RbfA, a 30S ribosomal binding factor, is a cold-shock protein whose absence triggers the cold-shock response

The cold-shock response, characterized by a specific pattern of gene expression, is induced upon a downshift in temperature and in the presence of inhibitors of ribosomal function. Here, we demonstrate that RbfA of Escherichia coli, considered to be involved in ribosomal maturation and/or initiation of translation, is a cold-shock protein. Shifting the rbfA mutant to a lower temperature resulted in a constitutive induction of the cold-shock response accompanied by slower growth at low temperatures, while shifting the rbfA mutant that overproduces wild-type RbfA resulted in an increase in total protein synthesis accompanied by faster growth adaptation to the lower temperature. Furthermore, the cold-shock response was also constitutively induced in a cold-sensitive 16S rRNA mutant at low temperatures. Accompanying the transient induction of the cold-shock response, we also report that shifting E. coli from 37°C to 15°C resulted in a temporary inhibition of initiation of translation, as evidenced by the transient decrease in polysomes accompanied by the transient increase in 70S monosomes. The accumulative data indicate that the inducing signal for the cold-shock response is the increase in the level of cold-unadapted non-translatable ribo-somes which are converted to cold-adapted translatable ribosomes by the association of cold-shock proteins such as RbfA. Therefore, the expression of the cold-shock response, and thus cellular adaptation to low temperature, is regulated at the level of translation. The data also indicate that cold-shock proteins can be translated by ribosomes under conditions that are not translatable for most mRNAs.     

Expression of CspA and GST by an Antarctic psychrophilic bacterium Colwellia sp. NJ341 at near-freezing temperature

Summary A psychrotrophic bacterium Colwellia sp. NJ341 from Antarctic sea ice could grow at −5 and 22 °C, and the extent of cellular protein content and growth were greater at low temperatures (0–10 °C) than at higher temperatures. SDS-PAGE analysis demonstrated the presence of a 7 kDa cold-shock protein. The further result of two-dimensional electrophoresis (2-DE) showed that two proteins a and c were newly synthesized at near-freezing temperatures. With matrix-assisted laser desorption/ionization mass spectrometry (MALDI-TOF MS) analysis, proteins a and c were identified as glutathione S-transferase (GST) and cold-shock protein A (CspA), respectively, which were involved in cold-adaptation at near-freezing temperature in an Antarctic psychrophilic bacterium Colwellia sp. NJ341.     

Characterization of Chimeric Isocitrate Dehydrogenases of a Mesophilic Nitrogen-Fixing Bacterium, <Emphasis Type="Italic">Azotobacter vinelandii,</Emphasis> and a Psychrophilic Bacterium, <Emphasis Type="Italic">Colwellia maris</Emphasis>

Several properties of chimeric enzymes between a mesophilic isocitrate dehydrogenase (IDH) from a nitrogen-fixing bacterium, Azotobacter vinelandii, and a cold-adapted IDH isozyme (IDH-II) from a psychrophilic bacterium, Colwellia maris, were examined. Each of the genes encoding the IDHs was divided into four regions of almost equal lengths, and each region was ligated with different combinations to construct various chimeric genes. The resultant wild-type and chimeric genes were overexpressed in Escherichia coli. The wild-type and chimeric IDHs were classified into three groups based on optimum temperatures for activity of 20°, 30°, and 40°C. The IDHs with a lower optimum temperature were more thermolabile. The optimum temperature and thermostability of the chimeric enzymes decreased on increasing the proportion derived from the cold-adapted IDH-II of C. maris. Furthermore, the C-terminal region of the C. maris IDH-II was suggested to be responsible for its psychrophilic characteristics.     

Family of the major cold-shock protein, CspA (CS7.4), of Escherichia coli, whose members show a high sequence similarity with the eukaryotic Y-box binding proteins

The cspA is a gene of Escherichia coli, whose expression is specifically induced at low temperatures to a level of 13% of total protein synthesis. The CspA protein consisting of 70 amino add residues has high sequence similarity with eukaryotic Y-box DNA-binding proteins. We found two independent clones from the Kohara miniset phage collection, which hybridized with a DNA fragment containing cspA. DNA sequencing of these clones confirmed that the two genes are highly homologous to cspA. One designated cspB is mapped at 35 min on the E. coli chromosome and encodes a 71-residue protein with 79% identity to CspA, while the other, cspC, is mapped at 40 min and encodes a 69-residue protein with 70% identity. In addition, a DNA sequence upstream of the clpA gene at 19 mm published elsewhere contains an open reading frame for a 74-residue protein with 45% identity to CspA. All csp genes were fused in the coding regions with the lacZ gene, and the expression of β-galactosidase was examined for these hybrid genes upon cold shock. A similar cold-shock induction to cspA was observed for cspB but not cspC and cspD. These results Indicate that E. coli has a family of the cspA gene, some of which are induced by cold shock.     

