock protein might be related to the E. coli 32,000 Mr heat-shock sigma subunit. The synthesis of the major C. crescentus RNA polymerase sigma factor was not induced by heat shock. The E. coli GroEL protein and the related protein from C. crescentus were also induced by treatment with hydrogen peroxide. Like some of the proteins in the heat-shock protein families of Drosophila and yeast, the four heat-shock proteins in C. crescentus were found to be regulated developmentally under normal conditions. All four proteins were synthesized in the predivisional cell, but the progeny showed cell type-specific bias in the level of enhanced synthesis after heat shock. The 92,000 Mr Lon homolog and the 37,000 Mr RNA polymerase subunit were preferentially synthesized in the stalked cell, whereas the synthesis of the 62,000 Mr GroEL homolog was enhanced in the progeny swarmer cell. Furthermore, the four heat-shock proteins synthesized in the predivisional cell were partitioned in a specific manner upon cell division. The stalked cell, which initiates chromosome replication immediately upon division, received the Lon homolog, the DnaK homolog and the 37,000 Mr RNA polymerase subunit. The GroEL homolog, however, was distributed equally to both the stalked cell and the swarmer cell. These results provide access to the functions of C. crescentus heat-shock proteins under both normal and stress conditions. They also allow an investigation of the regulatory signals that modulate the asymmetric distribution of proteins and their subsequent cell type-specific expression in the initial stages of a developmental program.     

Genes for two subunits of acetyl coenzyme A carboxylase of Anabaena sp. strain PCC 7120: biotin carboxylase and biotin carboxyl carrier protein.

Genes for two subunits of acetyl-coenzyme A carboxylase, biotin carboxylase and biotin carboxyl carrier protein, have been cloned from Anabaena sp. strain PCC 7120. The two proteins are 181 and 447 amino acids long and show 40 and 57% identity to the corresponding Escherichia coli proteins, respectively. The sequence of the biotinylation site in Anabaena sp. strain PCC 7120 is MetLysLeu, not the MetLysMet found in other sequences of biotin-dependent carboxylases. The amino acid sequence of biotin carboxylase is also very similar (32 to 47% identity) to the sequence of the biotin carboxylase domain of other biotin-dependent carboxylases. Genes for these two subunits of acetyl-coenzyme A carboxylase are not linked in Anabaena sp. strain PCC 7120, contrary to the situation in E. coli, in which they are in one operon.     

The induction of stress proteins in three marine Vibrio during carbon starvation

Abstract The induction of DnaK and GroEL homologous proteins by heat-shock and long-term carbon starvation was studied in Vibrio vulnificus, Vibrio sp. strain S14, and Vibrio sp. strain DW1. In each Vibrio strain one protein (60 kDa) reacted with antibodies against Escherichia coli -GroEL and two proteins, DnaK (69 kDa) and Sis1 (62-60 kDa), reacted with antibodies against E. coli -Dnak. The carbon starvation elicited induction of the stress proteins was strain-specific, suggesting that the induction of stress proteins like DnaK and GroEL in marine Vibrios might not be a uniform starvation response. It appears as of these proteins, only DnaK in Vibrio sp. strain S14 remains induced after long-term carbon starvation in the three marine bacterial strains that were tested.     

Genes encoding the beta and epsilon subunits of the proton-translocating ATPase from Anabaena sp. strain PCC 7120.

The genes encoding the beta (atpB) and epsilon (atpE) subunits of the ATPase from the cyanobacterium Anabaena sp. strain PCC 7120 were cloned, and their sequences were determined. atpB and atpE are each single-copy genes in the Anabaena genome. The two genes are separated by a 96-base-pair intergenic spacer and transcribed as a single mRNA of 2.3 kilobases that initiates approximately 200 base pairs upstream of the atpB coding region. The predicted translation product of atpB has 81 and 68% amino acid identity with the corresponding proteins from spinach chloroplasts and Escherichia coli, respectively. The atpE gene product is less conserved, with 41 and 33% amino acid identity with the corresponding proteins from spinach chloroplasts and E. coli, respectively. The organization of the Anabaena atpB and atpE genes relative to adjacent genes differs from that of both E. coli and chloroplasts.     

