opuE
BSGatlas-gene-828
BSGatlas
Description | Information |
---|---|
Coordinates | 726840..728318 |
Genomic Size | 1479 bp |
Name | opuE |
Outside Links | SubtiWiki |
BsubCyc | |
Strand | - |
Type | CDS |
SubtiWiki
Description | Information |
---|---|
Alternative Name | opuE |
opuE | |
yerK | |
Category | SW 1 Cellular processes |
SW 1.2 Transporters | |
SW 1.2.4 Transporters/ other | |
SW 1.2.4.1 Amino acid transporters | |
SW 1.2.4.1.1 Solute:sodium symporter family | |
SW 1.2.4.1.7 Sodium-solute symporter | |
SW 1.2.4.9 Uptake of compatible solutes | |
SW 4 Lifestyles | |
SW 4.3 Coping with stress | |
SW 4.3.1 General stress proteins (controlled by SigB) | |
SW 4.3.6 Coping with hyper-osmotic stress | |
SW 6 Groups of genes | |
SW 6.2 Membrane proteins | |
Description | proline transporter |
Function | compatible solute transport |
Is essential? | no |
Isoelectric point | 9.81 |
Locus Tag | BSU_06660 |
Molecular weight | 53.1154 |
Name | opuE |
Product | proline transporter |
RefSeq
Description | Information |
---|---|
Alternative Locus Tag | BSU06660 |
Description | Evidence 1a: Function from experimental evidencesin the studied strain; PubMedId: 9701821, 11902719,14996799, 15849754, 16850406, 17183215, 22685134; Producttype t: transporter |
Functions | 16.1: Circulate |
16.8: Protect | |
Locus Tag | BSU_06660 |
Name | opuE |
Title | proline transporter |
Type | CDS |
BsubCyc
Description | Information |
---|---|
Alternative Name | yerK |
Citation | Hoffmann T;Bremer E Guardians in a stressful world: the Opu family of compatible solute transporters from Bacillus subtilis. Biol Chem 398(2);193-214 (2017) PUBMED: 27935846 |
Hoffmann T;von Blohn C;Stanek A;Moses S;Barzantny H;Bremer E Synthesis, release, and recapture of compatible solute proline by osmotically stressed Bacillus subtilis cells. Appl Environ Microbiol 78(16);5753-62 (2012) PUBMED: 22685134 | |
Description | proline transporter |
Gene Ontology | GO:0005215 transporter activity |
GO:0005298 proline:sodium symporter activity | |
GO:0005886 plasma membrane | |
GO:0006810 transport | |
GO:0006811 ion transport | |
GO:0006814 sodium ion transport | |
GO:0015293 symporter activity | |
GO:0016020 membrane | |
GO:0016021 integral component of membrane | |
GO:0031402 sodium ion binding | |
GO:0035524 proline transmembrane transport | |
GO:0035725 sodium ion transmembrane transport | |
GO:0055085 transmembrane transport | |
GO:1902475 L-alpha-amino acid transmembrane transport | |
Locus Tag | BSU06660 |
Molecular weight | 53.283 |
Name | opuE |
Nicolas et al. predictions
Description | Information |
---|---|
Expression neg. correlated with | new_1770236_1770410, BSU34130, BSU06950, BSU08110, BSU06940, BSU35940, BSU06560, BSU35930, BSU06930, BSU16990 |
Expression pos. correlated with | new_728319_728449_c, new_3471824_3472588, BSU33840, BSU33860, BSU05790, BSU04340, BSU05490, BSU_misc_RNA_1, BSU_misc_RNA_3, BSU_misc_RNA_6, BSU_misc_RNA_7, BSU_misc_RNA_8, BSU_misc_RNA_9, BSU_misc_RNA_10, BSU_misc_RNA_11, BSU_misc_RNA_12, BSU_misc_RNA_13, BSU_misc_RNA_14, BSU_misc_RNA_15, BSU_misc_RNA_16, BSU_misc_RNA_17, BSU_misc_RNA_18, BSU_misc_RNA_19, BSU_misc_RNA_20, BSU_misc_RNA_21, BSU_misc_RNA_23, BSU_misc_RNA_24, BSU_misc_RNA_25, BSU_misc_RNA_26, BSU_misc_RNA_27, BSU_misc_RNA_28, BSU_misc_RNA_29, BSU_misc_RNA_31, BSU_misc_RNA_32, BSU_misc_RNA_34, BSU_misc_RNA_36, BSU_misc_RNA_38, BSU_misc_RNA_39, BSU_misc_RNA_40, BSU_misc_RNA_41, BSU_misc_RNA_42, BSU_misc_RNA_44, BSU_misc_RNA_45, BSU_misc_RNA_46, BSU_misc_RNA_47, BSU_misc_RNA_48, BSU_misc_RNA_49, BSU_misc_RNA_50, BSU_misc_RNA_51, BSU_misc_RNA_52, BSU_misc_RNA_53, BSU_misc_RNA_54, BSU_misc_RNA_56, BSU_misc_RNA_59, BSU_misc_RNA_60, BSU_misc_RNA_63, BSU02980, BSU13110 |
Highly expressed condition | (Etha) Cells were grown in a synthetic medium (J. Stülke, R. Hanschke, M. Hecker, J Gen Microbiol 139, 2041, Sep, 1993) with 0.2 % glucose as carbon source (Belitsky Minimal Medium/BMM) at 37 °C with vigorous shaking. Stress was applied to exponentially growing cultures at OD500nm of 0.4. Samples were harvested before stress [BMM]; after a rapid temperature up-shift from 37 °C to 48 °C [Heat]; after a temperature down-shift from 37 °C to 18 °C [Cold]. Ethanol stress was imposed by adding ethanol to a final concentration of 4 % (v/v) and cells were harvested 10 minutes after ethanol addition [Etha]. |