A Nonconserved Carboxy-Terminal Segment of GroEL Contributes to Reaction Temperature

The role of the C-terminal segment of the GroEL equatorial domain was analyzed. To understand the molecular basis for the different active temperatures of GroEL from three bacteria, we constructed a series of chimeric GroELs combining the C-terminal segment of the equatorial domain from one species with the remainder of GroEL from another. In each case, the foreign C-terminal segment substantially altered the active temperature range of the chimera. Substitution of L524 of Escherichia coli GroEL with the corresponding residue (isoleucine) from psychrophilic GroEL resulted in a GroE with approximately wild-type activity at 25 °C, but also at 10 °C, a temperature at which wild-type E. coli GroE is inactive. In a detailed look at the temperature dependence of the GroELs, normal E. coli GroEL and the L524I mutant became highly active above 14 °C and 12 °C respectively. Similar temperature dependences were observed in a surface plasmon resonance assay of GroES binding. These results suggested that the C-terminal segment of the GroEL equatorial domain has an important role in the temperature dependence of GroEL. Moreover, E. coli acquired the ability to grow at low temperature through the introduction of cold-adapted chimeric or L524I mutant groEL genes.     

Cloning and Expression of <Emphasis Type="Italic">lipP</Emphasis>, A Gene Encoding a Cold-Adapted Lipase from <Emphasis Type="Italic">Moritella</Emphasis> sp.2-5-10-1

A gene (lipP, 837 bp in length) coding for a cold-adapted lipase of psychrophilic bacterium Moritella sp. 2-5-10-1 isolated from Antarctic region was cloned and sequenced in this study. The deduced amino acid sequence revealed a protein of 278 amino acid residues with a molecular mass of 30,521. The primary structure of the lipase deduced from the nucleotide sequence showed consensus pentapeptide containing the active serine [Gly-Trp-Ser-Leu-Gly] and a conserved His-Gly dipeptide in the N-terminal part of the enzyme. These sequences were involved in the lipase active site conformation. Structure factors that would allow proper enzyme flexibility at low temperatures were discussed. It was suggested that the changes in the primary structure of the psychrophilic lipases compared to the thermophilic ones could account for their ability to catalyze lipolysis at temperatures close to 0°C. For expression, the sequence corresponding to the cold-adapted lipase of strain 2-5-10-1 was subcloned into the pET-28a expression vector to construct a recombinant lipase protein. Expression of the lipase by Escherichia coli BL21 (DE3) cells was observed as clear halos on 1% (vol/vol) tributyrin upon induction with IPTG at 25°C.     

Characterization of NADP+-dependent isocitrate dehydrogenase isozymes from a psychrophilic bacterium,Colwellia psychrerythraea strain 34H

NADP⁺-dependent isocitrate dehydrogenase (IDH) isozymes of a psychrophilic bacterium, Colwellia psychrerythraea strain 34H, were characterized. The coexistence of monomeric and homodimeric IDHs in this bacterium was confirmed by Western blot analysis, the genes encoding two monomeric (IDH-IIa and IDH-IIb) and one dimeric (IDH-I) IDHs were cloned and overexpressed in Escherichia coli, and the three IDH proteins were purified. Both of the purified IDH-IIa and IDH-IIb were found to be cold-adapted enzymes while the purified IDH-I showed mesophilic properties. However, the specific activities of IDH-IIa and IDH-IIb were lower even at low temperatures than that of IDH-I. Therefore, IDH-I was suggested to be important for the growth of this bacterium. The results of colony formation of E. coli transformants carrying the respective IDH genes and IDH activities in their crude extracts indicated that the expression of the IDH-IIa gene is cold-inducible in the E. coli cells.     