Cloning, expression, and characterization of the Anabaena thioredoxin gene in Escherichia coli.

The gene encoding thioredoxin in Anabaena sp. strain PCC 7119 was cloned in Escherichia coli based on the strategy that similarity between the two thioredoxins would be reflected both in the gene sequence and in functional cross-reactivity. DNA restriction fragments containing the Anabaena thioredoxin gene were identified by heterologous hybridization to the E. coli thioredoxin gene following Southern transfer, ligated with pUC13, and used to transform an E. coli strain lacking functional thioredoxin. Transformants that complemented the trxA mutation in E. coli were identified by increased colony size and confirmed by enzyme assay. Expression of the cloned Anabaena thioredoxin gene in E. coli was substantiated by subsequent purification and characterization of the algal protein from E. coli. The amino acid sequence derived from the DNA sequence of the Anabaena gene was identical to the known amino acid sequence of Anabaena thioredoxin. The E. coli strains which expressed Anabaena thioredoxin complemented the TrxA- phenotype in every respect except that they did not support bacteriophage T7 growth and had somewhat decreased ability to support bacteriophages M13 and f1.     

Limited stress response in Streptococcus pneumoniae.

In Streptococcus pneumoniae, heat shock induces the synthesis of 65-, 73-, and 84-kDa proteins, and ethanol shock induces a 104-kDa protein. In this study, the 65-, 84-, and 104-kDa proteins were identified as members of the GroEL, ClpL and alcohol dehydrogenase families, respectively, and the general properties of the stress response of S. pneumoniae to several other stresses were characterized. However, several stresses which are known to induce stress responses in Escherichia coli and Bacillus subtilis failed to induce any high molecular weight heat-shock proteins (HSPs) such as GroEL and DnaK homologues. A minor temperature shift from 30 to 37 C triggered induction of the homologues of DnaK and GroEL of E. coli. These features may provide a foundation for evaluating the role of heat-shock proteins relative to the physiology and pathogenesis of pneumococcus.     

Stress Protein and Crystallin Synthesis During Heat Shock and Transdifferentiation of Embryonic Chick Neural Retina Cells

Embryonic chick neural retina responds to heat shock by the synthesis of "stress" polypeptides with molecular weights of 85 and 70 kd. Both stress proteins are synthesised from newly-transcribed messenger RNA. Sodium arsenite induces an additional stress protein of MW 25 kd. The heat shock response does not change during culture and subsequent transdifferentiation, and crystallin synthesis is not coinducible with the heat-shock proteins. We have also examined the pattern of protein synthesis at various stages of culture in both monolayer and aggregate systems; although changes in the protein synthetic profine are evident, there is no stress protein induction above basal levels at any time. Whilst mammalian α crystallin (B₂ chain) exhibits considerable homology to four small Drosophila heat-shock proteins, no significant antigenic similarity is apparent between δ crystallin and the major avian heat shock proteins. Thus during transdifferentiation, (a) the crystallin proteins do not behave in a manner analogous to stress proteins; moreover (b) crystallin production is not mediated by stress proteins resulting from a culture-induced stress response.     

Tn5 mutagenesis of Anabaena sp. strain PCC 7120: isolation of a new mutant unable to grow without combined nitrogen.

Methylation by Ava methylases in Escherichia coli increases the efficiency to transfer of Tn5 in pBR322bla:: Tn5 from E. coli to Anabaena sp. strain PCC 7120 by conjugation. Following conjugation, Tn5 but not pBR322 sequences were found at many different positions in the Anabaena chromosome. This procedure was used to mutagenize, tag, and clone a previously unrecognized gene required for nitrogen fixation in this Anabaena sp.