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Genome-Wide Transcriptional Analysis of the Cold Shock Response in Wild-Type and Cold-Sensitive, Quadruple-csp-Deletion Strains of Escherichia coli

Department of Biochemistry, Robert Wood Johnson Medical School, Piscataway, New Jersey

Received 6 February 2004/ Accepted 22 July 2004

	ABSTRACT

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A DNA microarray-based global transcript profiling of Escherichia coli in response to cold shock showed that in addition to the known cold shock-inducible genes, new genes such as the flagellar operon, those encoding proteins involved in sugar transport and metabolism, and remarkably, genes encoding certain heat shock proteins are induced by cold shock. In the light of strong reduction in metabolic activity of the cell after temperature downshift, the induction of sugar metabolism machinery is unexpected. The deletion of four csps (cspA, cspB, cspG, and cspE) affected cold shock induction of mostly those genes that are transiently induced in the acclimation phase, emphasizing that CspA homologues are essential in the acclimation phase. Relevance of these findings with respect to the known RNA chaperone function of CspA homologues is discussed.

	TEXT

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The cold shock response is a physiological response of living cells to temperature downshift (12) and has been studied in detail using Escherichia coli and Bacillus subtilis as model systems (for a review, see references 5, 21, 26, and 32). When an exponentially growing culture of E. coli is shifted from 37 to 15°C, an acclimation phase (lag period of cell growth) characterized by transient dramatic induction of cold shock proteins against a severe inhibition of general protein synthesis precedes the resumption of growth. Out of the nine CspA homologues of E. coli, only CspA, CspB, CspG, and CspI are cold shock inducible (6, 17, 20, 31). Interestingly, double or triple deletions of genes encoding cold shock-inducible CspA homologues do not result in cold sensitivity. In a triple-deletion strain, the cspA cspB cspG strain, CspE that is normally produced at 37°C is overproduced at low temperatures (33). This observation suggests that the functions of the CspA family members may overlap and they are able to substitute for each other during cold acclimation. Indeed a quadruple-deletion strain (the cspA cspB cspG cspE strain) of E. coli exhibits cold sensitivity at 15°C, which can be complemented by overproduction of any one of the CspA homologues except CspD (33).

In spite of a wealth of knowledge accumulated in recent years, the cold shock response is not fully elucidated. The proteomic approaches that so far have been extremely useful in identification of many cold shock-induced proteins do have certain limitations: (i) not all the proteins can be resolved well on two-dimensional gel electrophoresis, and (ii) identification of proteins from the gel may sometimes be cumbersome. To overcome these shortcomings, in the present study, we carried out analysis of global cold shock gene expression profiles of an E. coli wild-type and cold-sensitive quadruple-deletion strain. Our main objectives were (i) to identify the E. coli open reading frames that exhibit significant increase or decrease in mRNA abundance caused by the temperature downshift and (ii) to explore the effect of deletion of four csp genes that leads to cold sensitivity. In brief, the E. coli JM83 strain [F^– ara(lac-proAB) rpsL(Str^r)] (35) (considered the wild-type strain in this study) was grown in Luria broth (LB). The cells grown overnight in LB medium at 37°C were diluted into fresh LB medium. Cells were grown at 37°C to exponential phase (optical density at 600 nm [OD₆₀₀] of 0.8), and part of the cell culture was harvested and used as a control. Aliquots of the cells were transferred to a prechilled LB medium at 15°C, and the cells were harvested after 1 and 5 h of cold shock. The OD₆₀₀ did not increase after 1 h of cold shock, while after 5 h of cold shock, it was 1.2. The 37°C controls were of corresponding OD₆₀₀ values. For studies involving the quadruple-deletion strain, the wild-type and the deletion strain were grown at 37°C and subsequently cold shocked for 1 h as described above. Note that in the studies involving the quadruple-deletion strain, both the wild-type and the deletion cells are cold shocked at 15°C for 1 h and compared with each other. This enables us to directly single out the genes that were differentially expressed as a result of csp deletion upon cold shock. The RNA extraction and hybridization and DNA array analysis were carried out as described previously (24). The cell density of all samples used was the same; thus, the changes seen in the microarray were not substantially influenced by the difference in cell densities. Genes whose expression levels differed by a ratio of at least 4 after cold shock were considered. From replicates, we estimate that the chance random fluctuations giving rise to a fourfold up- or down-modulation is less than 0.14%, corresponding to a confidence interval of 99.86%. Thus, the chosen fourfold cutoff value is rather stringent and the modulation of expression beyond the cutoff is highly statistically significant. In some cases, genes belonging to the same operon or category were considered even if the ratios did not adhere to these specified values. Ratios above 1 indicate induction and below 1 indicate repression. Ratios averaged from three independent of sets of experiments are shown with standard deviation values.

The result of the microarray analysis was confirmed by Northern blot analysis. The genes chosen for these experiments represent the important groups changed by the cold shock treatment, such as cspA and those encoding proteins involved in sugar metabolism, molecular chaperones, and iron metabolism. The deoxyoligonucleotides used for detection of cspA and dps were described previously (22, 24, 34). The deoxyoligonucleotides used for detection of malT (4) (accession number M13585), mopB (19), rbsD (3), and fecA (29) correspond to the region from codons 13 to 6 of malT and mopB, 21 to 14 of rbsD, and 13 to 8 of fecA. The Northern blot analysis was carried out as described previously (30). The results are shown in Fig. 1. These results are consistent with the microarray data.