(HiOs) Cells were grown in Spizizen’s minimal medium (SMM) (C. Anagnostopoulos, J. Spizizen, J Bacteriol 81, 741, May, 1961) with vigorous agitation. The control culture was grown at 37 °C [SMMPr]. For growth at high or low temperatures, pre-cultures were grown at 37 °C, diluted to an OD578nm of 0.1 and subsequently transferred to 51 °C [HiTm] and 16 °C [LoTm], respectively. For the growth at high salinity, the salinity of the medium was adjusted by adding NaCl (5 M stock solution) to produce a final concentration of 1.2 M [HiOs]. | |
(MG+10) A culture of LB medium was inocualted from a frozen glycerol stock of B. subtilis. After few hours at 37oC when the culture was growing exponentially, this culture was used to inoculate M9 minimal medium at several different dilutions usually in the range of 500- to 2000-fold. The dilution range was chosen to ensure that at least one of these M9 precultures had reached an OD600 between 0.5 - 1.0 after overnight incubation. These precultures were then used to inoculate 2.5 L of M9 medium in a 3.1 L KLF bioreactor (Bioengineering AG, Wald, Switzerland) to a starting OD600 of 0.03 – 0.05. Condiions in the bioreactor were rigorously controlled as follows: temperature was controlled at 37 °C; the pH was maintained at exactly 7.2 by automatic titration with 2.0 M KOH and 2.0 M H2SO4, and the dissolved oxygen tension was maintained above 50%. In each nutritional shift experiment cells were grown on the single substrate until the OD600 reached 0.50, at which point the second substrate was added instantaneously (4 g/L L-malate or 3 g/L glucose). The nutrient shifts performed were from glucose to glucose+malate [GM] and from malate to malate+glucose [MG] (Buescher et al., accompanying paper). Cell growth during the course was monitored throughout the experiment by measuring OD600. | |
(MG+15) A culture of LB medium was inocualted from a frozen glycerol stock of B. subtilis. After few hours at 37oC when the culture was growing exponentially, this culture was used to inoculate M9 minimal medium at several different dilutions usually in the range of 500- to 2000-fold. The dilution range was chosen to ensure that at least one of these M9 precultures had reached an OD600 between 0.5 - 1.0 after overnight incubation. These precultures were then used to inoculate 2.5 L of M9 medium in a 3.1 L KLF bioreactor (Bioengineering AG, Wald, Switzerland) to a starting OD600 of 0.03 – 0.05. Condiions in the bioreactor were rigorously controlled as follows: temperature was controlled at 37 °C; the pH was maintained at exactly 7.2 by automatic titration with 2.0 M KOH and 2.0 M H2SO4, and the dissolved oxygen tension was maintained above 50%. In each nutritional shift experiment cells were grown on the single substrate until the OD600 reached 0.50, at which point the second substrate was added instantaneously (4 g/L L-malate or 3 g/L glucose). The nutrient shifts performed were from glucose to glucose+malate [GM] and from malate to malate+glucose [MG] (Buescher et al., accompanying paper). Cell growth during the course was monitored throughout the experiment by measuring OD600. | |
(MG+25) A culture of LB medium was inocualted from a frozen glycerol stock of B. subtilis. After few hours at 37oC when the culture was growing exponentially, this culture was used to inoculate M9 minimal medium at several different dilutions usually in the range of 500- to 2000-fold. The dilution range was chosen to ensure that at least one of these M9 precultures had reached an OD600 between 0.5 - 1.0 after overnight incubation. These precultures were then used to inoculate 2.5 L of M9 medium in a 3.1 L KLF bioreactor (Bioengineering AG, Wald, Switzerland) to a starting OD600 of 0.03 – 0.05. Condiions in the bioreactor were rigorously controlled as follows: temperature was controlled at 37 °C; the pH was maintained at exactly 7.2 by automatic titration with 2.0 M KOH and 2.0 M H2SO4, and the dissolved oxygen tension was maintained above 50%. In each nutritional shift experiment cells were grown on the single substrate until the OD600 reached 0.50, at which point the second substrate was added instantaneously (4 g/L L-malate or 3 g/L glucose). The nutrient shifts performed were from glucose to glucose+malate [GM] and from malate to malate+glucose [MG] (Buescher et al., accompanying paper). Cell growth during the course was monitored throughout the experiment by measuring OD600. | |
