Selected lectures from Physiology •Children puzzle (riddle): • •It's still all around us; not to see or hear. •You can not touch it, even to smell. •Life can not do without it. •It forms part of each story. •It's as long as it takes, and it's happening everywhere. • •What is it? • •A house full of wheels •What is it? • • Information from previous lectures: Type of secretion of hormones - summary: •Constant secretion – hormones of glandula thyreoidea •Pulsatile secretion – GnRH (gonadoliberin) •circadian secretion (latin: circa diem = approximately 24h) – hormons of adrenal cortex •monthly fluctuation – estrogens, testosteron in saliva •„en demande“ (according to need - demands) – e.g. Insuline and regulation blood glucose Records of breathing and circulatory parameters waves (from plethysmomanometer - Peňáz method) obr11 Biorhythms - studied by chronobiology as a special branch of physiology research In humans and other mammals, processes such as sleep/awake and feed/fast cycles, body temperature oscillations, hormonal secretions and metabolic events occur in a circadian manner and are ruled by biological clock Periods of rhythms (a frequency with which the parametr is repeated): Ultradian period – period is shorter than 24hours (e.g.:10sec rhythm in breathing) Circadian period – period is 24h (sleep/awake…..from Latin circa diem-about a day) Infradian period – period is longer than 24h (the menstrual cycle) Pineal gland •The pineal gland coordinates circadian (daily) rhythms of dark/light (day-night) cycles by secreting the hormone melatonin. Darkness stimulates its release. Macrostructure: -it is a small gland found of posterior end of the corpus callosum, forming a section of the roof in the posterior wall of the third ventricle •Microstructure of pineal gland • •: - is composed of 2 types of neural cells: pinealocytes (specialized secretory neurons) + glial support cells •: - it has a very rich blood supply that forms a network of capillaries surrounded by the pinealocytes •: - it receives innervation from many parts of the brain, but the main connections are with: • Suprachiasmatic nuclei (SCN) • Retina • Sympathetic system (multisynaptic sympathetic way: paraventricular nucleus in hypothalamus + upper sympathetic cervical ganglion – SCG; releas norepinephrin-beta adrenergic receptors –stimulate cAMP-activate gene expression for gen coding AA-NAT=arylalkylamin-N-acetyltranspherase) • • Master circadian pacemaker •Information about the external light-dark cycle was passed via the retinohypothalamic tract – sensory input integrating centers in the thalamus, but also to the hypothalamic suprachiasmatic nucleus •SCN – is a bilaterally paired structure with high cell body density located to the third ventricle and directly atop the optic chiasm. •It comprises about 50 000 neurons in humans (in rodents 20 000) •Plays critical role in generation of mammalian circadian rhythms •(in experiments – animal with ablated SCN become behaviorally and physiologically arrhythmic. Critically, transplanting isolated SCN tissue into SCN-lesioned animals restores circadian rhythmicity) The molecular clockwork •Period genes (PER) was the first discovered clock gene which is conversed from fruit flies to humans………1971 (Konopka and Benzer) •In the past decades our knowledge of the molecular clockwork has been significantly expanded •Transcriptional-translation feed-back loop •Two helix-loop-helix transcription factors: • CLOCK – circadian locomotor output cycles kaput •+ BMAL1 (ARNTL) – brain and muscle aryl hydrocarbon receptor nuclear translocator. •Both form heterodimers via their PAS domein – PER-ARNTL-SIM binding. •Activates E-box-element containing gens. •Complexes CLOCK+BMAL1 activate transcription of PER and CRY genes during the day. PERs and CRYs translocate into the nucleus and forms inhibitory complexes, PER/CRY complexes accumulate and does their inhibitory effect on CLOCK-BMAL1 activity, shutting down Per and Cry transcription during the night. • (Silbernagl at al. 2006) •PER – period gene – PER 1, PER2, PER 3 ---trimer •CLOCK – circadian locomotor output cycles kaput •BMAL1 (ARNTL) – brain and muscle aryl hydrocarbon receptor nuclear translocator •PAS domena – PER-ARNTL-SIM •E-Box –controlled genes •CRY genes – cryptochrome • • •„intrinsic clock“ - in humans – period time duration : 24.2 – 26 h; mean 25h • (e.g. - mouse: 23.8 h) • •Pineal gland - Function: •The pineal gland synthesizes and secrets the hormone MELATONIN • (NOT melanin – the brown skin pigment) •Melatonin is modified form of the aminoacid tryptophan (4steps of biosynthesis - serotonin – enzyme AA-NAT=arylalkylamin-N-acetyltranspherase : activity on the night, light – inhibited – acetylation –methylation ….melatonin • •The suprachiasmatic nucleus in the hypothalamus serves as an „intrinsic clock“ which interacts with an external rhythm stimulus, in this case light, to coordinate melatonin release with the external day-night cycle • •This system allows the conversion of inhibitory light stimuli into a hormonal stimulus that can regulate: • : Day-night (circadian rhythm) • : Seasonal breeding rhythms (e.g. deer, birds) (Silbernagl at al. 2006) Effects of melatonin – pleiotropic effect •Melatonin has 3 main effects: • •It resets the SCN •It induces sleep (hypnotic effect) •It influences the hypothalamus, especially the reproductive function • •Circadian rhythms influence almost every cell in the body. Hormones are secreted from the hypothalamus, pituitary gland and gonads with a circadian rhythm-e.g.: CRH, ACTH-peak early in the morning (Reiter at al. 2014) Jet lag syndrome •The pineal gland has evolved to allow adaptation to changing day length: •When people leaves his/her home country the SCN and pineal gland are synchronized: at night, darkness and SCN activation stimulate melatonin production, inducing sleep •If the person flies across time zones, the SCN continues to oscillate in accordance with the previous time zone, which means that the timing of melatonin production (and, therefore, tiredness) does not change •At a rate of adjustment of a couple of hours a day, the SCN adapts to a new time zone Jat leg syndrome - treatment •Taking oral melatonin can shorten the period of jet lag •Melatonin should be taken at the times of darkness in the new time zone whilst on the plane and for several days at the destination •For shift work, the melatonin should be taken during the period of desired sleep •The SCN is reset more quickly and the body becomes resynchronized Seasonal affective disorder •Effect of melatonin also on an anual rhythm • - season rhythm - in winter – a little light, elevated of concentration of melatonin – internal desynchronization …….. increased incidence of depression • • Sleep disorder •Sleep delay (problem to sleep at night - delayed sleep) –problem: sleep at night, wake up in the morning is wrong. Treatment: administered melatonin when he wants to sleep • •Phase advance – go to sleep without any problems, but the waking up too early in the morning . Treatment: bright light exposure at a time when he wants to sleep, but it should still be awake) •In the abscence of light signals, circadian rhythms still exist but are not synchronized with the day-night cycle. • •transition to summer or winter time •shift work (porter, in hospital – nurse, doctor – working during the night time) • •Resynchronisation internal clock system with the external part – diseaseas: • fatique (tiredness) - sleep disruption - lack of appetite – gastric ulsers – stress – hypertension – obesity – changes in behaviour (Tsang at al. 2014) (Tsang at al. 2014) E (Tsang at al. 2014) (Reiter at al. 2014) References: •Russel J. Reiter, Dun XianTan, Ahmet Korkmaz and Sergio A.Rosales-Corral. Melatonin and stable circadian rhythms optimize maternal, placental and fetal physiology. Human Reproduction Update, Vol.20, No.2 pp.293–307, 2014 doi:10.1093/humupd/dmt054 •SILBERNAGL, Stefan a Agamemnon DESPOPOULOS. Color atlas of physiology. 6th ed., completely rev. and expanded. Stuttgart: Thieme, c2009. ISBN 978-3-13-545006-3. SILBERNAGL, Stefan a Agamemnon DESPOPOULOS. Color atlas of physiology. 6th ed., completely rev. and expanded. Stuttgart: Thieme, c2009. ISBN 978-3-13-545006-3. •Anthony A Tsang, Johanna L Barclay and Henrik Oster. Interactions between endocrine and circadian systems. Journal of Molecular Endocrinology, 2014, vol. 52, pp. R1-R16. doi:10.1530/JME-13-0118 •JAVORKA, Kamil. Lekárska fyziologia. 3, prep. a dopl. vyd. Martin: Vydavateľstvo Osveta, c2009. ISBN 978-80-8063-291-5. •