POSSIBLE FUNCTIONS of the CIRCADIAN CLOCK

POSSIBLE FUNCTIONS of the CIRCADIAN CLOCK IS IT IMPORTANT AT ALL? YES! POSSIBLE FUNCTIONS DAILY PROGRAMING of PHYSIOLOGY PHOTOPERIODIC REPRODUCTION ANIMAL MIGRATION MCB 186 December 5, 2007

IS THE CIRCADIAN CLOCK IMPORTANT ? DOES THE CLOCK CONFER SELECTIVE ADVANTAGE?MAYBE NOT: NULL MUTANTS are VIABLE in ALL STUDIES TWO KINDS of STUDIES MEASURE LIFESPAN IN ANIMALS SUBJECTED TO NON-24 hr CYCLES RESONANCE EXPERIMENTS IN CYANOBACTERIA USING PERIOD MUTANTS

SURVIVIAL CURVES for FLIES in LIGHT/DARK CYCLES with PERIODS of 20, 24 AND 28 HOURS

FIVE HOUR LD PHASE SHIFTS EACH CYCLE

CYANOBACTERIA MUTANTS V.S. WILD TYPE IN DIFFERENT LD CYCLES C.H. Johnson lab

CYANOBACTERIAMUTANT Tau-28 V.S. WILD TYPE Tau-25C.H.Johnson lab Two independent experiments

SOME FUNCTIONS OF THE CIRCADIAN CLOCK TIMED PHYSIOLOGY: SPECIFIC TIMES OF DAY/NIGHT Synthesis of specific proteins at specific times of day Insect eclosion acrophase is at time of daily temperature minimum. The internal bee clock; Visitations timed to time of flower openings Cyanobacteria, photosynthesis by day, nitrogen fixation by night. PHOTOPERIODIC REPRODUCTION: MEASURE DURATION OF DAY AND NIGHT -Plants: seasonal flowering, spring, summer or fall. -Animal seasonal reproduction; hamster only once per year. ANIMAL MIGRATION -Celestial navigation for migration (birds, butterflies, arthropods, fish, reptiles); knowledge of time of day required.

TIME of DAY PROGRAMS • Different activities at different times of day involve different genes and proteins • In circadian systems, different proteins are synthesized at different times of day • Cyanobacteria carry out photosynthesis with oxygen production and nitrogen fixation at different times of day. Oxygen inhibits nitrogenase.

BEAN (top) and CANAVALIA CIRCADIAN LEAF MOVEMENTS

DROSOPHILA ENTRAINMENT TO FULL LD CYCLES PITTENDRIGHACROPHASE DEPENDS ON PHOTO-FRACTION

TEMPORAL SEPARATION OF CELL BIOCHEMICAL ACTIVITIES IN CYANOBACTERIA (OXYGEN, NITROGENASE ETC)MITSUI ET AL 1986

Markovic et al., 1996 J. Biol. Rhythms 11 PATTERNS of CLOCK-CONTROLLED PROTEIN SYNTHESIS in Gony p21 unknown p32 PCP p33 OEE1 p45 GAPDH p55 Rubisco II p75 Luciferin binding protein

PHOTOPERIODISMDISCOVERY: Garner & Allard, 1920 TOBACCO FLOWERING ONLY IN FALL WITH SHORT DAYS OTHER PLANTS SHOWN TO FLOWER WITH LONG DAYS. STILL OTHERS DAY LENGTH NEUTRALTERMINOLOGY CORRECTED: Hamner & Bonner, 1938 LENGTH OF THE NIGHT, NOT THE DAY, IS CRITICAL LIGHT INTERRUPTIONS OF NIGHT BLOCK RESPONSE, DARK INTERRUPTIONS OF DAY DO NOT BLOCKINCORRECT TERMINOLOGY STILL IN USE:

DAY LENGTH AT DIFFERENT LATITUDES & SEASONS

HAMSTER TESTIS WEIGHT IN DIFFERENTFULL PHOTOPERIODS Elliott, 1976

PHOTOPERIODIC INDUCTION OF CYSTS IN GONYAULAX

SOY BEAN (SHORT DAY PLANT) 0.5 hr LIGHT INTERRUPTION of LONG DARK PERIOD WARING, 1954

H. NIGER (LONG-DAY PLANT) 2 hr LIGHT INTERRUPTION OF LONG DARK PERIOD

SOYBEAN (short day) FLOWERING IN DIFFERENT LD CYCLES

MODELS FOR PHOTOPERIODISM HOUR GLASS: Substance X builds up during dark Explains night interruption by brief light exposure Does not explain oscillation of long dark periods. ENDOGENOUS OSCILLATION Explains circadian recurrence of susceptibility to brief light exposure during prolonged DD External Coincidence model: Night interruption causes delays & advances