Overexpression of Cold Shock Protein A of <Emphasis Type="Italic">Psychromonas arctica</Emphasis> KOPRI 22215 Confers Cold-Resistance

A polar bacterium was isolated from Arctic sea sediments and identified as Psychromonas artica, based on 16S rDNA sequence. Psychromonas artica KOPRI 22215 has an optimal growth temperature of 10 °C and a maximum growth temperature of 25 °C, suggesting this bacterium is a psychrophile. Cold shock proteins (Csps) are induced upon temperature downshift by more than 10 °C. Functional studies have researched mostly Csps of a mesophilic bacterium Escherichia coli, but not on those of psychrophilic bacteria. In an effort to understand the molecular mechanisms of psychrophilic bacteria that allow it withstand freezing environments, we cloned a gene encoding a cold shock protein from P. artica KOPRI 22215 (CspA_Pa) using the conserved sequences in csp genes. The 204 bp-long ORF encoded a protein of 68 amino acids, sharing 56% homology to previously reported E. coli CspA protein. When CspA_Pa was overexpressed in E. coli, it caused cell growth-retardation and morphological elongation. Interestingly, overexpression of CspA_Pa drastically increased the host’s cold-resistance by more than ten times, suggesting the protein aids survival in polar environments.     

Cold shock response and low temperature adaptation in psychrotrophic bacteria

Psychrotrophic bacteria are capable of developing over a wide temperature range and they can grow at temperatures close to or below freezing. This ability requires specific adaptative strategies in order to maintain membrane fluidity, the continuance of their metabolic activities, and protein synthesis at low temperature. A cold-shock response has been described in several psychrotrophic bacteria, which is somewhat different from that in mesophilic microorganisms: (i) the synthesis of housekeeping proteins is not repressed following temperature downshift and they are similarly expressed at optimal and low temperatures (ii) cold-shock proteins or Csps are synthesized, the number of which increases with the severity of the shock (iii) a second group of cold-induced proteins, i.e. the cold acclimation proteins or Caps, comparable with Csps are continuously synthesized during prolonged growth at low temperature. Homologues to CspA, the major cold-shock protein in E. coli, have been described in various psychrotrophs, but unlike their mesophilic counterparts, they belong to the group of Caps. Although they have been poorly studied, Caps are of particular importance since they differentiate psychrotrophs from mesophiles, and they are probably one of the key determinant that allow life at very low temperature.     

Molecular modelling of a psychrophilic β-galactosidase

An Antarctic strain of bacteria was isolated from the digestive tract of the crustacean Thysanoessa macrura and classified as Pseudoalteromonas sp. 22b based on 16SrRNA gene sequence and physiological as well as biochemical properties. This bacterium turned out to be a good producer of a cold-adapted β-galactosidase. The enzyme displays high catalytic and molecular adaptation to low temperatures. Here we present a homology model of the psychrophilic β-galactosidase based on the structural template of the mesophilic β-galactosidase from Escherichia coli (PDB code: 1JZ7, resolution 1.5 Å). Our aim was to identify and characterize potential cold-adaptational features of the target psychrophilic β-galactosidase at the level of the three-dimensional structure rather than solely from the analysis of the amino acid sequence. We report the results of comparisons between the psychrophilic and mesophilic β-galactosidases and point out similarities and differences in the catalytic site and in other parts of the structure. The model allowed us to pinpoint a number of characteristics that are frequently observed in psychrophilic enzymes and allowed interpretation of the results of immunochemical and biochemical analyses.     

Two isocitrate dehydrogenases from a psychrophilic bacterium, Colwellia psychrerythraea

Two structurally different monomeric and dimeric types of isocitrate dehydrogenase (IDH; EC 1.1.1.42) isozymes were confirmed to exist in a psychrophilic bacterium, Colwellia psychrerythraea, by Western blot analysis and the genes encoding them were cloned and sequenced. Open reading frames of the genes (icd-M and icd-D) encoding the monomeric and dimeric IDHs of this bacterium, IDH-M and IDH-D, were 2,232 and 1,251 bp in length and corresponded to polypeptides composed of 743 and 416 amino acids, respectively. The deduced amino acid sequences of the IDH-M and IDH-D showed high homology with those of monomeric and dimeric IDHs from other bacteria, respectively. Although the two genes were located in tandem, icd-M then icd-D, on the chromosomal DNA, a Northern blot analysis and primer extension experiment revealed that they are transcribed independent of each other. The expression of the monomeric and dimeric IDH isozyme genes in C. maris, a psychrophilic bacterium of the same genus as C. psychrerythraea, is known to be induced by low temperature and acetate, respectively, but no such induction in the expression of the C. psychrerythraea icd-M and icd-D genes was detected. IDH-M and IDH-D overexpressed in Escherichia coli were purified and characterized. In C. psychrerythraea, the IDH-M isozyme is cold-active whereas IDH-D is mesophilic, which is similar to C. maris that contains both cold-adapted and mesophilic isozymes of IDH. Experiments with chimeric enzymes between the cold-adapted monomeric IDHs of C. psychrerythraea and C. maris (IDH-M and ICD-II, respectively) suggested that the C-terminal region of the C. maris IDH-II is involved in its catalytic activity.     

