Presentation is loading. Please wait.

Presentation is loading. Please wait.

Do Cyanobacteria Communicate With Each Other? Bacterial Communication Quorum Sensing Important to perform group functions Secretion of toxins to kill.

Published byWhitney Campbell Modified over 8 years ago

Similar presentations

Presentation on theme: "Do Cyanobacteria Communicate With Each Other? Bacterial Communication Quorum Sensing Important to perform group functions Secretion of toxins to kill."— Presentation transcript:

1

2 Do Cyanobacteria Communicate With Each Other?

3 Bacterial Communication Quorum Sensing Important to perform group functions Secretion of toxins to kill competitors, production of luminescent compounds, etc. Small numbers of bacteria don’t activate their Quorum Sensing genes

4 Bacterial Communication Quorum Sensing Gram negative bacteria secrete acylhomoserine lactone (AHL) quorum sensing signals also called Autoinducers (AI’s) These molecules can easily diffuse through the membrane and are detected by proteins in the cytoplasm In this way the gram negative bacteria can communicate with each other When concentration of AI’s is high enough (numbers of bacteria are high enough) it can trigger genes to become expressed

5 Bacterial Communication Vibrio fischeri http://www.biologie.uni-hamburg.de/lehre/mikro/allgmi00/alg07f13.jpg http:// www.genomenewsnetwork.org/articles/2004/01/09/squid.php Hawaiian Bobtailed Squid Euprymna scolopes Light Organ Containing Vibrio fischeri

6 Cell Density Time growth bioluminescence Induction of Bioluminescence in Vibrio Fischeri (Auto-induction)

7 Auto-induction in Vibrio Fischeri LuxI AHL’s LuxR luxCluxDluxAluxBluxE

8 Auto-induction in Vibrio Fischeri LuxI AHL’s LuxR luxCluxDluxAluxBluxE luciferase Autoinducer binds LuxR activated Moves to promoter of luciferase genes

9 Gram Positive Communication Gram positive bacteria secrete small oligopeptides as their signal molecule The other bacteria have receptors for the signal peptides (also called auto-inducers) When the receptor binds the signal peptide it triggers the target genes

10 Gram Positive Quorum Sensing ABC (ATP binding cassette) transporter Recognizes GG containing sequence, Cleaves the peptide, and secretes it GG P P sensor kinase - binding of autoinducer leads to autophosphorylation at conserved histidine residue response regulator - phosphorylation leads to binding of regulator to specific target promoters His P D ACTTTGCGATTGGCC Peptide signal Precursor genes Precursor peptide Final Peptide Signal

11 How do you find what type of signaling cyanobacteria use? Are they similar to the gram positive bacteria? The gram negative? Or something entirely different?

12 Do Cyanobacteria use gram negative type signaling? The LuxI protein in Vibrio fischeri has a specific motif [LMFYA]-R-x(3)-F-x(2)-[KRQ]-x(2)-W-x- [LIVM]-x(6,9)-E-x-D-x-[FY]-D Search proteins of cyanobacteria for this motif = nil

13 Do Cyanobacteria use gram negative type signaling? Use Pfam to find the sequence of proteins related to Luxi Use conserved sequences to create a PSSM to compare with cyanobacterial proteins

