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Plasmid Curing is a Promising Approach to Improve Thermophiles for Biotechnological Applications: Perspectives in Archaea

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Tatsuki Mizuno, Takashi Ohshiro and Hirokazu Suzuki

Submitted: 04 November 2016 Reviewed: 07 June 2017 Published: 11 October 2017

DOI: 10.5772/intechopen.70041

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Archaea New Biocatalysts, Novel Pharmaceuticals and V... Edited by Haitham Sghaier

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Archaea - New Biocatalysts, Novel Pharmaceuticals and Various Biotechnological Applications

Edited by Haitham Sghaier, Afef Najjari and Kais Ghedira

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Abstract

Thermophiles are attractive as host cells for microbial processes to produce or degrade various compounds. In these applications, it is often desirable to improve the properties of thermophiles, such as their growth rate, cell density, and protein productivity, although this is rarely achieved because of the lack of general approaches. In this chapter, we describe the elimination of the pHTA426 plasmid from a moderate thermophile, Geobacillus kaustophilus HTA426, and its effects on the microbial properties. This process, called plasmid curing, was simply achieved using a DNA intercalator and confirmed by phenotypic and genotypic analyses. Of note, pHTA426 curing had beneficial effects on diverse properties, probably because of the reduced energy burden in terms of plasmid replication at high temperatures. The result suggests that plasmid curing is a simple and versatile approach for improving thermophiles. In particular, this approach may be effective for archaeal thermophiles because they grow at much higher temperatures and could have the greater energy burden on plasmid replication. Data mining has also shown that plasmids are distributed in archaeal thermophiles. This chapter provides a new tip for improving archaeal thermophiles, thereby increasing the opportunities for their use in various biotechnological applications.

Keywords

  • genetic engineering
  • host improvement
  • plasmid curing
  • plasmid elimination
  • thermophile application

1. Introduction

Thermophiles are organisms that are capable of growing at temperatures above 55°C. Archaeal thermophiles generally grow at much higher temperatures and thus comprise most extreme thermophiles and hyperthermophiles. These thermophiles are attractive organisms in biotechnological applications because they produce thermostable enzymes, which can be used as stable industrial catalysts even at high temperatures. Thermophile cells themselves are attractive as hosts for microbial processes at high temperatures.

High-temperature processes have several advantages compared with moderate processes using mesophiles, where an important advantage is that high temperature prevents the growth of animal pathogens, including all viruses, which are killed or at least prevented from proliferating at temperatures above 65°C [1]. High temperature also inhibits growth and/or metabolism by mesophiles, which may hinder processes of interests via involuntary reactions. The advantage is especially important for processes using crude biomass (e.g., sewage, municipal or agricultural waste, and materials from animal farms) because mesophiles and virulent pathogens are common in biomass from natural environments and they may increase during reactions performed under moderate conditions. In addition, high temperature facilitates the removal of volatile products (e.g., ethanol and butanol) while decreasing oxygen solubility; therefore, thermophiles are practical for fermentative production of alcohols [26]. Moreover, thermophiles often have remarkable properties useful for bioprocesses. A good example is the hyperthermophilic archaeon Thermococcus kodakarensis KOD1, which can use protons as an electron accepter in catabolism to generate molecular hydrogen and has been studied as a hydrogen production tool [7].

In this chapter, we will demonstrate the salutary effects of plasmid curing on thermophiles using as an example a prokaryotic thermophile that was isolated from deep sea sediments of the Mariana Trench, Geobacillus kaustophilus HTA426 [8, 9]. Its growth occurs at temperatures ranging between 42 and 74°C, with optimal growth at 60°C, and is as rapid as Escherichia coli and Bacillus subtilis. Genetic tools are available for this strain [1016]. The whole genome sequence has been determined [17], showing that G. kaustophilus HTA426 harbors the circular plasmid pHTA426 (Figure 1). Because the members of the genus Geobacillus include strains that are useful for high-temperature processes, as demonstrated by strains that are capable of degrading hydrocarbons [18], long-chain alkanes [1921], biphenyls [22], paraffin-wax [23], or nylons [24], we have studied biotechnological applications of the genus using G. kaustophilus HTA426 as a model and pilot strain.

Figure 1.

Structure of pHTA426. Genes for possible and hypothetical proteins are indicated by solid and faded arrows, respectively. The plasmid contains possible genes responsible for plasmid replication (gkp02 and gkp36), DNA restriction–modification (gkp08 and gkp09), and integrase/transposase (gkp12 and gkp13).

Aiming to construct a plasmid-free strain that may be useful for the genetic analysis of pHTA426, this study was originally designed to eliminate this plasmid from an HTA426 derivative, G. kaustophilus MK244. The resultant strain MK633 was then characterized to confirm that plasmid elimination (termed plasmid curing) had no effects on its microbial properties, but the analysis unexpectedly demonstrated that G. kaustophilus MK633 had advantages compared with the parent strain MK244 in terms of several properties. We suggest here that plasmid curing is a promising approach for improving diverse thermophiles.

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2. Experimental procedures

2.1. Bacterial strains and culture conditions

The bacterial strains employed are summarized in Table 1. G. kaustophilus MK244 was previously constructed from G. kaustophilus HTA426 [14]. If not specified otherwise, G. kaustophilus strains were grown at 60°C in Luria–Bertani (LB) and minimal media (MM) with rotary shaking at 180 rpm. MM comprised 0.3 g l−1 K2SO4, 2.5 g l−1 Na2HPO4⋅12H2O, 1 g l−1 NH4Cl, 0.4 g l−l MgSO4, 3 mg l−1 MnCl2⋅4H2O, 5 mg l−1 CaCl2⋅2H2O, 7 mg l−1 FeCl3⋅6H2O, 0.1% trace element solution [25], 10 mM Tris-HCl (pH 7.0), 1 g l−1 casamino acids, and 10 g l−1 D-glucose. The media also contained 5 mg l−1 kanamycin, 10 mg l−1 uracil, 50 mg l−1 5-fluoroorotic acid, 1 g l−1 yeast extract, and/or 50 mg l−1 5-bromo-4-chloro-3-indolyl-β-D-galactopyranoside (X-gal), as necessary. E. coli strains were grown at 37°C in LB medium supplemented with appropriate antibiotics (50 mg l−1 ampicillin, 50 mg l−1 kanamycin, 13 mg l−1 chloramphenicol, and/or 7 mg l−1 tetracycline). The optical cell density at 600 nm was monitored automatically using an OD-MonitorA instrument (Taitec, Saitama, Japan).

