BSGatlas

floT

BSGatlas-gene-3643

BSGatlas

Description	Information
Coordinates	3180465..3181994
Genomic Size	1530 bp
Name	floT
Outside Links	SubtiWiki
	BsubCyc
Strand	-
Type	CDS

SubtiWiki

Description	Information
Alternative Name	floT
	floT
	yuaG
	yuaH
Category	SW 1 Cellular processes
	SW 1.1 Cell envelope and cell division
	SW 1.1.7 Membrane dynamics
	SW 4 Lifestyles
	SW 4.1 Exponential and early post-exponential lifestyles
	SW 4.1.2 Biofilm formation
	SW 4.1.2.5 Other proteins required for biofilm formation
	SW 4.2 Sporulation
	SW 4.2.3 Sporulation/ other
	SW 4.3 Coping with stress
	SW 4.3.2 Cell envelope stress proteins (controlled by SigM, V, W, X, Y)
	SW 6 Groups of genes
	SW 6.2 Membrane proteins
Description	membrane-associated scaffold protein, orchestration of physiological processes in lipid microdomains, involved in the control of membrane fluidity, confers (together with [[protein\|FFBB9B236B7D532D45FE0593B793E28E051BE7A2]]) resistance to cefuroxime
Function	control of membrane fluidity
Is essential?	no
Isoelectric point	5.14
Locus Tag	BSU_31010
Molecular weight	55.8235
Name	floT
Product	membrane-associated scaffold protein

RefSeq

Description	Information
Alternative Locus Tag	BSU31010
Description	Evidence 1a: Function from experimental evidencesin the studied strain; PubMedId: 9153235, 9987136,12533473, 17482313, 19383680, 25635948, 26297017,28681845; Product type s: structure
Locus Tag	BSU_31010
Name	floT
Title	flotillin lipid rafts scaffold protein
Type	CDS

BsubCyc

Description	Information
Alternative Name	yuaG
	yuaH
Citation	Bach JN;Bramkamp M Dissecting the molecular properties of prokaryotic flotillins. PLoS One 10(1);e0116750 (2015) PUBMED: 25635948
	Bach JN;Bramkamp M Flotillins functionally organize the bacterial membrane. Mol Microbiol 88(6);1205-17 (2013) PUBMED: 23651456
	Dempwolff F;Moller HM;Graumann PL Synthetic Motility and Cell Shape Defects Associated with Deletions of Flotillin/Reggie Paralogs in Bacillus subtilis and Interplay of These Proteins with NfeD Proteins. J Bacteriol 194(17);4652-61 (2012) PUBMED: 22753055
	Dempwolff F;Schmidt FK;Hervas AB;Stroh A;Rosch TC;Riese CN;Dersch S;Heimerl T;Lucena D;Hulsbusch N;Stuermer CA;Takeshita N;Fischer R;Eckhardt B;Graumann PL Super Resolution Fluorescence Microscopy and Tracking of Bacterial Flotillin (Reggie) Paralogs Provide Evidence for Defined-Sized Protein Microdomains within the Bacterial Membrane but Absence of Clusters Containing Detergent-Resistant Proteins. PLoS Genet 12(6);e1006116 (2016) PUBMED: 27362352
	Dempwolff F;Wischhusen HM;Specht M;Graumann PL The deletion of bacterial dynamin and flotillin genes results in pleiotrophic effects on cell division, cell growth and in cell shape maintenance. BMC Microbiol 12;298 (2012) PUBMED: 23249255
	Donovan C;Bramkamp M Characterization and subcellular localization of a bacterial flotillin homologue. Microbiology 155(Pt 6);1786-99 (2009) PUBMED: 19383680
	Lee YH;Kingston AW;Helmann JD Glutamate dehydrogenase affects resistance to cell wall antibiotics in Bacillus subtilis. J Bacteriol 194(5);993-1001 (2012) PUBMED: 22178969
	Lopez D;Kolter R Functional microdomains in bacterial membranes. Genes Dev 24(17);1893-902 (2010) PUBMED: 20713508
	Schneider J;Klein T;Mielich-Suss B;Koch G;Franke C;Kuipers OP;Kovacs ÁT;Sauer M;Lopez D Spatio-temporal Remodeling of Functional Membrane Microdomains Organizes the Signaling Networks of a Bacterium. PLoS Genet 11(4);e1005140 (2015) PUBMED: 25909364
	Schneider J;Mielich-Suss B;Bohme R;Lopez D In vivo characterization of the scaffold activity of flotillin on the membrane kinase KinC of Bacillus subtilis. Microbiology 161(9);1871-87 (2015) PUBMED: 26297017
	Yepes A;Schneider J;Mielich B;Koch G;Garcia-Betancur JC;Ramamurthi KS;Vlamakis H;Lopez D The biofilm formation defect of a Bacillus subtilis flotillin-defective mutant involves the protease FtsH. Mol Microbiol 86(2);457-71 (2012) PUBMED: 22882210
Description	flotillin
Gene Ontology	GO:0016020 membrane
	GO:0016021 integral component of membrane
Locus Tag	BSU31010
Molecular weight	55.994
Name	floT