View larger version (26K): [in this window] [in a new window]   FIG. 1. Effect of cold shock on the levels of mRNAs. Total RNA was extracted by the hot phenol method as described in the text, and Northern blot analysis was carried out with deoxyoligonucleotides corresponding to cspA, malT, dps, mopB, rbsD, and fecA. Lanes 1 and 2 in each case except fecA represent mRNAs isolated from control (37°C) and cold-shocked (1 h) wild-type cells, respectively. In the case of fecA, lanes 1 and 2 represent mRNAs isolated from cold-shocked (1 h) wild-type and quadruple-deletion cells, respectively. The positions of the transcripts were determined using as reference ribosomal RNAs. Bands corresponding to 23S and 16S rRNAs were visualized by ethidium bromide staining of the gel.

The genes affected by cold shock are grouped as those that (i) are transiently induced immediately following the cold shock in the acclimation phase (Table 1), (ii) show transient repression upon cold shock (Table 2), (iii) show prolonged induction beyond the acclimation phase (Table 3), and (iv) show prolonged repression upon cold shock.

As the cold shock response of the quadruple-deletion strain was severely affected, many genes repressed in the wild type upon cold shock were further repressed in the deletion strain. In addition to the genes listed in Table 1, the genes repressed in the quadruple-deletion strain included those involved in transport (ATP synthase, DctA protein, DsdX permease, fatty acid transport protein, maltoporin precursor, OmpF, OmpX, thiamine-binding protein precursor, and tryptophan permease) and a number of genes involved in cellular metabolism (especially amino acids and sugars).

On the other hand, a few genes were transiently induced in the quadruple-deletion strain compared with the wild-type strain, and these prominently constitute the genes encoding proteins involved in transport of iron, such as exbD, fecA to fecD, fepC, and fhuA and fhuF (Table 4). It is not clear why deletion of csp genes should result in induction of iron transport. It is noteworthy that these genes were repressed in the wild-type cells upon temperature downshift. In fact, judging from Table 4, a very divergent group of genes was induced by deletion of the four csp genes.

In addition, the products of a number of genes, such as ybdQ, ycfP, ydaA, ydhO, yeaA, yedU, yeeX, yefI, yfbU, yfiA, yfjL, yggG, ygjR, yhbT, yhjH, yieP, yqeB, yqhD, and yzzQ, increased significantly, although the products have not been assigned any functions. On the other hand, priB, yaeG, yafK, ybiR, ybiT, ycaJ, ycaO, yccA, yceD, yceP, ycfC, ycfV, ycfX, ycgE, ydgR, ydiU, yedA, yedl, yfcA, yfK, yfgL, yfgM, yfiH, yfiR, ygdE, yggN, yhaD, yhaE, yhaF, yhaU, yhbM, yheQ, yhiN, yjgP, yqgE, yqgF, and yrbE were repressed.

Genes showing prolonged induction and repression upon cold shock. Genes encoding flagellar proteins were induced and maintained at high levels even after 5 h at 15°C in the wild-type strain and were down-regulated in the quadruple-deletion strain. Spermidine acetyltransferase encoded by speG is required to prevent spermidine toxicity at low temperatures in E. coli (18). Our DNA microarray analysis showed a steady increase in speG levels from three- to fivefold at 1 to 5 h after temperature downshift (Table 3). On the other hand, genes such as tas (Tas protein), artP (ArtP protein), those mainly involved in amino acid and nucleotide biosynthesis, such as trpB, and leu, pur, and pyr operon genes were repressed even 5 h after cold shock. All of these showed further down-regulation in the quadruple-deletion strain.