StrainRelevant descriptionReference
E. coli
BR397Conjugation helper strain; F e14 (mcrA) Δ(mrr-hsdRMS-mcrBC)114::IS10 Δdcm::lacZ Δdam::metB pUB307 pIR207[18]
BR398Conjugation helper strain; F e14 (mcrA) Δ(mrr-hsdRMS-mcrBC)114::IS10 Δdcm::lacZ pUB307 pIR207[18]
BR408Conjugation helper strain; F e14 (mcrA) Δ(mrr-hsdRMS-mcrBC)114::IS10 Δdcm::lacZ pUB307 pIR408[18]
G. kaustophilus
MK244Derivative of the wild-type strain HTA426; ΔpyrF ΔpyrR ΔhsdM1S1R1 Δ(mcrB1-mcrB2-hsdM2S2R2-mrr) pHTA426[20]
MK244′Derivative of the MK244 strain; ΔpyrF ΔpyrR ΔhsdM1S1R1 Δ(mcrB1-mcrB2-hsdM2S2R2-mrr) pHTA426 (Δgkp09::PsigA-bgaB)This study
MK244bgaBDerivative of the MK244 strain; ΔpyrF ΔpyrR ΔhsdM1S1R1 Δ(mcrB1-mcrB2-hsdM2S2R2-mrr) gk0707::Pgk704-bgaB pHTA426This study
MK633Derivative of the MK244 strain; ΔpyrF ΔpyrR ΔhsdM1S1R1 Δ(mcrB1-mcrB2-hsdM2S2R2-mrr)This study
MK633bgaBDerivative of the MK633 strain; ΔpyrF ΔpyrR ΔhsdM1S1R1 Δ(mcrB1-mcrB2-hsdM2S2R2-mrr) gk0707::Pgk704-bgaBThis study

Table 1.

Bacterial strains used in this study. pUB307 mediates the conjugative transfer of oriT-containing plasmids. This plasmid contains kanamycin and tetracycline resistance genes. pIR207 is a chloramphenicol resistance plasmid derived from pACYCDuet-1 (Merck KgaA, Darmstadt, Germany). The plasmid was used to construct pIR408, which contains the hsdM1S1 and hsdM2S2 genes from G. kaustophilus HTA426, and thus, it is responsible for heterologous DNA methylation in E. coli [18]. G. kaustophilus MK244 lacks genes related to pyrimidine biosynthesis (pyrF and pyrR) and DNA restriction–modification (hsdM1S1R1, mcrB1, mcrB2, hsdM2S2R2, and mrr). PsigA-bgaB and Pgk704-bgaB denote bgaB expression cassettes under the control of PsigA [19] and Pgk704 promoters [21], respectively.

2.2. Plasmids

The E. coli-Geobacillus shuttle plasmids are summarized in Table 2. To construct the pGKE25-bgaB plasmid, a gkp09 downstream region of pHTA426 was amplified using the primers 5′-GGAGTTTGCCAAACTCCGGATCCAGCTTGGATTTATC-3′ (BamHI site underlined) and 5′-CACAAGCTTGGGGCTGGATGTAATG-3′ (HindIII site underlined), and a gkp09 upstream region was amplified using the primers 5′-GGCGGATCCTTCCGATTAGGTTCCCATGC-3′ (BamHI site underlined) and 5′-GGCGAATTCGGCCTTTTCGCATTAC-3′ (EcoRI site underlined). In addition, a bgaB expression cassette encoding thermostable β-galactosidase under the control of PsigA promoter was amplified from the pGAM47-bgaB plasmid [13] using the primers 5′-AAGATCTCTTCGCCTCATCCGCACGATTTC-3′ and 5′-GCCAGATCTCTAAACCTTCCCGGCTTCATC-3′ (BglII site underlined). The downstream region was cloned between the BamHI and HindIII sites of the pGKE25 plasmid [14], and the upstream region was cloned between the BamHI and EcoRI sites. The bgaB expression cassette was then cloned in the BamHI site of the resulting plasmid to yield pGKE25-bgaB for replacing the gkp09 gene in pHTA426 with the bgaB cassette. The pGAM48-bgaB plasmid [15] was used to integrate a bgaB expression cassette under the control of the Pgk704 promoter at the gk0707 locus in the G. kaustophilus chromosome. The pUCG18T plasmid [12] was used to assess the transformation efficiency of G. kaustophilus.

PlasmidRelevant descriptionReference
pGAM47-bgaBpUC19 derivative; pUC replicon, oriT, bla, pyrF, PsigA-bgaB flanked by gk0707 upstream and downstream regions[19]
pGAM48-bgaBpUC19 derivative; pUC replicon, oriT, bla, pyrF, Pgk704-bgaB flanked by gk0707 upstream and downstream regions[21]
pGKE25pUC19 derivative; pUC replicon, oriT, bla, pyrF[20]
pGKE25-bgaBpGKE25 derivative; pUC replicon, oriT, bla, pyrF, PsigA-bgaB flanked by gkp09 upstream and downstream regionsThis study
pUCG18TpUC18 derivative; pUC and pBST1 replicons, oriT, bla, TK101[18]

Table 2.

E. coli-Geobacillus shuttle plasmids used in this study. bla and TK101 genes confer resistance to ampicillin in E. coli and kanamycin in G. kaustophilus, respectively. pyrF encodes orotidine-5′-phosphate decarboxylase in G. kaustophilus HTA426. oriT is the conjugative transfer origin. PsigA-bgaB and Pgk704-bgaB denote bgaB expression cassettes under the control of PsigA [19] and Pgk704 promoters [21], respectively. The pUC and pBST1 replicons allow autonomous plasmid replication in E. coli and G. kaustophilus, respectively.