Nicolas et al. predictions

Description	Information
Expression neg. correlated with	new_4005626_4005729, BSU30350, 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, BSU39650, BSU13880, BSU35660, BSU11620, BSU29820, BSU27710, BSU05160
Expression pos. correlated with	BSU31000, BSU31020, BSU14340, BSU25380, BSU25370, BSU25390, new_3996377_3996599, BSU19290, BSU40180, new_2099865_2099968_c
Highly expressed condition	(T-0.40H) Anon-sporulating B. subtilis strain was grown in a modified M9 medium in batch culture (T. Hardiman, K. Lemuth, M. A. Keller, M. Reuss, M. Siemann-Herzberg, J Biotechnol 132, 359, Dec 1, 2007). Glucose was exhausted when the culture reached an OD600 of approx. 10 and this was designated T0 [T0.0H]. 7 samples were harvested at various times before glucose exhaustion [T-5.40H to T-0.40H] and 10 samples at various times after glucose exhaustion [T0.30H to T5.0H].
	(T-1.10H) Anon-sporulating B. subtilis strain was grown in a modified M9 medium in batch culture (T. Hardiman, K. Lemuth, M. A. Keller, M. Reuss, M. Siemann-Herzberg, J Biotechnol 132, 359, Dec 1, 2007). Glucose was exhausted when the culture reached an OD600 of approx. 10 and this was designated T0 [T0.0H]. 7 samples were harvested at various times before glucose exhaustion [T-5.40H to T-0.40H] and 10 samples at various times after glucose exhaustion [T0.30H to T5.0H].
	(T0.0H) Anon-sporulating B. subtilis strain was grown in a modified M9 medium in batch culture (T. Hardiman, K. Lemuth, M. A. Keller, M. Reuss, M. Siemann-Herzberg, J Biotechnol 132, 359, Dec 1, 2007). Glucose was exhausted when the culture reached an OD600 of approx. 10 and this was designated T0 [T0.0H]. 7 samples were harvested at various times before glucose exhaustion [T-5.40H to T-0.40H] and 10 samples at various times after glucose exhaustion [T0.30H to T5.0H].
	(T0.30H) Anon-sporulating B. subtilis strain was grown in a modified M9 medium in batch culture (T. Hardiman, K. Lemuth, M. A. Keller, M. Reuss, M. Siemann-Herzberg, J Biotechnol 132, 359, Dec 1, 2007). Glucose was exhausted when the culture reached an OD600 of approx. 10 and this was designated T0 [T0.0H]. 7 samples were harvested at various times before glucose exhaustion [T-5.40H to T-0.40H] and 10 samples at various times after glucose exhaustion [T0.30H to T5.0H].
	(T1.0H) Anon-sporulating B. subtilis strain was grown in a modified M9 medium in batch culture (T. Hardiman, K. Lemuth, M. A. Keller, M. Reuss, M. Siemann-Herzberg, J Biotechnol 132, 359, Dec 1, 2007). Glucose was exhausted when the culture reached an OD600 of approx. 10 and this was designated T0 [T0.0H]. 7 samples were harvested at various times before glucose exhaustion [T-5.40H to T-0.40H] and 10 samples at various times after glucose exhaustion [T0.30H to T5.0H].
	(T1.30H) Anon-sporulating B. subtilis strain was grown in a modified M9 medium in batch culture (T. Hardiman, K. Lemuth, M. A. Keller, M. Reuss, M. Siemann-Herzberg, J Biotechnol 132, 359, Dec 1, 2007). Glucose was exhausted when the culture reached an OD600 of approx. 10 and this was designated T0 [T0.0H]. 7 samples were harvested at various times before glucose exhaustion [T-5.40H to T-0.40H] and 10 samples at various times after glucose exhaustion [T0.30H to T5.0H].
	(T2.0H) Anon-sporulating B. subtilis strain was grown in a modified M9 medium in batch culture (T. Hardiman, K. Lemuth, M. A. Keller, M. Reuss, M. Siemann-Herzberg, J Biotechnol 132, 359, Dec 1, 2007). Glucose was exhausted when the culture reached an OD600 of approx. 10 and this was designated T0 [T0.0H]. 7 samples were harvested at various times before glucose exhaustion [T-5.40H to T-0.40H] and 10 samples at various times after glucose exhaustion [T0.30H to T5.0H].