Cold shock induction of genes encoding heat shock proteins. Protein misfolding was previously not considered a major problem upon cold shock. But increasing numbers of recent reports of a heat shock protein being induced by cold shock even in higher systems suggest that proper folding of proteins as well as refolding of cold-damaged proteins is important after cold shock. However, in most of these cases the heat shock induction of proteins is after prolonged incubation at low temperature (10, 28). On the other hand, in the present study, a number of genes encoding heat shock-inducible proteins and molecular chaperones such as htpG, mopA, mopB, and ppiA (encoding HtpG, GroEL, GroES, and peptidyl-prolyl-cis-trans-isomerase, respectively) showed transient induction immediately following cold shock. ClpB, which is both heat and cold shock-inducible in Synechococcus sp. strain PCC 7942 (28) was induced 10-fold and maintained at this level even at 5 h after temperature downshift (Table 3). ppiA, encoding peptidyl-prolyl-cis-trans-isomerase, is also reported from Bacillus, is involved in accelerating proline-limited steps in protein folding, and is important in helping protein folding at low temperatures (7, 8). Trigger factor encoded by tig is another interesting chaperone, which is moderately induced 2 to 3 h after cold shock (15). It is not included in Table 1, as it does not fulfill the criteria of the required n-fold increase; however, we did find moderate (1.7-fold) induction of this gene. Previously, it was also shown that when E. coli is grown at 16°C, GroEL expression is reduced (15); however, in that study the cells were grown to an OD₆₀₀ of 0.5, and then the protein expression was checked by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. In the present study, the immediate effect of cold shock is being analyzed (1 h). Both mopA and mopB were induced 9.3- and 8-fold after 1 h and then reduced to a basal level of 1.3- and 0.9-fold, respectively, after 5 h. Thus, our data are consistent with the low level of GroEL observed by these authors after cells reached the OD₆₀₀ of 0.5 at 16°C. Note that the OD₆₀₀ increased by 0.4 at 5 h after cold shock in the present study. This suggests that the GroELS system is transiently induced immediately after the temperature downshift, along with the induction of CspA homologues, and is then reduced to a basal level. It should be mentioned that GroEL is induced in E. coli at 37°C by the overexpression of CspC and CspE, although this induction is lesser than its heat shock induction (22). On the same note, the present study showed that deletion of four CspA homologues leads to repression of cold shock induction of mopA and mopB (Table 1). This suggests a possibility that cold shock induction of GroEL may be linked to the higher levels of CspA homologues.

Comparison of cold shock response of E. coli and B. subtilis. DNA microarray analysis of the cold shock response of B. subtilis has been carried out by two groups (2, 13). Our study showed that there are a number of common genes such as leuBCD (amino acid biosynthesis) and purBCDEFHKLMN (purine biosynthesis) that are affected by cold shock in E. coli and Bacillus spp. Other such examples include topA (DNA topoisomerase I), gltB, arg, and aro genes (amino acid biosynthesis) (Table 2). There are certain genes that are not included in the tables, as their ratios do not fulfill the criteria of the required n-fold difference; however, these are worth mentioning as they are affected by cold shock in Bacillus spp. The genes and the respective n-fold differences are as follows: (i) amino acid biosynthesis, aroF and aroH (0.5 and 0.6, respectively), metC (0.7), and serC (0.6); (ii) tRNA synthetases, aspS (0.6), hisS (0.5), and thrS (0.75); (iii) NAD biosynthesis, nifS (0.7) and nadC (0.7); (iv) ATP synthase, atpA, atpB, atpE, atpF, atpH, and atpI (approximately 0.5); (vi) pyrimidine biosynthesis, pyrC (0.75); (vii) citric acid cycle, sdhC (0.8); and (viii) metabolism, bioA and bioD (0.5 to 0.6) and ptb (2). However, there were also differences between E. coli and Bacillus cold shock response. For example, in the case of Bacillus spp., the ribosomal proteins were induced by cold shock, while in E. coli, these were either repressed or showed no significant change. One of these two analyses in Bacillus showed repression of GroEL 70 min after cold shock (2), while the present study shows induction of the GroELS system in E. coli 1 h after cold shock. This suggests that in spite of common basic principles in the cold shock response of E. coli and Bacillus spp., there are certain distinct differences.

CspA homologues are needed at acclimation phase. At low temperature, the secondary structures of RNA stabilize, which should slow down (i) transcription elongation and (ii) ribosomal movement on RNA and thus translation. The Csps are transiently and dramatically induced in the acclimation phase upon cold shock. These presumably act as RNA chaperones (1, 9, 11, 23, 25) by destabilizing the secondary structures in RNA and thus facilitating transcription and translation. Increased levels of CspA homologues after cold shock may be important for compensating for higher stability of secondary structures in RNA at low temperatures (11). The RNA chaperone effect of CspA homologues is apparent in the present microarray analysis, as cold shock induction of a number of diverse genes was repressed by deletion of four csp genes. These may be the genes that need help to transcribe and translate efficiently at low temperature, possibly due to stabilization of secondary structures in their mRNAs, and the high level of Csps ensures their effective production. It is noteworthy that, except for the flagellar operon, deletion of four csp genes mainly affected genes that are transiently induced during acclimation phase. This emphasizes the need for the RNA chaperones immediately upon cold shock, and once the cells are acclimated to cold, their presence is no longer required. This is supported by the observations that cold shock induction of Csps is transient and the quadruple-deletion strain shows a prolonged lag period after cold shock. Further studies on the effect of Csps on the transcription and translation of genes, especially those encoding GroELS, maltose, the ribose operon, and flagellar proteins, should prove to be useful in this aspect.

	ACKNOWLEDGMENTS

 
This work was supported by a grant from the National Institutes of Health (GM 19043) to M.I.

We thank Takara Bio Inc. Japan for DNA array chips and help in analysis of the array scans. We also thank Anirvan Sengupta and Ruadhan O'Flanagan for their help in statistical analysis of the data and K. V. Chin for his useful suggestions in the scanning of the DNA arrays.

	FOOTNOTES

 
* Corresponding author. Mailing address: Department of Biochemistry, Robert Wood Johnson Medical School, 675 Hoes Ln., Piscataway, NJ 08854. Phone: (732) 235-4116. Fax: (732) 235-4559. E-mail: phadtasa{at}umdnj.edu.

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