2.3. Plasmid introduction into G. kaustophilus

Plasmids were introduced into G. kaustophilus by conjugative plasmid transfer from E. coli BR408 [12]. Briefly, an E. coli donor (10 ml) and a G. kaustophilus recipient (100 ml) were grown in LB media. The cells were subsequently mixed, centrifuged, and spotted onto LB plates. After incubation at 37°C for 20 h, the resultant cells were collected and incubated at 60°C on appropriate media to isolate G. kaustophilus transformants. The transformation efficiency, as the number of transformants per 106 recipients, was determined as described previously [12]. Data were expressed as the mean ± standard error (n = 3).

2.4. pHTA426 curing from G. kaustophilus MK244

The gkp09 gene in pHTA426 was replaced by a bgaB expression cassette using pGKE25-bgaB with pyrF-based counterselection [13]. The resultant clone, strain MK244′, was successively cultured three times in LB media supplemented with 20 µM acridine orange to facilitate pHTA426 curing. In each culture, an aliquot (103 cells) was grown on LB plates supplemented with X-gal to identify candidates from which pHTA426 was eliminated along with the bgaB cassette. The candidates were purified using LB plates with X-gal.

2.5. Southern blot

Total DNA (25 µg) was digested using EcoRV and separated on an agarose gel by electrophoresis. DNA was transferred onto a nylon membrane and hybridized with digoxigenin-labeled DNA probes to detect the bgaB and gkp30 regions. Probes were synthesized using PCR DIG Probe Synthesis Kit (Roche, Basel, Switzerland) using the primers 5′-GCCGGATCCTGTTATCCTCAATTTGTTAC-3′ and 5′-GCCGGATCCTGTTATCCTCAATTTGTTAC-3′ (for bgaB probe) and 5′-CCGATATAGGCTGAGAACGC-3′ and 5′-CAGCTGGTAGACATGGGG-3′ (for gkp30 probe). Hybridized DNA was detected with the chromogenic method using DIG Nucleic Acid Detection Kit (Roche).

2.6. Construction of G. kaustophilus MK244bgaB and MK633bgaB

A bgaB expression cassette under the control of the Pgk704 promoter was integrated at the gk0707 locus in G. kaustophilus using pGAM48-bgaB, as described previously [15]. G. kaustophilusMK244 and MK633 were subjected to this process to generate strains MK244bgaB and MK633bgaB, respectively.

2.7. BgaB assay

G. kaustophilus MK244bgaB and MK633bgaB were cultured for 4 h in MM containing yeast extract but not D-glucose or casamino acids, and then for 20 h in the presence of 10 g l−1 maltose. Cells were subsequently harvested, sonicated in 50 mM sodium phosphate (pH 6.0), and clarified by centrifugation to obtain a lysate. The reaction mixture (100 µl) contained 50 mM sodium phosphate (pH 6.0), 2 mM p-nitrophenyl-β-D-galactopyranoside, and the lysate. The mixture was incubated at 60°C to react and then diluted with ice-cold 2 M sodium carbonate (900 µl) to terminate the reaction. p-Nitrophenol liberated in the mixture was quantified based on the absorbance at 405 nm and using an experimentally derived standard curve. One unit was defined as the amount of enzyme required to generate 1 µmol of p-nitrophenol per min. Proteins were quantified by the Bradford method using a protein assay kit (Nacalai Tesque, Kyoto, Japan). Data were expressed as the mean ± standard error (n = 4–5).

2.8. Plasmid stability assay

G. kaustophilus harboring pUCG18T was precultured in LB medium with kanamycin until the optical cell density at 600 nm reached 0.5. An aliquot (200 µl) was then cultured in LB medium (20 ml) without kanamycin until the stationary phase. The resultant cells were incubated on LB plates with or without kanamycin to determine the concentrations of kanamycin-resistant and viable cells, respectively. The plasmid retention rate was defined as the number of kanamycin-resistant cells per viable cells. Data were expressed as the mean ± standard error (n = 3).

2.9. Cell density assay

G. kaustophilus cells were cultured in LB medium until the stationary phase. Cells were harvested by centrifugation and analyzed to determine the wet weight. Data were expressed as the mean ± standard error (n = 4–5).

2.10. Mutation frequency assay

The frequency of spontaneous mutations was assessed based on the generation of rifampicin- and streptomycin-resistant cells via rpoB and rpsL genes, respectively [26]. G. kaustophilus (103 cells) was cultured at 60°C in LB medium until the stationary phase. The resultant cells were then incubated on LB plates with or without efficacious rifampicin or streptomycin (10 mg l−1) to determine the concentrations of mutant (rifampicin- or streptomycin-resistant) and viable cells, respectively. The colonies were counted to calculate the ratio of mutant cells relative to the viable cells incubated, which was defined as the mutation frequency. Data were expressed as the mean ± standard error (n = 3).

2.11. Nucleotide stability assay

Deoxyribonucleoside triphosphates (1 mM) were incubated for 24 h in 20 mM sodium phosphate (pH 7.0) at 30, 60, 80, and 90°C. The residual nucleotides in samples (5 µl) were analyzed using reversed-phase high-performance liquid chromatography. The chromatography system comprised solvent delivery units (LC-10AT; Shimadzu, Kyoto, Japan), an ultraviolet absorption detector (SPD-10Avp; Shimadzu), a reverse-phase column (Cosmosil 2.5C18-MS-II; Nacalai Tesque), and a column bath at 30°C. Solvents A and B comprised 5 mM tetrabutylammonium bromide in 20 mM sodium phosphate (pH 7.0) and 90% (v/v) acetonitrile in water, respectively. After injecting the sample into a column that had been equilibrated with 15% solvent B, the column was isocratically developed at a flow rate of 0.5 ml min−1 for 1 min and then at a linear gradient of 15–60% solvent B over 15 min. The chromatogram was obtained by detection at 260 nm.