(MG+45) A culture of LB medium was inocualted from a frozen glycerol stock of B. subtilis. After few hours at 37oC when the culture was growing exponentially, this culture was used to inoculate M9 minimal medium at several different dilutions usually in the range of 500- to 2000-fold. The dilution range was chosen to ensure that at least one of these M9 precultures had reached an OD600 between 0.5 - 1.0 after overnight incubation. These precultures were then used to inoculate 2.5 L of M9 medium in a 3.1 L KLF bioreactor (Bioengineering AG, Wald, Switzerland) to a starting OD600 of 0.03 – 0.05. Condiions in the bioreactor were rigorously controlled as follows: temperature was controlled at 37 °C; the pH was maintained at exactly 7.2 by automatic titration with 2.0 M KOH and 2.0 M H2SO4, and the dissolved oxygen tension was maintained above 50%. In each nutritional shift experiment cells were grown on the single substrate until the OD600 reached 0.50, at which point the second substrate was added instantaneously (4 g/L L-malate or 3 g/L glucose). The nutrient shifts performed were from glucose to glucose+malate [GM] and from malate to malate+glucose [MG] (Buescher et al., accompanying paper). Cell growth during the course was monitored throughout the experiment by measuring OD600. | |
(MG+60) A culture of LB medium was inocualted from a frozen glycerol stock of B. subtilis. After few hours at 37oC when the culture was growing exponentially, this culture was used to inoculate M9 minimal medium at several different dilutions usually in the range of 500- to 2000-fold. The dilution range was chosen to ensure that at least one of these M9 precultures had reached an OD600 between 0.5 - 1.0 after overnight incubation. These precultures were then used to inoculate 2.5 L of M9 medium in a 3.1 L KLF bioreactor (Bioengineering AG, Wald, Switzerland) to a starting OD600 of 0.03 – 0.05. Condiions in the bioreactor were rigorously controlled as follows: temperature was controlled at 37 °C; the pH was maintained at exactly 7.2 by automatic titration with 2.0 M KOH and 2.0 M H2SO4, and the dissolved oxygen tension was maintained above 50%. In each nutritional shift experiment cells were grown on the single substrate until the OD600 reached 0.50, at which point the second substrate was added instantaneously (4 g/L L-malate or 3 g/L glucose). The nutrient shifts performed were from glucose to glucose+malate [GM] and from malate to malate+glucose [MG] (Buescher et al., accompanying paper). Cell growth during the course was monitored throughout the experiment by measuring OD600. | |
(MG+t5) A culture of LB medium was inocualted from a frozen glycerol stock of B. subtilis. After few hours at 37oC when the culture was growing exponentially, this culture was used to inoculate M9 minimal medium at several different dilutions usually in the range of 500- to 2000-fold. The dilution range was chosen to ensure that at least one of these M9 precultures had reached an OD600 between 0.5 - 1.0 after overnight incubation. These precultures were then used to inoculate 2.5 L of M9 medium in a 3.1 L KLF bioreactor (Bioengineering AG, Wald, Switzerland) to a starting OD600 of 0.03 – 0.05. Condiions in the bioreactor were rigorously controlled as follows: temperature was controlled at 37 °C; the pH was maintained at exactly 7.2 by automatic titration with 2.0 M KOH and 2.0 M H2SO4, and the dissolved oxygen tension was maintained above 50%. In each nutritional shift experiment cells were grown on the single substrate until the OD600 reached 0.50, at which point the second substrate was added instantaneously (4 g/L L-malate or 3 g/L glucose). The nutrient shifts performed were from glucose to glucose+malate [GM] and from malate to malate+glucose [MG] (Buescher et al., accompanying paper). Cell growth during the course was monitored throughout the experiment by measuring OD600. | |
(Salt) Cells were grown in Spizizen’s minimal medium (SMM) at 37 °C with vigorous shaking. Salt was added, to a final concentration of 0.4 M to an exponentially growing culture of cells at OD500 of 0.4. Samples were harvested before [SMM] and 10 minutes after [Salt] NaCl addition. | |
