The Course of Development

Time Events

The Course of Development Time Events

The Course of Development Time Events in time

The Course of Development Time Events in time

The Course of Development Time Events in time and space...

The Course of Development Time Events in time and space...

The Course of Development Time Events in time and space...

The Course of Development Events in time and space driven by patterned gene expression

The Course of Development Events in time and space driven by patterned gene expression Understanding Human Development

The Course of Development Understanding Human Development

The Course of Development Understanding Human Development

The Course of Development The fate of cells patterned in time and space Intrinsic control? Extrinsic control? Understanding Human Development

Why so difficult? DevelopmentComplex Process9 mo – 20 yrs Generation20 yrs Genetic recombinationUncontrolled Genetic manipulationDifficult / Impossible Genome size ~3 billion nucleotides How to attack a problem that’s too complex?

How to Attack a Complex Problem Probability of getting a full house?

How to Attack a Complex Problem Probability of getting a pair?

How to Attack a Complex Problem Probability of getting a pair in 2 cards? 1· 3/51

Simplification can help in understanding complexity

Understanding Human Development Why so difficult? DevelopmentComplex Process9 mo – 20 yrs Generation20 yrs Genetic recombinationUncontrolled Genetic manipulationDifficult / Impossible Genome size ~3 billion nucleotides

Process9 mo – 20 yrs Generation20 yrs Genetic recombinationUncontrolled Genetic manipulationDifficult / Impossible Genome size ~3 billion nucleotides Understanding Fly Development ~8 days ~14 days Controlled Difficult Still difficult How to simplify further? ~170 million nucleotides DevelopmentComplexComplex

Process Generation Genetic recombination Genetic manipulation Genome size ~8 days ~14 days Controlled Difficult Does such an organism exist? DevelopmentComplex ~170 million nucleotides Hours Easy Few million nucleotides Single phenomenon What do we want in a model organism? Understanding Any Development

Bacteria... but no development

Bacillus subtilis Temporally regulated differentiation Sporulation by Bacillus subtilis

Bacillus subtilis Temporally regulated differentiation Sporulation by Bacillus subtilis

Bacillus subtilis Temporally regulated differentiation Sporulation by Bacillus subtilis

Bacillus subtilis Temporally regulated differentiation Sporulation by Bacillus subtilis

Bacillus subtilis Temporally regulated differentiation Sporulation by Bacillus subtilis Development in time and space

Free-living Nostoc heterocysts Matveyev and Elhai (unpublished) CO 2 sucrose N2N2 O2O2 Heterocyst differentiation by Anabaena

Free-living Nostoc heterocysts Matveyev and Elhai (unpublished) CO 2 sucrose N2N2 NH 3 O2O2 Heterocyst differentiation by Anabaena

Anabaena Spatially regulated differentiation Heterocyst differentiation by Anabaena Time after nitrogen removal 0 h 3 h 6 h 9 h 12 h 18 h N 2 fixation

Anabaena Spatially regulated differentiation Heterocyst differentiation by Anabaena Time after nitrogen removal 0 h 3 h 6 h 9 h 12 h 18 h N 2 fixation

Anabaena Spatially regulated differentiation Heterocyst differentiation by Anabaena Mark Hill, University of New South Wales Time after nitrogen removal 0 h 3 h 6 h 9 h 12 h 18 h N 2 fixation Development of pattern

Fruiting body formation by Myxococcus Herd motility

Fruiting body formation by Myxococcus Herd development

Fruiting body formation by Myxococcus Extrinsic control over development

Caulobacter crescentus Cell cycle-regulated differentiation Cell cycle of Caulobacter swarmer cell

Caulobacter crescentus Cell cycle-regulated differentiation Cell cycle of Caulobacter swarmer cell stalk cell

Caulobacter crescentus Cell cycle-regulated differentiation Cell cycle of Caulobacter swarmer cell stalk cell

Caulobacter crescentus Cell cycle-regulated differentiation Cell cycle of Caulobacter Intrinsic control over development

End result... much simpler Bacillus sporulation Myxobacteria fruiting Anabaena heterocysts Caulobacter cell cycle Bacterial Development

Bacillus subtilis Temporally regulated differentiation Sporulation by Bacillus subtilis ? How to make the decision? Control of initiation selective gene expression

Bacterial regulation of gene expression Transcriptional factors DNA RNA protein RNA Pol P

No stimulus DNA binding protein RNA Pol Binding site P DNA No RNA Stimulus signal Bacterial regulation of gene expression Transcriptional factors

DNA binding protein RNA Pol Binding site P DNA No RNA No stimulusStimulus signal Bacterial regulation of gene expression Transcriptional factors

DNA RNA Pol Spo0A Binding site P RNA protein No stimulusStimulus signal Bacterial regulation of gene expression Transcriptional factors

Sporulation by Bacillus subtilis Control of initiation selective gene expression P ADP ATP P Spo genes Spores spo0A A P A P spo0B B B spo0F P F F kinA P K K Why???