2.12. Genome data mining

Genome data were collected from the GenBank database (https://www.ncbi.nlm.nih.gov/genome) in December 2016. The collection was performed for bacterial thermophiles (Geobacillus spp.), bacterial mesophiles (B. subtilis), archaeal thermophiles (Pyrobaculum, Pyrococcus, Sulfolobus, and Thermococcus spp.), archaeal mesophiles (Haloarcula, Halococcus, Haloferax, and Halorubrum spp.), and archaeal methanogens (Methanobacterium, Methanobrevibacter, Methanocaldococcus, Methanocella, Methanococcoides, Methanococcus, Methanocorpusculum, Methanoculleus, Methanofollis, Methanogenium, Methanohalophilus, Methanolacinia, Methanolinea, Methanolobus, Methanomassiliicoccus, Methanomethylovorans, Methanomicrobium, Methanoplanus, Methanoregula, Methanosaeta, Methanosalsum, Methanosarcina, Methanosphaerula, Methanothermobacter, Methanothermococcus, Methanothermus, Methanotorris, and Methermicoccus spp.). The growth temperatures of archaeal methanogens were based on the Methanogens database (http://metanogen.biotech.uni.wroc.pl). Genome sizes were expressed as the mean ± standard deviation.

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3. Results

3.1. Genetic features of the pHTA426 plasmid

The pHTA426 sequence suggested that the plasmid was a large circular plasmid (47.9 kb) comprising 1.3% of the circular chromosome of G. kaustophilus HTA426 (3.54 Mb) and that it encoded possible proteins for plasmid replication (gkp02) and plasmid partition (gkp36). A partition system has a role in the stable transmission of single-copy plasmids during cell division, so pHTA426 appeared to be present as a single copy in G. kaustophilus HTA426. In addition, the plasmid contained genes for a type II restriction–modification system, which was homologous to the AlwI restriction-modification system (gkp08 encoding methyltransferase and gkp09 encoding endonuclease). A type II restriction-modification system generally comprises an endonuclease and methyltransferase, where the endonuclease cuts exogenous DNA at specific sites, but not endogenous DNA that has been methylated by methyltransferase. In the AlwI system, AlwI methyltransferase is responsible for 5′-GG6mATC-3′ and 5′-G6mATCC-3′ methylation (6mA, N6-methyladenin), whereas AlwI endonuclease cuts 5′-GGATC-3′ and 5′-GATCC-3′ sites but not 5′-GG6mATC-3′ and 5′-G6mATCC-3′ sites. Because plasmids carrying a type II restriction-modification system have greater segregational stability [27], it is likely that the gkp08gkp09 system contributes to the stable maintenance of pHTA426.

3.2. Construction of G. kaustophilus MK633

Figure 2A shows the process employed to eliminate pHTA426 from G. kaustophilus MK244. To facilitate plasmid curing and readily identify positive clones from which pHTA426 was eliminated, the gkp09 gene was preliminarily replaced by a bgaB expression cassette using pGKE25-bgaB. The resultant strain MK244′ was then cultured successively in the presence of a DNA intercalator, and we screened for positive clones by using the X-gal degradation assay. Fortunately, one positive clone was obtained from the first culture but not from the second culture. From the third culture, 24 positive clones were identified, which suggests that three successive rounds of culture were effective for pHTA426 curing. The positive clone obtained from the first culture was designated as G. kaustophilus MK633.

Figure 2.

Construction of G. kaustophilus MK633. (A) Schematic representation of pHTA426 curing from G. kaustophilus MK244. The gkp09 gene in pHTA426 was replicated by the bgaB expression cassette (PsigA-bgaB) to generate strain MK244′. The plasmid pHTA426 (Δgkp09::PsigA-bgaB) in strain MK244′ was subsequently eliminated using acridine orange. The positive clones from which pHTA426 was eliminated, including strain MK633, were identified using the X-gal degradation assay. (B) X-gal degradation assay. G. kaustophilus strains MK244 (1), MK244′ (2), and MK633 (3) were grown at 60°C on LB plates with (+) or without (−) X-gal. (C) DNA methylation assay of MK244, MK244′, and MK633 chromosomes. Total DNA from the strains was digested with restriction enzymes (1, none; 2, DpnI; 3, AlwI) and analyzed by agarose gel electrophoresis. (D) Southern blot analysis of pHTA426. Total DNA from strains MK244 (1), MK244′ (2), and MK633 (3) was digested with EcoRV, and detected by bgaB (left panel) and gkp30 probes (right panel).

G. kaustophilus MK244′ degraded X-gal to form blue colonies on LB plates with X-gal, whereas strains MK244 and MK633 did not (Figure 2B). This suggests that strain MK633 lacked the bgaB gene. The MK633 chromosome is resistant to DpnI (which digests 5′-G6mATC-3′ but not 5′-GATC-3′)but sensitive to AlwI (see above), in contrast to the chromosomes from strains MK244 and MK244′ (Figure 2C), so it is likely that strain MK633 lacked the gkp08 gene encoding an AlwI methyltransferase homolog. Southern blot analysis (Figure 2D) confirmed that strain MK633 lacked the bgaB and gkp30 genes, which are located on opposite sides of pHTA426 (Δgkp09::PsigA-bgaB). Based on these results, we concluded that G. kaustophilus MK633 lacked pHTA426.

3.3. Microbial properties of G. kaustophilus MK244 and MK633

G. kaustophilus MK244 and MK633 were characterized in detail (Table 3). Both strains grew in LB and MM with comparable doubling times. The difference in their mutation frequencies was also not significant. However, strain MK633 was more transformed efficiently with pUCG18T than strain MK244 and it maintained the plasmid with higher stability. Moreover, strain MK633 grew at higher cell densities than strain MK244. The cell density of G. kaustophilus MK244′ was lower than that of strain MK633 at 60°C (0.30 ± 0.03 g wet), but the pUCG18T retention rate was comparable (43 ± 14%).