14 Q9ZIU1_BURCE/10-189Q9ZIU1_BURCE/10-189.NAEWAVRP..ML.AA.VVECAAQLGARQLIGVTFASMERLFRRIG-IHAHRA..G..PPK....q-V.DGRLV.VAC.. Q9AM57_BURCE/10-189.NAEWAVRP..ML.AA.VVECAAQLGARQLIGVTFASMERLFRRIG-IHAHRA..G..PPK....q-V.DGRLV.VAC.. Q9AM55_BURCE/10-189.NAEWAVRP..ML.AA.VVECAAQLGARQLIGVTFASMERLFRRIG-IHAHRA..G..PPK....q-V.DGRLV.VAC.. Q9AM54_9BURK/10-189.NAEWAVRP..ML.AA.VVECAAQLGARQLIGVTFASMERLFRRIG-IHAHRA..G..PPK....q-V.DGRLV.VAC.. Q93PD3_BURVI/10-173.NAEWAVRP..ML.AA.VVECAAQLGARQLIGVTFASMERLFRRIG-IHAHRA..G..PPK....q-V.DG---.---.. Q93PF8_BURCE/10-173.NAEWAVRP..ML.AA.AVECAAQLGARQLIGVTFASMERLFRRIG-IHAHRA..G..PPK....q-V.DG---.---.. Q9AER2_9BURK/10-189.NAEWAVRP..ML.AA.VVECAAQLGARQLIGVTFASMERLFRRIG-VHAHRA..G..PPK....q-V.DGRLV.VAC.. Q9AM52_BURCE/10-189.NAEWAVRP..ML.AA.VVECAAQLGARQLIGVTFASMERLFRRIG-VHAHRA..G..PPK....q-V.DGRLV.VAC.. Q9AM53_BURVI/10-189.NADWAVRP..ML.AV.VVECAAQLGARQLIGVTFASMERLFRRIG-VHAHRA..G..PPK....q-V.DGRLV.VAC.. Q93PF5_9BURK/10-173.NADWAVRP..ML.AA.VVECAAQLGARQLIGVTFASMERLFRRIG-VHAHRA..G..PPK....q-V.DG---.---.. Q9AM56_BURML/9-189.GADWAVRP..ML.AA.VVACAAERGARQLIGVTFASMERLFRRIG-VHAHRA..G..PPK....q-V.DGRLV.VAC.. Q9AM45_BURML/9-189.GADWAVRP..ML.AA.VVACAAERGARQLIGVTFASKERLFRRIG-VHAHRA..G..PPK....q-V.DGRLV.VAC.. Q9AM44_BURML/9-189.GADWAVRP..ML.AA.VVACAAERGARQLIGVTFASMERLFRRIG-VHAHRA..G..PPK....q-V.DGRLV.VAC.. Q93NN9_BURML/9-189.GADWAVRP..ML.AA.VVACAAERGARQLIGVTFASMERLFRRIG-VHAHRA..G..PPK....q-V.DGRLV.VAC.. Q9AM42_BURML/9-189.GADWAVRP..ML.AA.VVACAAERGARQLIGVTFASMERLFRRIG-VHAHRA..G..PPK....q-V.DGRLV.VAC.. Q9AM43_BURML/9-189.GADWAVRP..ML.AA.VVACAAERGARQLIGVTFASMERLFRRIG-VHAHRA..G..PPK....q-V.DGRLV.VAC.. Q8L2M9_BURPS/13-190.NLAWAVRP..ML.AA.VVECAARLGAKQLIGVTFLSMERLFRRIG-VHAHRT..G..PAQ....q-I.DGRMV.VAC.. Q8KRT8_BURMA/10-190.GGNPAWAVrpML.AA.VVECAARLGAKQLIGVTFLSMERLFRRIG-VHAHRA..G..PAQ....q-I.DGRMV.VAC.. Q6UBQ0_BURPS/10-190.GGNPAWAVrpML.AA.VVECAARLGAKQLIGVTFLSMERLFRRIG-VHAHRA..G..PAQ....q-I.DGRMV.VAC.. Q6Q6F8_BURTH/10-190.TGNPAWAVrpML.AA.VVECAARLGARQLIGVTFLSMERLFRRIG-VHAHRA..G..PAQ....q-I.DGRMV.VAC.. SOLI1_RALSO/10-191.RPDWAVRP..ML.AS.VVQCAAQRGARRLIGVTFVSMVRLFRRIG-VRAHHA..G..PVR....c-I.GGRPV.VAC.. SOLI2_RALSO/10-191.RADWAVRP..ML.AS.VVQCAAQRGARRLIGATFVSMVRLFRRIG-VRAHRA..G..PVR....c-I.GGRPV.VAC.. Q9AHP8_BURCE/9-191.ESWQNTRA..MM.SE.IVRVAHAHGANRLIAFSVLGNERLLKRMG-VNVHRA..A..PPQ....m-I.EGKPT.LPF.. Q9AM57_BURCE/10-189 Q9AM55_BURCE/10-189 Q9AM54_9BURK/10-189 Q93PD3_BURVI/10-173 Q93PF8_BURCE/10-173 Q9AER2_9BURK/10-189 Q9AM52_BURCE/10-189 Q9AM53_BURVI/10-189 Q93PF5_9BURK/10-173 Q9AM56_BURML/9-189 Q9AM45_BURML/9-189 Q9AM44_BURML/9-189 Q93NN9_BURML/9-189 Q9AM42_BURML/9-189 Q9AM43_BURML/9-189 Q8L2M9_BURPS/13-190 Q8KRT8_BURMA/10-190 Q6UBQ0_BURPS/10-190 Q6Q6F8_BURTH/10-190 SOLI1_RALSO/10-191 SOLI2_RALSO/10-191 Q9AHP8_BURCE/9-191 Pfam search results for LuxI Alignment of Conserved sequences for autoinducer synthase (LuxI like proteins)