PP Sporulation by Bacillus subtilis Phosphorelay as an integration processing device P ADP ATP P Spo genes Spores spo0A A P A P spo0B B B spo0F P F F kinA P K K Cell density Control by phosphatases ? - Cell cycle - DNA damage - Nutrient status

Sporulation by Bacillus subtilis Control of initiation of development Integration of signals through signal transduction Centers on phosphorylation of master protein DNA binding protein regulates transcription

Bacillus subtilis Temporally regulated differentiation Sporulation by Bacillus subtilis Control of timing by selective gene expression Set 0 Set II Set III Set IVSet V Fore-sporeMother cell

Promoter recognition by sigma factors Figure from Griffiths et al (1996) Introduction to Genetic Analysis, 6th ed., WH Freeman and Co.    '' RNA polymerase core enzyme Sigma factor

Figure from Griffiths et al (1996) Introduction to Genetic Analysis, 6th ed., WH Freeman and Co. Promoter recognition by sigma factors

Figure from Griffiths et al (1996) Introduction to Genetic Analysis, 6th ed., WH Freeman and Co. Promoter recognition by sigma factors

AA uvrB Repair DNA damage TTGTTGGCATAATTAAGTACGACGAGTAAAATTAC ATACCT recA DNArecombination CACTTGATACTGTA.TGAGCATACAGTATAATTGC TTCAACA rrnAB RibosomalRNA CTCTTGTCAGGCCG.GAATAACTCCCTATAATGCGCCACCACTG str Ribosomal protein TTCTTGACACCTT.TCGGCATCGCCCTAAAATTCG GCGTCG rpoA RNA polymerase TTCTTGCAAAGTTGGGTTGAGCTGGCTAGATTAGC CAGCCA TTGaca TAtAaT R Promoter recognition by sigma factors

NN uvrB Repair DNA damage TTGTTGGCATAATTAAGTACGACGAGTAAAATTAC ATACCT recA DNArecombination CACTTGATACTGTA.TGAGCATACAGTATAATTGC TTCAACA rrnAB RibosomalRNA CTCTTGTCAGGCCG.GAATAACTCCCTATAATGCGCCACCACTG str Ribosomal protein TTCTTGACACCTT.TCGGCATCGCCCTAAAATTCG GCGTCG rpoA RNA polymerase TTCTTGCAAAGTTGGGTTGAGCTGGCTAGATTAGC CAGCCA TTGacaTAtAaT R Kp nifE nitrogenase accessory CTTCTGGAGCGCGAATTGCA TCTTCCCCCT Kp nifU nitrogenase accessory TCTCTGGTATCGCAATTGCT AGTTCGTTAT Kp nifB nitrogenase accessory CCTCTGGTACAGCATTTGCA GCAGGAAGGT Kp nifH nitrogenase CGGCTGGTATGTTCCCTGCACTTCTCTGCTG Kp nifM nitrogenase accessory TGGCTGGCCGGAAATTTGCA ATACAGGGAT Kp nifF nitrogenase accessory AACCTGGCACAGCCTTCGCA ATACCCCTGC Kp nifL nitrogenase regulat’n ATAAGGGCGCACGGTTTGCATGGTTATCACC glnA P2glutamine synthetase AAGTTGGCACAGATTTCGCTTTATCTTTTTT CTGG-ATTGCA AA Promoter recognition by sigma factors

Sigma factors in sporulation A A A A H H H H Starvation (and other signals) Stage 0 Starvation- specific Sigma-H Housekeeping Sigma-A

Sigma factors in sporulation A A A A H H E E F F Stage II/III Mother cellForespore Forespore- specific Sigma-F Mother-specific Sigma-E

Sigma factors in sporulation A A A A H H H H Starvation (and other signals) Stage 0 E E E F F F Uniform presence of inactive sigma precursors

F F F F E E Sigma factors in sporulation A A A A H H E E F F Stage II/III E F Selective activation of sigma precursors Active mother- specific Sigma-E Active forespore- specific Sigma-F

Sigma factors in sporulation A A E E F F K K G G Starvation (and other signals) Stage III Stage IV Late forespore- specific Sigma-G Late mother- specific Sigma-K Cascade of sigma factors

Sporulation by Bacillus subtilis Control of timing by selective gene expression Determined by specific, active sigma factors Presence and activation important Activation linked to morphological events

Anabaena Spatially regulated differentiation Heterocyst differentiation by Anabaena Time after nitrogen removal 0 h 3 h 6 h 9 h 12 h 18 h N 2 fixation How to find regulation of pattern?