MK244MK633
Transformation efficiency (per 106recipients)
E. coli BR397 donor<1300 ± 75
E. coli BR398 donor55 ± 1722 ± 3
E. coli BR408 donor87 ± 1434 ± 14
Mutation frequency (per 106cells)
Rifampicin resistance12 ± 242 ± 8
Streptomycin resistance7 ± 47 ± 2
Doubling time in LB medium (min)
50°C47 ± 642 ± 2
60°C23 ± 221 ± 3
70°C38 ± 732 ± 5
Doubling time in MM medium (min)
50°C100 ± 9130 ± 20
60°C83 ± 689 ± 2
70°CNDND
pUCG18T retention rate (%)
50°C6 ± 358 ± 7
60°C6 ± 479 ± 9
70°C1 ± 164 ± 2
Cell yield (g wet weight per 20 ml culture)
50°C0.41 ± 0.010.41 ± 0.01
60°C0.30 ± 0.030.36 ± 0.01
70°C0.38 ± 0.030.41 ± 0.01

Table 3.

Microbial properties of G. kaustophilus MK244 and MK633. Analyses were repeated more than three times. Data represent the mean ± standard error. ND, growth was not observed within 2 days.

When cultured at 60°C, strain MK633bgaB produced 220 ± 20 units of BgaB, whereas strain MK244bgaB produced 140 ± 10 units (Figure 3A). BgaB was also produced more abundantly by MK633bgaB at 50 and 70°C. Moreover, G. kaustophilus MK633bgaB had advantages in terms of the cell yield per culture (Figure 3B), protein yield per culture (Figure 3C), and BgaB-specific activity (Figure 3D). The higher specific activity suggests that MK633bgaB enhanced the BgaB productivity per cell.

Figure 3.

BgaB production by G. kaustophilus MK244bgaB and MK633bgaB. These strains were cultured at 50, 60, and 70°C in medium (100 ml) and analyzed to determine the total activity in terms of intracellular BgaB (A), cell weight (B), intracellular total protein (C), and BgaB-specific activity (D). Data are expressed as the mean ± standard error (n = 4–5).

3.4. Nucleotide stability

In bacteria and Archaea, DNA replication proceeds in cytosol (approximately at pH 7) using deoxyribonucleoside triphosphates as the building blocks. To assess their thermolability in cytosol, deoxyribonucleoside triphosphates (i.e., dATP, dCTP, dGTP, and dTTP) were treated at high temperatures and analyzed to determine residual amounts relative to those after incubation at 30°C. Most nucleotides were instable at 60°C (residual ratio: dATP, 68%; dCTP, 70%; dGTP, 71%; and dTTP, >99%). All of the nucleotides were clearly degraded into other forms when incubated at 80°C (dATP, 10%; dCTP, 26%; dGTP, 12%; and dTTP, 15%) and were completely degraded at 90°C (residual ratio, <0.2%). This suggests that the deoxyribonucleoside triphosphates are physicochemically unstable in the thermophiles.

3.5. Archaeal thermophiles: Smaller genomes

Genomic data were analyzed to compare the genome sizes of thermophiles (capable of growing at > 55°C) and mesophiles (capable of growing at 20–55°C). The genomes of thermophilic bacteria Geobacillus spp. (3.4 ± 0.3 Mb; n = 57) were smaller than those of phylogenetically related mesophiles, e.g., B. subtilis (4.1 ± 0.3 Mb; n = 100). The results were similar for archaeal methanogens, in which thermophiles had smaller genomes (1.7 ± 0.6 Mb; n = 20) than mesophiles (2.6 ± 0.8 Mb; n = 57). Archaeal thermophiles, such as Pyrobaculum (2.2 ± 1.6 Mb; n = 4), Pyrococcus (1.8 ± 0.1 Mb; n = 5), Sulfolobus (2.5 ± 0.2 Mb; n = 5), and Thermococcus (2.0 ± 0.1 Mb; n = 18) members, have much smaller genomes compared with archaeal mesophiles, such as Haloarcula (3.6 ± 1.2 Mb; n = 9), Halococcus (3.6 ± 0.4 Mb; n = 7), Haloferax (3.7 ± 0.4 Mb; n = 6), and Halorubrum (3.1 ± 0.8 Mb; n = 13) members. These data suggest that the thermophiles, especially archaeal thermophiles, tend to have smaller genomes than mesophiles.

3.6. Distribution of plasmids in archaeal thermophiles

Data mining showed that many thermophiles harbored plasmids, although not the majority. In Archaea, plasmids were identified frequently in Sulfolobus spp. (14 strains) and Thermococcus spp. (11 strains): pARN3 (26.2 kb), pARN4 (26.5 kb), pHEN7 (7.8 kb), pHVE14 (35.4 kb), pING1 (24.6 kb), pKEF9 (28.9 kb), pLD8501 (26.6 kb), pRN1 (5.4 kb), pRN2 (7.0 kb), pSOG1 (29.0 kb), pSOG2 (26.0 kb), pSSVx (5.7 kb), pXZ1 (7.0 kb), and pYN01 (42.2 kb) in Sulfolobus islandicus; pIT3 (5.0 kb), pMGB1 (28.0 kb), and pSSVi (5.7 kb) in Sulfolobus solfataricus; pTBMP1 (54.2 kb) in Thermococcus barophilus; an unnamed plasmid (3.6 kb) in Thermococcus eurythermalis; pTN1 (3.6 kb), pTN2 (13.0 kb), and pTN3 (18.3 kb) in Thermococcus nautili; an unnamed plasmid (49.1 kb) in Thermococcus peptonophilus; and pAMT7 (8.6 kb), pAMT11 (20.5 kb), pCIR10 (13.3 kb), pEXT9a (10.6 kb), pIRI33 (11.0 kb), pIRI48 (13.0 kb), and pT26-2 (21.6 kb) in Thermococcus spp. The other plasmids identified in archaeal thermophiles are as follows: pDSM2661_1 (58.4 kb) and pDSM2661_2 (16.6 kb) in Methanocaldococcus jannaschii; pMTBMA4 (4.4 kb) in Methanothermobacter marburgensis; pFV1 (13.5 kb), pFZ1 (11.0 kb), pME2001 (4.4 kb), and pME2200 (6.2 kb) in Methanothermobacter thermautotrophicus; pMETOK01 (14.9 kb) in Methanothermococcus okinawensis; pGT5 (3.4 kb) in Pyrococcus abyssi; and pTA1 (15.7 kb) in Thermoplasma acidophilum. In addition, several cryptic plasmids have been identified in archaeal thermophiles [28].