	(T2.30H) Anon-sporulating B. subtilis strain was grown in a modified M9 medium in batch culture (T. Hardiman, K. Lemuth, M. A. Keller, M. Reuss, M. Siemann-Herzberg, J Biotechnol 132, 359, Dec 1, 2007). Glucose was exhausted when the culture reached an OD600 of approx. 10 and this was designated T0 [T0.0H]. 7 samples were harvested at various times before glucose exhaustion [T-5.40H to T-0.40H] and 10 samples at various times after glucose exhaustion [T0.30H to T5.0H].
	(T3.0H) Anon-sporulating B. subtilis strain was grown in a modified M9 medium in batch culture (T. Hardiman, K. Lemuth, M. A. Keller, M. Reuss, M. Siemann-Herzberg, J Biotechnol 132, 359, Dec 1, 2007). Glucose was exhausted when the culture reached an OD600 of approx. 10 and this was designated T0 [T0.0H]. 7 samples were harvested at various times before glucose exhaustion [T-5.40H to T-0.40H] and 10 samples at various times after glucose exhaustion [T0.30H to T5.0H].
	(T3.30H) Anon-sporulating B. subtilis strain was grown in a modified M9 medium in batch culture (T. Hardiman, K. Lemuth, M. A. Keller, M. Reuss, M. Siemann-Herzberg, J Biotechnol 132, 359, Dec 1, 2007). Glucose was exhausted when the culture reached an OD600 of approx. 10 and this was designated T0 [T0.0H]. 7 samples were harvested at various times before glucose exhaustion [T-5.40H to T-0.40H] and 10 samples at various times after glucose exhaustion [T0.30H to T5.0H].
Lowely expressed condition	(C30) Cellsgrown overnight on LB agar plates at 30°Cwere harvested and used to inoculate pre-warmed minimal medium at OD600 of 0.5 (D. Dubnau, R. Davidoff-Abelson, J Mol Biol 56, 209, Mar 14, 1971). After growth at 37°C with vigorous shaking, cells were diluted ten times in fresh pre-warmed minimal medium and samples were harvested after a period of 30 minutes [C30] , i.e. before maximal induction of competence, and after a period of 90 minutes [C90], i.e. when competence induction was maximal.
	(dia0) Diamide was added to an exponentially growing culture (OD600 approx. 0.6) at a sub-lethal concentration(0.5 mM) and growth continued at 37°C with vigorous shaking. Samples were collected 0, 5 and 15 minutes after diamide addition [dia0, dia5 and dia15].
	(dia15) Diamide was added to an exponentially growing culture (OD600 approx. 0.6) at a sub-lethal concentration(0.5 mM) and growth continued at 37°C with vigorous shaking. Samples were collected 0, 5 and 15 minutes after diamide addition [dia0, dia5 and dia15].
	(G180) Purified spores were obtained by growing cells in DSM medium (P. Schaeffer, J. Millet, J. P. Aubert, Proc Natl Acad Sci U S A 54, 704, Sep, 1965) at 37°C for 48 hours after which they were washed ten times in ice cold distilled waterover a period of 5 days. Purified spores were heat activated at 70°C in Tris 10 mM pH8.4 and germination was initiated by the addition of L-alanine 10 mM (A. Moir, J Bacteriol 146, 1106, Jun, 1981). After incubation for one hour at 37°C, the culture was diluted with an equal volume of 2X LBmedium and germinating cells were harvested at 135, 150 or 180 minutes after addition of L-alanine [G135, G150 and G180].
	(H2O2) Cells were grown in LB medium at 37°C. At OD540 of 0.3, the culture were divided into four subcultures and diamide 0.6 mM [Diami], paraquat 0.4 mM [Paraq], H2O2 0.1mM [H2O2] or no oxidative drug [Oxctl] were added to the medium. Samples were taken 10 minutes after addition
	(Heat) 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].
	(LBexp) 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 .
	(LBGexp) Cells were grown in Luria-Bertani medium (Sigma) supplemented with glucose 0.3 % [LBG] 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 .
	(LBGtran) Cells were grown in Luria-Bertani medium (Sigma) supplemented with glucose 0.3 % [LBG] 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 .
	(Paraq) Cells were grown in LB medium at 37°C. At OD540 of 0.3, the culture were divided into four subcultures and diamide 0.6 mM [Diami], paraquat 0.4 mM [Paraq], H2O2 0.1mM [H2O2] or no oxidative drug [Oxctl] were added to the medium. Samples were taken 10 minutes after addition
Name	floT

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