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Michael Menaker

March 04, 2023

Michael Menaker (May 19, 1934 – February 14, 2021),[1] was an American chronobiology researcher, and was Commonwealth Professor of Biology at University of Virginia. His research focused on circadian rhythmicity of vertebrates, including contributing to an understanding of light input pathways on extra-retinal photoreceptors of non-mammalian vertebrates, discovering a mammalian mutation for circadian rhythmicity (tau mutation in golden hamsters), and locating a circadian oscillator in the pineal gland of bird. He wrote almost 200 scientific publications.[2]

Michael Menaker
Born(1934-05-19)May 19, 1934
Austria
DiedFebruary 14, 2021(2021-02-14) (aged 86)
Virginia, U.S.
Alma materSwarthmore College (B.A.)
Princeton University
Scientific career
FieldsBiology
Doctoral advisorColin Pittendrigh

Early life and education

Menaker grew up in New York City and attended Swarthmore College.

After graduating from Swarthmore College in 1955 with a B.A. in biology, Menaker went on to Princeton University.[3] In the lab of Colin Pittendrigh,[4][5] the father of research on biological clocks, Menaker studied the endogenous circadian rhythm of bats (Myotis lucifugus).[6]

He graduated from Princeton University with a Ph.D. in 1960, and continued postdoctoral studies in Donald Griffin's lab [5] at Harvard University.[3] As he continued to study bats, his interest shifted from circadian rhythms to hibernation patterns.[7] When Menaker joined faculty at University of Texas at Austin in 1962,[4] he transitioned to studying circadian rhythms in the house sparrow (Passer domesticus)[8] and the golden hamster (Mesocricetus auratus).[9]

Academic career

Menaker has held academic positions at the University of Texas, University of Oregon, and more recently, at University of Virginia, where he has been the Commonwealth Professor of Biology since 1987.[3] He served as Chairman of the Biology Department at Virginia from 1987 to 1993.[3] He has mentored several experts in the field of chronobiology, including Joseph Takahashi,[10] Chair of the Neuroscience Department at University of Texas Southwestern Medical Center; Heidi Hamm, Chair of the Pharmacology Department at Vanderbilt University; and Carl Johnson Professor of Biological Sciences at Vanderbilt University. He has authored almost 200 papers and maintained grant funding to support his research for over 60 years.[5]

Scientific work

Discovery of extra-retinal photoreceptor(s) in the house sparrow

In 1968, Menaker provided evidence for the existence of extra-retinal photoreceptors that were sufficient for photoentrainment by measuring rhythmic locomotor behavior as the output signal of the house sparrows (Passer domesticus) circadian clock. He demonstrated that photoentrainment could occur in the absence of optic neurons, evidence for the presence of an extra-retinal photoreceptor(s) coupled to the House Sparrow circadian clock.[11] In this experiment, bilaterally enucleated house sparrows were exposed to an artificial light-dark cycle. They were kept in constant darkness to determine their free-running period and subsequently allowed to entrain to light cues. Locomotor activity was recorded through observing perching behavior of the sparrows. He tested three possible confounding variables for entrainment: (1) temperature fluctuation, (2) post-enucleation retinal fragments remaining in the eye, and (3) ectoparasites that might transfer light information through their movements in the birds' skin. To study the effects of temperature on circadian rhythms, Menaker exposed the enucleated sparrows to an electroluminescent panel. Menaker treated sparrows with Dry-Die, an anti-parasitic agent, to eliminate any possible effects of light transferring by ectoparasites. Since the sparrows did not entrain during tests of temperature fluctuation and the sparrows remained entrained 10 months after enucleation, a point at which any excess of the functional retina would have degraded, Menaker ruled out these possible confounding variables.[8] Menaker's lab concluded the sparrows were able to entrain to environmental light cues. These results demonstrate that retinal light receptors are not necessary for photoentrainment, indicating there is an extra-retinal photoreceptor(s) contributing to circadian locomotor activity. Menaker's findings in enucleated sparrows were consistent with Aschoff's Rule, and he concluded that the retinae and the extra-retinal receptor(s) both contribute to the photoentrainment process.

Pineal gland as a location for circadian oscillator in the house sparrow

In 1979, Menaker and Natille Headrick Zimmerman expanded on Menaker's previous work with house sparrows, by exploring the influence of the pineal gland and hypothalamus on circadian rhythms. They transplanted the pineal tissue of one sparrow into the anterior chamber of the eyes of an arrhythmic, pinealectomized sparrow. Prior to the transplantation procedure, the donor birds were entrained to a 12:12 light:dark photoperiod cycle. This allowed them to compare the onset of activity, measured by perching patterns, of the donors before pineal transplantation and the recipients after transplantation. Upon receiving pineal tissue transplantation, previously arrhythmic sparrows experienced the reestablishment of rhythmicity. In fact, their reestablished circadian oscillations resembled the circadian oscillation pattern for locomotor activity of the donor sparrows. The 20% of the sparrows who had successful transplantations showed temporary arrhythmicity in constant darkness for a period of 10 to 100 days, which was not always evenly distributed in the 24-hour day; the sparrows, however, eventually became rhythmic once again.[12] Menaker concluded the pineal gland is a driving oscillator within a multi-component system.