15 Comparison of s7942 protiens against Luxi-PSSM (#$S7942.p-Ser0724 (19 "LLQAASGLGAGLIVV" 1.1923437) (208 "RLAHWLDRGYSQIAV" 3.6059587) (#$S7942.p-Ser1616 (44 "AVLTAAPSSAAERIT" 1.884795) (294 "HVTTSARSFENVLVG" 63.0499) (409 "VAAVAADGLASDVFG" 2.342644) (431 "TVPTLIWGGSRDVVT" 16.80221) (#$S7942.p-Ser2323 (65 "IRKWNRELDYRLIKE" 14.655321) (77 "IKEVWAWHDNRIAVR" 3.8783476) (#$S7942.p-Sef2443 (51 "TGKPAWELRTPQIVY" 14.529033) (307 "SAKDQARLQANRLIW" 58.11094) (#$S7942.p-Sef2642 (5 "WVRCARLLKLCFCTA" 8.126585) (132 "VGEVAAERLTPAIAT" 7.601579) (#$S7942.p-SSELR002 (146 "IVASSSLNGIQQVVK" 1160.4387) (206 "NTAIAGGHGLTNSIT" 2.1221216) (229 "LIEYLVESGLPQDMA" 2.472199) Results Name of protein, starting position of sequence, sequence, score

16 Do cyanobacteria use gram positive type signaling The peptides used in gram positive bacteria have a conserved GG leader sequence which allows them to be secreted by their ABC transporter This GG containing sequence has its own motif as well LSX2ELX2IXGG Searching cyanobacteria for this motif = nil