Genetic approach to Cell Biology

Isolation of Defective Gene Genetic approach to Cell Biology

Anabaena Spatially regulated differentiation Heterocyst differentiation by Anabaena Time after nitrogen removal 0 h 3 h 6 h 9 h 12 h 18 h N 2 fixation How to find regulation of pattern? Many mutants Rare mutants hetR

Anabaena Spatially regulated differentiation Heterocyst differentiation by Anabaena How to find regulation of pattern? hetR Gene expression? hetR - +N -N +N -N +N hetR (wild-type)

GTA..(8).. TAC 5’-GTGAGTTAGCTCACNNNNNNNNNNTANNNTNNNNNNNNNNNNNNNNNNNNNNNNNNNNATGNNNNNNNNNNNNNNNN 3’-CACTCAATCGAGTGNNNNNNNNNATNNNANNNNNNNNNNNNNNNNNNNNNNNNNNNNNTACNNNNNNNNNNNNNNNN Reporter gene Gene fusions to monitor expression 5’-GTA..(8).. TACNNNNNNNNNNTANNNTNNNNNNNNNNNNNNNNNNNNNNNNNNNNATGNNNNNNNNNNNNNNNN 3’-CAT..(8).. ATGNNNNNNNNNNATNNNANNNNNNNNNNNNNNNNNNNNNNNNNNNNTACNNNNNNNNNNNNNNNN hetR gene RNA Polymerase hetR Regulation

GTA..(8).. TAC NNNNNNNNNNNNNNNNNNATGNNNNNNNNNNNNNNNN NNNNNNNNNNNNNNNNNNTACNNNNNNNNNNNNNNNN Reporter gene Gene fusions to monitor expression 5’-GTA..(8).. TACNNNNNNNNNNTANNNTNNNNNNNNNN 3’-CAT..(8).. ATGNNNNNNNNNNATNNNANNNNNNNNNN RNA Polymerase hetR Regulation

Detection of hetR gene expression through Green Fluorescent Protein The hydromedusa Aequoria victoria Source of Green Fluorescent Protein

Expression of hetR during differentiation Weak and patchy

Expression of hetR after differentiation Strong and focused

hetR - hetR (wild-type) hetR expression 0 18 Hrs after -N HetR is required for its own induction! hetR + hetR - hetR (wild-type) HetR Feedback Induction Expression of hetR after differentiation Other examples: spo0Aeve

Temperature Feedback Induction Temperature Feedback Inhibition Feedback Regulation Stability All-or-none

Feedback Regulation Alan Turing’s Reaction-Diffusion Model R color D + Marcelo Walter, U Br Columbia

Feedback Regulation Alan Turing’s Reaction-Diffusion Model R color D + Giraffe Model Initiation Marcelo Walter, U Br Columbia

Feedback Regulation Alan Turing’s Reaction-Diffusion Model Pattern emerging from random initiation

Feedback Regulation Alan Turing’s Reaction-Diffusion Model Pattern emerging from random initiation

Feedback Regulation Alan Turing’s Reaction-Diffusion Model R color D + hetR What is the diffusible inhibitor?

Heterocyst differentiation by Anabaena How to find the hypothetical diffusible inhibitor? plasmid (chopped) Encodes diffusible inhibitor? genome ?

Heterocyst differentiation by Anabaena The nature of the hypothetical inhibitor (typical size of gene) Active part of sequence MLVNFCDERGSGR PatS Is PatS the predicted diffusible inhibitor?

Heterocyst differentiation by Anabaena The nature of the hypothetical inhibitor + RGSGR hetR HetR R color D + hetR + RGSGR HetR + patS -

Heterocyst differentiation by Anabaena The nature of the hypothetical inhibitor +N -N patS + (wild-type) +N -N patS - Multiple heterocysts But not ALL heterocysts

Heterocyst differentiation by Anabaena The nature of the hypothetical inhibitor Nonrandom spacing

Heterocyst distribution is affected Heterocyst differentiation by Anabaena The nature of the hypothetical inhibitor But it’s not RANDOM

Heterocyst differentiation by Anabaena A natural example of the Turing model? Differentiation regulated by R-like protein, HetR Differentiation regulated by D-like protein, PatS Pattern is not completely determined by HetR and PatS

End result... much simpler Bacillus sporulation Myxobacteria fruiting Anabaena heterocysts Caulobacter cell cycle Bacterial Development vs

How to understand complexity?