(Sw) Exponentially growing cells were spotted on 1 % agar LB plates and incubated at 37°C. Swarming cells were collected after 16 hours. | |
Lowely expressed condition | (LBstat) Cells were grown in Luria-Bertani medium (Sigma) [LB] at 37°C with vigorous shaking in flasks. Overnight cultures were diluted 2000-fold in fresh pre-warmed medium and samples were collected during the exponential [exp], transition [tran] and stationary [stat] phases of the growth cycle . |
(LBtran) Cells were grown in Luria-Bertani medium (Sigma) [LB] at 37°C with vigorous shaking in flasks. Overnight cultures were diluted 2000-fold in fresh pre-warmed medium and samples were collected during the exponential [exp], transition [tran] and stationary [stat] phases of the growth cycle . | |
(M0t90) Cells were grown in LB medium at 37°C with vigorous shaking. An exponentially growing culture (O.D.600 approx. 0.25) was divided: one culture acted as the control [no mitomycin C , M0] while mitomycin was added to the second culture to a final concentration of 40 ng/ml [mitomycin, M40]. Samples were harvested at 0, 45 and 90 minutes after mitomycin addition [t0, t45 and t90]. | |
(M40t90) Cells were grown in LB medium at 37°C with vigorous shaking. An exponentially growing culture (O.D.600 approx. 0.25) was divided: one culture acted as the control [no mitomycin C , M0] while mitomycin was added to the second culture to a final concentration of 40 ng/ml [mitomycin, M40]. Samples were harvested at 0, 45 and 90 minutes after mitomycin addition [t0, t45 and t90]. | |
(S3) Cells were grown in CH medium at 37°C and sporulation was induced by resuspension in warm sporulation medium as described by Sterlini and Mandelstam (J. M. Sterlini, J. Mandelstam, Biochem J 113, 29, Jun, 1969). The initiation of sporulation was designated T0, the time of resuspension. Samples were harvested at hourly intervals for 6 hours [S0 to S6] for the first set of experiments and for 8 hours [S0 to S8] for a second set of experiments. | |
(S4) Cells were grown in CH medium at 37°C and sporulation was induced by resuspension in warm sporulation medium as described by Sterlini and Mandelstam (J. M. Sterlini, J. Mandelstam, Biochem J 113, 29, Jun, 1969). The initiation of sporulation was designated T0, the time of resuspension. Samples were harvested at hourly intervals for 6 hours [S0 to S6] for the first set of experiments and for 8 hours [S0 to S8] for a second set of experiments. | |
(S5) Cells were grown in CH medium at 37°C and sporulation was induced by resuspension in warm sporulation medium as described by Sterlini and Mandelstam (J. M. Sterlini, J. Mandelstam, Biochem J 113, 29, Jun, 1969). The initiation of sporulation was designated T0, the time of resuspension. Samples were harvested at hourly intervals for 6 hours [S0 to S6] for the first set of experiments and for 8 hours [S0 to S8] for a second set of experiments. | |
(S6) Cells were grown in CH medium at 37°C and sporulation was induced by resuspension in warm sporulation medium as described by Sterlini and Mandelstam (J. M. Sterlini, J. Mandelstam, Biochem J 113, 29, Jun, 1969). The initiation of sporulation was designated T0, the time of resuspension. Samples were harvested at hourly intervals for 6 hours [S0 to S6] for the first set of experiments and for 8 hours [S0 to S8] for a second set of experiments. | |
(S7) Cells were grown in CH medium at 37°C and sporulation was induced by resuspension in warm sporulation medium as described by Sterlini and Mandelstam (J. M. Sterlini, J. Mandelstam, Biochem J 113, 29, Jun, 1969). The initiation of sporulation was designated T0, the time of resuspension. Samples were harvested at hourly intervals for 6 hours [S0 to S6] for the first set of experiments and for 8 hours [S0 to S8] for a second set of experiments. | |
(S8) Cells were grown in CH medium at 37°C and sporulation was induced by resuspension in warm sporulation medium as described by Sterlini and Mandelstam (J. M. Sterlini, J. Mandelstam, Biochem J 113, 29, Jun, 1969). The initiation of sporulation was designated T0, the time of resuspension. Samples were harvested at hourly intervals for 6 hours [S0 to S6] for the first set of experiments and for 8 hours [S0 to S8] for a second set of experiments. | |
Name | opuE |