17 Possible GG containing sequences found in other experiments Do cyanobacteria use gram positive type signaling Peptide signal molecules and bacteriocins in Gram-negative bacteria: a genome-wide in silico screening for peptides containing a double-glycine leader sequence and their cognate transporters by G. Dirixa, P. Monsieursb, B. Dombrechta, R. Danielsa, K. Marchalb, J. Vanderleydena, J. Michielsa,. MRELTLTEIDNVSGA MKELTQTEVMEVSGA NEELSTDELKSVSGG LQELSFDEIDQVSGA SQELSPQELANISGG IRELNEAELNCICGG TRELTENELEMTAGG FKELKENELTAITGG LKDLSEKELAAVFGG LQELTPEELEQIAGG LQELSTEELEQIAGG MQELSEEQLQATAGG MLELSNQELDYIAGG RQTLSDDELESVAGG RQTLSEDELESVAGG RQTLSDRELEGVAGG GRELSEEELESVAGG PIELSAEELDNVAGG PVELSAEELDNVAGG MKELHTSELVEVSGG MKELNDIEVTCVSGG MIELQLHELKLVSGG MRELTSNEMNNVSGG MRELTSIEMNNVSGG MRELTSYELQAVSGG MRTINDVEMEEVSGG MRTINAAEMEEVSGG MRTLTLNELDSVSGG MRELAFQEIENVDGA MRELVIQEIESVDGG VRELTVREIESVDGG MRELSKVEIEQISGA MRTELEIHEIESIGGA MRKLSENEIKQISGG MREITESQLRYISGA MREISQKDLNLAFGA MRELDREELNCVGGA LFINLSDEQQAFVAG LFINLSDEQQAFVAG LFMNLSDEQQAVVKG LFINLSDTQQAVVTG LFRNVSLEQQEMVVG LLADLSTEQQQFLVG LLEDLSLDQQQSLAG LLVELSTEDQQNLAG YLQDLSEQEQEIICG LFIDIYPEKSESVSG LFTQISVEESGVAAG EQDTLSEAELESVAG

18 Comparison of s7942 proteins against GG-PSSM (#$S7942.p-Sef1302 1280.0376 MQHLVDGDLAANNGG)#$S7942.p-Sef1302 (#$S7942.p-Ser0408 1193.9419 MEERMTVCNMAIEGG)#$S7942.p-Ser0408 (#$S7942.p-Sef2007 39.282513 LGPEASSVIQSIAGG)#$S7942.p-Sef2007 (#$S7942.p-Ser0406 24.167059 AEKMMQAAWQEISGG)#$S7942.p-Ser0406 (#$S7942.p-Ser1379 40.601192 YEQLLAPIYEWMAGG)#$S7942.p-Ser1379 (#$S7942.p-Sef0291 (28.36743 FLSLLSRDQVQWQGG) (#$S7942.p-Ser0724 (2.1610742 RQVVVHRHLGAMLGG) (122.12031 LRQLPLDALGLVFGG) This protein comes from an unknown gene it is small Like most Peptide signal molecules (less than 300 aa’s) So it could be a likely candidate for an autoinducer

19 Do cyanobacteria communicate with eachother? It would be beneficial for them to do so in some cases Tricodesmium grows in clusters Fixes N 2 But not with heterocysts Cells in middle of the clusters are Surrounded by much less O 2 than those Outside the clusters Thus N 2 fixation can occur in this organism

20 Do cyanobacteria communicate with each other? Cant give a definate answer based on these results However there are sequences similar to both types of Autoinducers present in the proteins of cyanobacteria

21 What I would do differently Screen nucleotides instead of proteins Look for nearby ABC transporters for the possible GG-hits Search more cyanobacteria for quorum sensing systems

22 Thanks to colaborators Rakefet Schwarz Bar llan University Alex from Bar llan university Yitschak Friedman Jeff Elhai VCU

Download ppt "Do Cyanobacteria Communicate With Each Other? Bacterial Communication Quorum Sensing Important to perform group functions Secretion of toxins to kill."

Similar presentations

VICTORIA HSIAO 1 Bacterial Edge Detector UT AUSTIN / UCSF IGEM 2006 Charles Darwin, immortalized.

VICTORIA HSIAO 1 Bacterial Edge Detector UT AUSTIN / UCSF IGEM Charles Darwin, immortalized.
Comparison of Genetic Material and Replication for Eukaryotes and Prokaryotes BacteriaArchaeaEukaryotes Genomehaploid; circular diploid; linear HistonesAbsentPresent;

Comparison of Genetic Material and Replication for Eukaryotes and Prokaryotes BacteriaArchaeaEukaryotes Genomehaploid; circular diploid; linear HistonesAbsentPresent;
Programmed population control by cell-cell communication and regulated killing Lingchong You, Robert Sidney Cox III, Ron Weiss & Frances H. Arnold Programmed.