Discovery of the tau mutation in golden hamsters

In 1988, Martin Ralph and Menaker serendipitously came across a tau mutant male golden hamster in a shipment from their commercial supplier, Charles River Laboratories, that was observed to have a circadian period significantly shorter than what is characteristic of that breed. These golden hamsters are recognized for their narrow range of periods with a typical mean of 24 hours.[13] Thus, rather than overlooking this abnormal male hamster, Menaker conducted breeding experiments to produce homozygous tau mutants with a period of 20 hours and heterozygous tau mutants with a period of 22 hours. The pattern of inheritance from this shortened tau indicated the genetic cause of this phenotype was isolated to a single allele, providing a genetic approach to the determination of the biological mechanism.[14] This accidental forward genetic screen yielded the first specimen that could be studied for genetic insight into mammalian circadian mechanisms.

The first major finding with this strain was that the oscillator had to be located in the suprachiasmatic nucleus (SCN).[14] To test this conclusion, Menaker and colleagues conducted experiments whereby the SCN from a tau mutant hamster was transplanted through a neural graft to a wild-type hamster with an ablated SCN. After this procedure, the formerly wild-type hamster displayed a shortened period which resembled the tau mutant. This result led to the conclusion that the SCN is sufficient and necessary for mammalian circadian rhythms.[14]

Further investigation of the SCN as a central structure of circadian rhythms by Silver, et al. found that the SCN can control circadian rhythmicity by a diffusive signal.[15] They transplanted the SCN as previously done by Menaker, but they encapsulated the graft thus preventing outgrowth by mutant SCN neurons. Even with the SCN restrained in this way the wild type hamster displayed a shorter period consistent with the period of the SCN donated by the mutant tau hamster, suggesting the SCN emits diffusable factors to control circadian rhythms.[15] That same year, Gianluca Tosini and Menaker also determined that hamster retinas cultured in vitro produced a consistent circadian rhythm, as measured by melatonin levels.[16] This suggests that there are multiple oscillators, or multiple neurons that compose a single oscillator sufficient for circadian outputs.

Molecular identification of the tau locus

It was still uncertain as to exactly which genetic locus the tau mutation was found, and which protein it affected. In 2000, Menaker collaborated with other scientists in the field to use genetically directed representational difference analysis (GDRDA), a new technique in molecular genetics that allowed them to accomplish this goal.[17]

GDRDA works by first generating polymorphic genetic markers for a monogenic trait (which the tau has already been proven to be) that can be directly identified in the genome. This is done by separating progeny from a cross, based on the phenotype of interest and then creating amplicons of pooled DNA from each group. With these groups of amplified DNA, it can be determined which loci are enriched in the group exhibiting the phenotype of interest. These enriched loci are the genetic markers for the trait of interest.

The genetic markers for the tau mutants mapped to chromosome 22. The region of conserved synteny was the gene casein kinase I epsilon (CKIe). This is consistent with CKIe's homology to the Drosophila circadian control gene doubletime (dbt). From this work it was also shown that CK1e could interact with the mammalian PERIOD protein in vitro and effect the expression of Per1. From this work, the Takahashi lab successfully validated the tau mutant genetically by discovering the affected locus and subsequently established a model of circadian protein interaction by which the effects of the tau mutation could be explained.

Establishing methamphetamine-sensitive circadian oscillator (MASCO) in mice

Although previous studies demonstrate that methamphetamine (MAP) has a significant effect on the circadian behavior of rats, suggesting evidence of the SCN-independent, MAP-sensitive circadian oscillator (MASCO), Menaker and colleagues chose to look at MASCO in mice.[18] The work done by Menaker and colleagues looked at the effects of chronic MAP expression on two strains of intact and SCN-lesioned mice in constant dark and constant light conditions.

MAP in the drinking water generated circadian locomotor rhythmicity in SCN lesioned mice. When MAP was removed, the free-running locomotor rhythm persisted for as long as fourteen cycles. This study also showed that small increases in MAP caused an increase in daily wheel-running activity and the length of the circadian period for intact mice and SCN-lesioned mice in constant dark and constant light conditions. The observations of Menaker and colleagues indicate that MASCO, a circadian oscillator, functions separately from the "master clock" of the SCN and is sufficient for locomotor circadian rhythm control.