Biophysical and biochemical characterization of the thioredoxin system from Colwellia psychrerythraea

The thioredoxin system is a ubiquitous oxidoreductase system consisting of the enzyme thioredoxin reductase, the protein thioredoxin, and the cofactor nicotinamide adenine dinucleotide phosphate. The system has been comprehensively studied from many organisms, such as Escherichia coli; however, structural and functional analysis of this system from psychrophilic bacteria has not been as extensive. In this study, the thioredoxin system proteins of a psychrophilic bacterium, Colwellia psychrerythraea, were characterized using biophysical and biochemical techniques. Analysis of the complete genome sequence of the C. psychrerythraea thioredoxin system suggested the presence of a putative thioredoxin reductase and at least three thioredoxin. In this study, these identified putative thioredoxin system components were cloned, overexpressed, purified, and characterized. Our studies have indicated that the thioredoxin system proteins from E. coli were more stable than those from C. psychrerythraea. Consistent with these results, kinetic assays indicated that the thioredoxin reductase from E. coli had a higher optimal temperature than that from C. psychrerythraea.     

Suitability of different β-galactosidases as reporter enzymes in <Emphasis Type="Italic">Bacillus subtilis</Emphasis>

The suitability of three β-galactosidases as reporter enzymes for promoter expression analyses was investigated in Bacillus subtilis with respect to various temperature conditions during cultivation and assay procedures. Starting from the hypothesis that proteins derived from diverse habitats have different advantages as reporters at different growth temperatures, the beta-galactosidases from the thermophilic organism Bacillus stearothermophilus, from the mesophilic bacterium Escherichia coli and from the psychrophilic organism Pseudoalteromonas haloplanktis TAE79 were analysed under control of the constitutive B. subtilis lepA promoter. Subsequent expression of the β-galactosidase genes and determination of specific activities was performed at different cultivation and assay temperatures using B. subtilis as host. Surprisingly, the obtained results demonstrated that the highest activities over a broad cultivation temperature range were obtained using the β-galactosidase from the mesophilic bacterium E. coli whereas the enzymes from the thermophilic and psychrophilic bacteria revealed a more restricted usability in terms of cultivation temperature.     

Temperature adaptation of DNA ligases from psychrophilic organisms

DNA ligases operating at low temperatures have potential advantages for use in biotechnological applications. For this reason, we have characterized the temperature optima and thermal stabilities of three minimal Lig E-type ATP-dependent DNA ligase originating from Gram-negative obligate psychrophilic bacteria. The three ligases, denoted Vib-Lig, Psy-Lig, and Par-Lig, show a remarkable range of thermal stabilities and optima, with the first bearing all the hallmarks of a genuinely cold-adapted enzyme, while the latter two have activity and stability profiles more typical of mesophilic proteins. A comparative approach based on sequence comparison and homology modeling indicates that the cold-adapted features of Vib-Lig may be ascribed to differences in surface charge rather than increased local or global flexibility which is consistent with the contemporary emerging paradigm of the physical basis of cold adaptation of enzymes.