EXTERNAL COINCIDENCE: POSTULATED PHOTOPERIODIC EFFECTS ON AN ORGANISM WITH A CIRCADIAN tau OF 24.5 hr

ENTRAINED T of HAMSTER ACTIVITY RHYTHM DEPENDS on PERIOD of SINGLE PULSE T CYCLE and PULSE is POSITIONED DIFFERENTLY Elliott 1976 DELAYS ADVANCES Tau for hamster is very close to 24 h Both T cycles cause phase shifts, + & -

HAMSTER TESTICULAR RESPONSES to T CYCLE PERIOD LENGTH

DROSOPHILA ENTRAINMENT TO FULL LD CYCLES PITTENDRIGH

PHASE ANGLES WITH DIFFERENT TWO PULSE SKELETONS Pittendrigh

BISTABILITY IN HAMSTER ENTRAINMENT SKELETON PHOTOPERIOD 13.5:0.25:10:0.25 hrs ANIMAL C15 ACTIVE in SHORT NIGHT TESTES MAINTAINED; ANIMAL C16 ACTIVE in LONG NIGHT; TESTES REGRESSED

SKELETON PHOTOPERIOD PHASING GIVES DIFFERENT RESPONSES

ARE HUMANS AFFECTED by PHOTOPERIOD?It appears so! • ANNUAL CYCLES • DAILY ENTRAINMENT PHASE

1824 1947

HUMAN ANNUAL CONCEPTION RHYTHMS

SOCIAL INFLUENCES on the ANNUAL CONCEPTION RHYTHM

Effect of Residence Locations on Sleep Acrophase (n=21,600) Roenneberg, 2006 Germany

DEPENDENCE of TIME of MID-SLEEP on LONGITUDE 8.5O=34min and RELATION to POPULATION DENSITY Roenneberg, 2006 Rural and towns less than 300,000 persons > 500,000 300,000 - 500,000

DAYLIGHT SAVING TIME RELATED to SLEEP PHASE and DURATION

CIRCANNUAL RHYTHMS IN SQUIRRELS & GONYAULAX

FUNCTIONS of the CIRCADIAN CLOCK CELESTIAL NAVIGATION -Animal migration (birds, butterflies, arthropods, fish, reptiles); knowledge of time of day required.

DIRECTION OF STARLING MIGRATORY ACTIVITYKramer,1950a) clear sky b)overcast c),d) direction of incident light deflected by mirrors

DIRECTION OF DEPARTURE IN PIGEONS ALTERED AFTER EXPOSURE TO LD CYCLE ALTERED BY 6 hr Schmidt-Koenig,1961

SHIFTING THE DIRECTIONAL RESPONSE OF PIGEONS

DELAYED SLEEP PHASE INSOMMNIA THERAPY Deficiency in advance phase shifts Treatment: Impose repeated delays until patient is back in phase.

POSSIBLE FUNCTIONS of the CIRCADIAN CLOCK

POSSIBLE FUNCTIONS of the CIRCADIAN CLOCK

Presentation Transcript

Floxing around with the clock: The effects of circadian clock gene deletion on the neuroendocrine control of reproducti

Models of Circadian Rhythms

Investigating the Biology of Circadian Rhythms

The clock

Circadian rhythm

Possible studies of structure functions at JLab

Does the Circadian Clock Modulate an Organism’s Response to Toxins?

Circadian Rhythms

circadian rhythms

Analyzing various models of Circadian Clock and Cell Cycle coupling

Circadian Rytyhymys

V2: Feedback loops control the mammalian circadian core clock

Clock Auctions, Proxy Auctions, and Possible Hybrids

Mechanistic Basis of Oscillation in a Three-Protein Circadian Clock

The clock

The robust ticking of a circadian clock

circadian rhythm

AGING AND THE CIRCADIAN CLOCK

Circadian Entrainment or Keeping Your Clock in Synch

Multiscale Modeling of the Mammalian Circadian Clock: The Role of GABA Signaling

Circadian Rhythms