Plasmids are also distributed in bacterial thermophiles. In Geobacillus spp., seven strains of Geobacillus spp. harbored plasmids: pGS18 (plasmid length, 62.8 kb), pSTK1 (1.9 kb), pTB19 (11.9 kb), and an unnamed plasmid (21.7 kb) in Geobacillus stearothermophilus; pLW1071 (57.7 kb) in Geobacillus thermodenitrificans; pLDW-1 (48.7 kb) in Geobacillus thermoleovorans; and pBt40 (39.7 kb) in Geobacillus sp. In Thermus spp., 12 strains were identified as plasmid carriers. Their plasmids include pTA14 (14.4 kb), pTA16 (16.6 kb), pTA69 (69.9 kb), and pTA78 (78.7 kb) in Thermus aquaticus; pTB1 (342.8 kb) and pTB2 (10.3 kb) in Thermus brockianus; pTHEOS01 (271.7 kb) and pTHEOS02 (57.2 kb) in Thermus oshimai; pTP143 (143.3 kb) in Thermus parvatiensis; pTSC8 (8.4 kb) in Thermus scotoductus; and pTF62 (10.4 kb), pTHTHE1601 (440.0 kb), pTT8 (9.3 kb), pTT27 (232.6 kb), pTTJL1801 (265.9 kb), pTTJL1802 (142.7 kb), and pVV8 (81.2 kb) in Thermus thermophilus. In Parageobacillus thermoglucosidans, pGEOTH01 (80.8 kb), pGEOTH02 (19.6 kb), pNCI001 (83.9 kb), and pNCI002 (47.9 kb) were identified.

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4. Discussion

In this study, we analyzed the effects of plasmid curing on thermophiles by characterizing G. kaustophilus MK244 and MK633 (Table 3 and Figure 3). Both strains exhibited comparable growth at 50–70°C in LB and MM; therefore, pHTA426 had no positive effects on cell growth under standard conditions. The mutation frequencies were largely comparable between strains MK244 and MK633, although G. kaustophilus MK633 lacked the gkp08 gene responsible for dam-like methylation (5′-GG6mATC-3′and 5′-G6mATCC-3′) and the dam methylation (5′-G6mATC-3′) is essential for DNA mismatch repair in E. coli [29]. In B. subtilis 168, DNA mismatch repair only involves mutS and mutL products, which do not depend on DNA methylation [30, 31], thereby suggesting that G. kaustophilus may use a mismatch repair system similar to the B. subtilis system rather than the E. coli system. In fact, the G. kaustophilus genome [17] contains mutS and mutL but not mutH, as found in B. subtilis 168.

A restriction-modification system generally protects the host microbe from transformation with exogenous DNA because the system cuts exogenous DNA that is not methylated by methyltransferase. However, a microbe can accept exogenous DNA that imitates the methylation pattern because a restriction-modification system is unable to cut this exogenous DNA [32]. In a previous study [12], we constructed E. coli strains BR397, BR398, and BR408 for conjugative plasmid transfer into G. kaustophilus HTA426. E. coli BR408 produces DNA that imitates the methylation pattern in G. kaustophilus HTA426. E. coli BR398 produces DNA with dam methylation, whereas E. coli BR397 produces methyl-free DNA. Although G. kaustophilus MK244 could not accept the pUCG18T plasmid transferred from the dam strain E. coli BR397, G. kaustophilus MK633 accepted pUCG18T from E. coli BR397 as well as strains BR398 and BR408. These results can be explained by the elimination of gkp09 from strain MK633 because the gkp09 product digests methyl-free DNA but not DNA with dam methylation (5′-G6mATC-3′, which covers gkp08 methylation (5′-GG6mATC-3′ and 5′-G6mATCC-3′. In addition, G. kaustophilus MK633 maintained pUCG18T with higher stability than strain MK244. This observation is also attributable to the elimination of gkp09 because the gkp09 product can occasionally digest endogenous plasmids that have not undergone gkp08 methylation immediately after plasmid replication. This hypothesis is supported by the fact that G. kaustophilus MK244′ maintained pUCG18T as stably as strain MK633. Thus, G. kaustophilus MK633 acquired advantages compared with strain MK244 in terms of plasmid transformation and plasmid stability due to the elimination of a restriction-modification system along with pHTA426 curing.

An intriguing observation was that G. kaustophilus MK633 had a higher cell density in the stationary phase. In contrast to the advantages in terms of plasmid transformation and plasmid stability, this observation cannot be explained by the elimination of gkp09 because G. kaustophilus MK244′ grew less efficiently than strain MK633. It was also interesting that strain MK633bgaB produced higher amounts of BgaB than MK244bgaB (Figure 3A). This observation is attributable mainly to the higher cell density of MK633bgaB (Figure 3B), as observed with strain MK633, and thus the higher protein yields from strain MK633bgaB (Figure 3C). In addition, this observation can be attributed to the higher BgaB productivity per cell because strain MK633bgaB had a higher BgaB specific activity (Figure 3D). Thus, these results suggest that the elimination of pHTA426 improved the cell density per culture and BgaB productivity per cell, thereby remarkably enhancing the production of BgaB.