     

Expression of a Temperature-Sensitive Esterase in a Novel Chaperone-Based Escherichia coli Strain

A new principle for expression of heat-sensitive recombinant proteins in Escherichia coli at temperatures close to 4°C was experimentally evaluated. This principle was based on simultaneous expression of the target protein with chaperones (Cpn60 and Cpn10) from a psychrophilic bacterium, Oleispira antarctica RB8^T, that allow E. coli to grow at high rates at 4°C (maximum growth rate, 0.28 h⁻¹) (M. Ferrer, T. N. Chernikova, M. Yakimov, P. N. Golyshin, and K. N. Timmis, Nat. Biotechnol. 21:1266-1267, 2003). The expression of a temperature-sensitive esterase in this host at 4 to 10°C yielded enzyme specific activity that was 180-fold higher than the activity purified from the non-chaperonin-producing E. coli strain grown at 37°C (32,380 versus 190 μmol min⁻¹ g⁻¹). We present evidence that the increased specific activity was not due to the low growth temperature per se but was due to the fact that low temperature was beneficial to folding, with or without chaperones. This is the first report of successful use of a chaperone-based E. coli strain to express heat-labile recombinant proteins at temperatures below the theoretical minimum growth temperature of a common E. coli strain (7.5°C).     

Acquirement of cold sensitivity by quadruple deletion of the cspA family and its suppression by PNPase S1 domain in Escherichia coli

Escherichia coli contains a large CspA family, CspA to CspI. Here, we demonstrate that E. coli is highly protected against cold-shock stress, as these CspA homologues existed at approximately a total of two million molecules per cell at low temperature and growth defect was not observed until four csp genes (cspA, cspB, cspE and cspG) were deleted. The quadruple-deletion strain acquired cold sensitivity and formed filamentous cells at 15 degrees C although chromosomes were normally segregated. The cold-sensitivity and filamentation phenotypes were suppressed by all members of the CspA family except for CspD, which causes lethality upon overexpression. Interestingly, the cold sensitivity of the mutant was also suppressed by the S1 domain of polynucleotide phosphorylase (PNPase), which also folds into a beta-barrel structure similar to that of CspA. The present results show that cold-shock proteins and S1 domains share not only the tertiary structural similarity but also common functional properties, suggesting that these seemingly distinct protein categories may have evolved from a common primordial RNA-binding protein.     

Development of a Cold-Adapted Pseudoalteromonas Expression System for the Pseudoalteromonas Proteins Intractable for the Escherichia coli System

Although the Escherichia coli expression system is the most commonly used expression system, some proteins are still difficult to be expressed by this system, such as proteins with high thermolability and enzymes that cannot mature by autoprocessing. Therefore, it is necessary to develop alternative expression systems. In this study, a cold-adapted Pseudoalteromonas expression system was developed. A shuttle vector was constructed, and a conjugational transfer system between E. coli and psychrophilic strain Pseudoalteromonas sp. SM20429 was established. Based on the shuttle vector, three reporter vectors were constructed to compare the strength of the cloned promoters at low temperature. The promoter of xylanase gene from Pseudoalteromonas sp. BSi20429 was chosen due to its high activity at 10–15°C. An expression vector pEV containing the chosen promoter, multiple cloning sites and a His tag was constructed for protein expression and purification. With pEV as expression vector and SM20429 as the host, a cold-adapted protease, pseudoalterin, which cannot be maturely expressed in E. coli, was successfully expressed as an active extracellular enzyme when induced by 2% oat spelt xylan at 15°C for 48 h. Recombinant pseudoalterin purified from the culture by Ni affinity chromatography had identical N-terminal sequence, similar molecular mass and substrate specificity as the native pseudoalterin. In addition, another two cold-adapted enzymes were also successfully expressed by this system. Our results indicate that this cold-adapted Pseudoalteromonas expression system will provide an alternative choice for protein expression, especially for the Pseudoalteromonas proteins intractable for the E. coli system.     

Characterization of a recombinant cold-adapted purine nucleoside phosphorylase and its application in ribavirin bioconversion

Ribavirin is a broad-spectrum antiviral drug and can be produced by enzymatic synthesis by purine nucleoside phosphorylase (PNP). In this study, we describe the application of such a cold-adapted XmPNP in ribavirin bioconversion which showed approximately 15°C lower optimum temperature and 1.80-fold higher catalytic efficiency (k_cat/K_m) at 37°C within substrate inosine than homolog in E. coli. By contrast, E. coli (XmPNP) took only 12 h to reach maximum substrate conversion rate (70%) under its optimum temperature (50°C) by using recombinant strain cell as enzyme source, but E. coli (EcPNP) did at 24 h. These results suggest cold-adapted PNP is one attractive candidate for ribavirin bioconversion and other nucleoside medications to improve the catalytic efficiency.