Programmed population control by cell-cell communication and regulated killing Lingchong You, Robert Sidney Cox III, Ron Weiss & Frances H. Arnold Programmed.
Active Transport with the Sodium Potassium Pump. Review Amphipathic molecules: – Hydrophobic region and hydrophilic region Example: Phospholipids and.

Active Transport with the Sodium Potassium Pump. Review Amphipathic molecules: – Hydrophobic region and hydrophilic region Example: Phospholipids and.
Regulating Gene Expression Microbes respond to changing environment – Alter growth rate – Alter proteins produced Must sense their environment – Receptors.

Regulating Gene Expression Microbes respond to changing environment – Alter growth rate – Alter proteins produced Must sense their environment – Receptors.
Plasmids Methods of DNA exchange 2 nd semester 17-2-2015.

Plasmids Methods of DNA exchange 2 nd semester
Holly Sewell 23 July 2010 Marine Biolumin escence.

Holly Sewell 23 July 2010 Marine Biolumin escence.
Sites of regulation. Feedback inhibition Mechanism of allosteric inhibition.

Sites of regulation. Feedback inhibition Mechanism of allosteric inhibition.
Spring semester 2006 ESE601: Hybrid Systems Modeling with hybrid systems.

Spring semester 2006 ESE601: Hybrid Systems Modeling with hybrid systems.
Quorum sensing and multidrug transporters in Escherichia coli PNAS, 2006, 103(7): 2386–2391 Shirley Yang, Christopher R. Lopez, and E. Lynn Zechiedrich.

Quorum sensing and multidrug transporters in Escherichia coli PNAS, 2006, 103(7): 2386–2391 Shirley Yang, Christopher R. Lopez, and E. Lynn Zechiedrich.
Bacterial Quorum Sensing Many species of bacteria use quorum sensing to coordinate their gene expression according to the local density of their population.

Bacterial Quorum Sensing Many species of bacteria use quorum sensing to coordinate their gene expression according to the local density of their population.
Advanced Microbial Physiology Lecture 4 Quorum Sensing.

Advanced Microbial Physiology Lecture 4 Quorum Sensing.
Regulation of gene and cellular activity

Regulation of gene and cellular activity
Cell-Cell Communication In Multicellular Organisms.

Cell-Cell Communication In Multicellular Organisms.
Scotty Merrell Department of Microbiology and Immunology B4140 Regulation of Gene Expression II.

Scotty Merrell Department of Microbiology and Immunology B4140 Regulation of Gene Expression II.
Transcription in Prokaryotes Lecture 9 Lakshmi Rajagopal

Transcription in Prokaryotes Lecture 9 Lakshmi Rajagopal
Gene Regulation 8/24/2015. DNA Binding Proteins Histones Sequence specific DNA major grove Homodimeric Inverted repeats 8/24/2015.

Gene Regulation 8/24/2015. DNA Binding Proteins Histones Sequence specific DNA major grove Homodimeric Inverted repeats 8/24/2015.
Quorum Sensing http://www.ted.com/talks/bonnie_bassler_on_how_bacteria_communicate This whole field has been created by Dr. Bonnie Bassler. She happened.

Quorum Sensing This whole field has been created by Dr. Bonnie Bassler. She happened.
B. Signal Transduction Pathway (cell signaling)

B. Signal Transduction Pathway (cell signaling)
ANTI-MICROBIALS – MEDICINAL CHEMISTRY Timothy Curd - Sunderland University - Supervised by Mark Ashton and Dr Yu Gong. Special acknowledgement to the Nuffield.

ANTI-MICROBIALS – MEDICINAL CHEMISTRY Timothy Curd - Sunderland University - Supervised by Mark Ashton and Dr Yu Gong. Special acknowledgement to the Nuffield.

Similar presentations

Ads by Google