Sodium dodecyl sulfate-polyacrylamide gel electrophoresis analysis showed that the crude extracts from G. kaustophilus MK244 and MK633 had negligible differences in terms of their protein compositions (data not shown). Therefore, it is unlikely that G. kaustophilus MK633 lost a nonessential protein that was abundantly synthesized from pHTA426, thereby reducing the energy burden to enhance the cell yield and BgaB productivity. Instead, these enhancements may be attributable to the reduced energy burden for plasmid replication. In fact, evidence suggests that plasmid maintenance places burdens on cell growth and/or metabolism [3336]. Given that pHTA426 replicates as a single copy, this plasmid accounts for only 1.3% of total DNA; however, deoxyribonucleoside triphosphates are more unstable at higher temperatures, thereby suggesting that plasmid replication may place a considerable energy burden on thermophiles even though the plasmid is not extremely large or present in high copy numbers. This hypothesis is consistent with our genome data analysis, which showed that thermophiles have relatively smaller genomes than mesophiles, and the negative correlation between genome size and growth temperature reported by Sabath et al [37]. Overall, we consider that the lower energy burden incurred for DNA replication can explain why pHTA426 curing improved the cell density per culture and BgaB productivity per cell.

In conclusion, we demonstrated that pHTA426 curing was effective for improving the performance of a moderate thermophile, G. kaustophilus MK244. The cell density and protein productivity were presumably improved by the reduced amounts of energy required for DNA replication at high temperatures, so plasmid curing may be a simple approach for improving thermophiles in terms of these properties. In particular, this approach may be effective for archaeal thermophiles because they grow at extremely high temperatures and thus could have a greater energy burden on plasmid replication. Moreover, in archaeal thermophiles, plasmids may account for larger fractions of chromosomes than in moderate thermophiles because archaeal thermophile genomes are generally smaller. Therefore, plasmid curing could remarkably reduce the energy burden in archaeal thermophiles. We note that many archaeal thermophiles harbor plasmids, such as S. solfataricus P2 (carrying pSSVi) and T. barophilus MP (carrying pTBMP1), which have been studied as model acidophilic hyperthermophiles [38] and piezophilic hyperthermophiles [39], respectively. Even if these thermophiles harbor a single copy plasmid, our results suggest that plasmid curing can improve their performance in terms of the cell density and protein productivity.

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Acknowledgments

The authors thank Dr. Hisashi Yagi of Tottori University for useful discussions. This study was supported by JSPS KAKENHI (Grant number 25450105).

References

  1. 1. Wiegel J, Ljungdahl LG. The importance of thermophilic bacteria in biotechnology. Critical Reviews in Biotechnology. 1986;3:39-108
  2. 2. Cripps RE, Eley K, Leak DJ, Rudd B, Taylor M, Todd M, Boakes S, Martin S, Atkinson T. Metabolic engineering of Geobacillus thermoglucosidasius for high yield ethanol production. Metabolic Engineering. 2009;11:398-408
  3. 3. Georgieva TI, Ahring BK. Evaluation of continuous ethanol fermentation of dilute-acid corn stover hydrolysate using thermophilic anaerobic bacterium Thermoanaerobacter BG1L1. Applied Microbiology and Biotechnology. 2007;77:61-68
  4. 4. Lin PP, Rabe KS, Takasumi JL, Kadisch M, Arnold FH, Liao JC. Isobutanol production at elevated temperatures in thermophilic Geobacillus thermoglucosidasius. Metabolic Engineering. 2014;24:1-8
  5. 5. Shaw AJ, Podkaminer KK, Desai SG, Bardsley JS, Rogers SR, Thorne PG, Hogsett DA, Lynd LR. Metabolic engineering of a thermophilic bacterium to produce ethanol at high yield. Proceedings of the National Academy of Sciences of the United States of America. 2008;105:13769-13774
  6. 6. Taylor MP, Eley KL, Martin S, Tuffin MI, Burton SG, Cowan DA. Thermophilic ethanologenesis: Future prospects for second-generation bioethanol production. Trends in Biotechnology. 2009;27:398-405
  7. 7. Kanai T, Simons J-R, Tsukamoto R, Nakajima A, Omori Y, Matsuoka R, Beppu H, Imanaka T, Atomi H. Overproduction of the membrane-bound [NiFe]-hydrogenase in Thermococcus kodakarensis and its effect on hydrogen production. Frontiers in Microbiology. 2015;6:847
  8. 8. Takami H, Inoue A, Fuji F, Horikoshi K. Microbial flora in the deepest sea mud of the Mariana Trench. FEMS Microbiology Letters. 1997;152:279-285
  9. 9. Takami H, Nishi S, Lu J, Shinamura S, Takaki Y. Genomic characterization of thermophilic Geobacillus species isolated from the deepest sea mud of the Mariana Trench. Extremophiles. 2004;8:351-356
  10. 10. Kobayashi J, Furukawa M, Ohshiro T, Suzuki H. Thermoadaptation-directed evolution of chloramphenicol acetyltransferase in an error-prone thermophile using improved procedures. Applied Microbiology and Biotechnology. 2015;99:5563-5572
  11. 11. Kobayashi J, Tanabiki M, Doi S, Kondo A, Ohshiro T, Suzuki H. Unique plasmids generated via pUC replicon mutagenesis in an error-prone thermophile derived from Geobacillus kaustophilus HTA426. Applied and Environmental Microbiology. 2015;81:7625-7632
  12. 12. Suzuki H, Yoshida K. Genetic transformation of Geobacillus kaustophilus HTA426 by conjugative transfer of host-mimicking plasmids. Journal of Microbiology and Biotechnology. 2012;22:1279-1287
  13. 13. Suzuki H, Murakami A, Yoshida K. Counterselection system for Geobacillus kaustophilus HTA426 through disruption of pyrF and pyrR. Applied and Environmental Microbiology. 2012;78:7376-7383
  14. 14. Suzuki H, Wada K, Furukawa M, Doi K, Ohshima T. A ternary conjugation system for the construction of DNA libraries for Geobacillus kaustophilus HTA426. Bioscience, Biotechnology, and Biochemistry. 2013;77:2316-2318
  15. 15. Suzuki H, Yoshida K, Ohshima T. Polysaccharide-degrading thermophiles generated by heterologous gene expression in Geobacillus kaustophilus HTA426. Applied and Environmental Microbiology. 2013;79:5151-5158
  16. 16. Wada K, Kobayashi J, Furukawa M, Doi K, Ohshiro T, Suzuki H. A thiostrepton resistance gene and its mutants serve as selectable markers in Geobacillus kaustophilus HTA426. Bioscience, Biotechnology, and Biochemistry. 2016;80:368-375
  17. 17. Takami H, Takaki Y, Chee G-J, Nishi S, Shimamura S, Suzuki H, Matsui S, Uchiyama I. Thermoadaptation trait revealed by the genome sequence of thermophilic Geobacillus kaustophilus. Nucleic Acids Research. 2004;32:6292-6303
  18. 18. Zheng C, He J, Wang Y, Wang M, Huang Z. Hydrocarbon degradation and bioemulsifier production by thermophilic Geobacillus pallidus strains. Bioresource Technology. 2011;102:9155-9161
  19. 19. Kato T, Haruki M, Imanaka T, Morikawa M, Kanaya S. Isolation and characterization of long-chain-alkane degrading Bacillus thermoleovorans from deep subterranean petroleum reservoirs. Journal of Bioscience and Bioengineering. 2001;91:64-70
  20. 20. Marchant R, Sharkey FH, Banat IM, Rahman TJ, Perfumo A. The degradation of n-hexadecane in soil by thermophilic geobacilli. FEMS Microbiology Ecology. 2006;56:44-54
  21. 21. Wang L, Tang Y, Wang S, Liu R, Liu M, Zhang Y, Liang F, Feng L. Isolation and characterization of a novel thermophilic Bacillus strain degrading long-chain n-alkanes. Extremophiles. 2006;10:347-356
  22. 22. Shimura M, Mukerjee-Dhar G, Kimbara K, Nagato H, Kiyohara H, Hatta T. Isolation and characterization of a thermophilic Bacillus sp. JF8 capable of degrading polychlorinated biphenyls and naphthalene. FEMS Microbiology Letters. 1999;178:87-93
  23. 23. Sood N, Lal B. Isolation and characterization of a potential paraffin-wax degrading thermophilic bacterial strain Geobacillus kaustophilus TERI NSM for application in oil wells with paraffin deposition problems. Chemosphere. 2008;70:1445-1451
  24. 24. Tomita K, Ikeda N, Ueno A. Isolation and characterization of a thermophilic bacterium, Geobacillus thermocatenulatus, degrading nylon 12 and nylon 66. Biotechnology Letters. 2003;25:1743-1746
  25. 25. Amartey SA, Leak DJ, Hartley BS. Development and optimization of a defined medium for aerobic growth of Bacillus stearothermophilus LLD-15. Biotechnology Letters. 1991;13:621-626
  26. 26. Suzuki H, Kobayashi J, Wada K, Furukawa M, Doi K. Thermoadaptation-directed enzyme evolution in an error-prone thermophile derived from Geobacillus kaustophilus HTA426. Applied and Environmental Microbiology. 2015;81:149-158
  27. 27. Naito N, Kusano K, Kobayashi I. Selfish behavior of restriction–modification systems. Science. 1995;267:897-899
  28. 28. Zillig W, Prangishvilli D, Schleper C, Elferink M, Holz I, Albers S, Janekovic D, Götz D. Viruses, plasmids and other genetic elements of thermophilic and hyperthermophilic Archaea. FEMS Microbiology Reviews. 1996;18:225-236
  29. 29. Kunkel TA, Erie DA. DNA mismatch repair. Annual Review of Biochemistry. 2005;74:681-710
  30. 30. Pillon MC, Lorenowicz JJ, Uckelmann M, Klocko AD, Mitchell RR, Chung YS, Modrich P, Walker GC, Simmons LA, Friedhoff P, Guarné A. Structure of the endonuclease domain of MutL: Unlicensed to cut. Molecular Cell. 2010;39:145-151
  31. 31. Simmons LA, Davies BW, Grossman AD, Walker GC. β clamp directs localization of mismatch repair in Bacillus subtilis. Molecular Cell. 2008;29:291-301
  32. 32. Suzuki H. Host-mimicking strategies in DNA methylation for improved bacterial transformation. In: Dricu A, editor. Methylation—From DNA, RNA and Histones to Diseases and Treatment. Rijeka: InTech; 2012. pp. 219-236
  33. 33. Helling RB, Kinney T, Adams J. The maintenance of plasmid-containing organisms in populations of Escherichia coli. Journal of General Microbiology. 1981;123:129-141
  34. 34. Jones KL, Kim SW, Keasling JD. Low-copy plasmids can perform as well as or better than high-copy plasmids for metabolic engineering of bacteria. Metabolic Engineering. 2000;2:328-338
  35. 35. Ow DS, Nissom PM, Philip R, Oh SK, Yap MG. Global transcriptional analysis of metabolic burden due to plasmid maintenance in Escherichia coli DH5α during batch fermentation. Enzyme and Microbial Technology. 2006;39:391-398
  36. 36. Seo J, Balley JE. Effects of recombinant plasmid content on growth properties and cloned gene product formation in Escherichia coli. Biotechnology & Bioengineering. 1985;27:1668-1674
  37. 37. Sabath N, Ferrada E, Barve A, Wagner A. Growth temperature and genome size in bacteria are negatively correlated, suggesting genomic streamlining during thermal adaptation. Genome Biology and Evolution. 2013;5:966-977
  38. 38. Berkner S, Lipps G. Genetic tools for Sulfolobus spp.: Vectors and first applications. Archives of Microbiology. 2008;190:217-230
  39. 39. Thiel A, Michoud G, Moalic Y, Flament D, Jebbar M. Genetic manipulations of the hyperthermophilic piezophilic archaeon Thermococcus barophilus. Applied and Environmental Microbiology. 2014;80:2299-2306

Written By

Tatsuki Mizuno, Takashi Ohshiro and Hirokazu Suzuki

Submitted: 04 November 2016 Reviewed: 07 June 2017 Published: 11 October 2017

© 2017 The Author(s). Licensee IntechOpen. This chapter is distributed under the terms of the Creative Commons Attribution 3.0 License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

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