This study disproves the "hourglass" mechanism hypothesis for MASCO proposed by Ruis, et al. This hypothesis states that the spontaneous consumption of MAP in drinking water by rodents results in lengthened bouts of activity, followed by sleep. The cycle is reinforced when the animal awakes and drinks once more.[19] Menaker and colleagues tested SCN-lesioned, arrhythmic mice in constant darkness and found that when the MAP was no longer consumed at rhythmic intervals, constant rhythms in locomotor behavior were still found. In another trial, MAP was alternated every other day with water, and locomotor rhythm persisted on days with just the water. Both of these findings made clear that the "hourglass" hypothesis for the mechanism of MASCO was not valid.[20]

Molecular mechanism of MASCO

Menaker and colleagues investigated if MASCO affected the molecular feedback loop underlying the currently accepted model for circadian rhythmicity in mammals. This investigation was done by treating arrhythmic mice lacking or with mutations to various genes in this feedback loop with MAP dosages. These genes included mutations and deletions to Per1, Per2, Cry1, Cry2, Bmal1, Npas2, CLOCK and CK1e. All of these mutants continued to respond and exhibit changes in free-running rhythms in the presence of MAP, despite mutational breaks in the feedback loop for circadian oscillation. In these arrhythmic animals, regardless of mutation or knockout of critical clock genes, MAP restored rhythm of circadian properties. This suggests that the molecular mechanism for MASCO is radically different from the known and accepted circadian oscillation model in mammals, and the feedback loop is not necessary for the generation of circadian locomotor rhythmicity by MAP.[21]

Later work

Menaker's lab group at University of Virginia was focused on the organization of circadian systems in vertebrates. The lab is working with a transgenic rat model with Per1 gene linked to a luciferase reporter to track the circadian expression patterns of the Per1 gene in brain and peripheral tissues. They anticipate this data to address if the clocks in all tissues remain in synchrony with a change in light cycle, and the clock-related signals from the brain to peripheral tissues [1].

Menaker discovered another mutant hamster, this time showing a free-running period of 25 hours in conditions of constant darkness.[22] Menaker's graduate student, Ashli Moore, was a teaching assistant in his colleague's animal behavior course when an undergraduate student insisted on trading in her hamster for one that had a period more closely resembling that of her classmates' hamsters. Menaker bred this mutant hamster with three different females to produce litters with Mendalian ratios of wild-type and heterozygous mutants. He subsequently bred homozygous mutants with a free-running period of 28 hours. Menaker's lab is currently in collaboration with Carla Green's molecular biology lab at University of Texas Southwestern Medical Center to study this mutant hamster line further.[22]

Awards and honors[7]

See also

References

  1. ^ "Passing of Michael Menaker | SRBR: Society for Research on Biological Rhythms".
  2. ^ "Using PubMed." National Center for Biotechnology Information. U.S. National Library of Medicine, n.d. Web. 23 Apr. 2013
  3. ^ a b c d Menaker, Michael. "Department of Biology, University of Virginia".
  4. ^ a b Refinetti, Roberto. Circadian Physiology. Boca Raton: CRC/Taylor & Francis Group, 2006. Print.
  5. ^ a b c "Michael Menaker". EUCLOCK Information System. Retrieved April 16, 2013.
  6. ^ MENAKER, MICHAEL (October 17, 1959). "Endogenous Rhythms of Body Temperature in Hibernating Bats". Nature. 184 (4694): 1251–1252. Bibcode:1959Natur.184.1251M. doi:10.1038/1841251a0. S2CID 4152050.
  7. ^ a b F1000Prime. "Michael Menaker". Faculty of 1000 Ltd. Retrieved April 24, 2013.
  8. ^ a b Menaker, Michael. Extraretinal Light Perception in Sparrow, I. Entrainment of the Biological Clock" Proc Natl Acad Sci USA 1968, Feb 15; 59(2): 414-421.
  9. ^ Ralph, Martin; Michael Menaker (1988). "A mutation of the circadian system in golden hamsters". Science. 241 (4870): 1225–1227. Bibcode:1988Sci...241.1225R. doi:10.1126/science.3413487. PMID 3413487.
  10. ^ . Archived from the original on February 3, 2014. Retrieved April 13, 2013.
  11. ^ Bellingham, James, and Russell G. Foster. Opsins and mammalian photoentrainment. Cell and Tissue Research 309.1 (2002): 57-71.
  12. ^ Zimmerman N.H., Menaker M. The pineal gland: A pacemaker within the circadian system of the house sparrow. Proc Natl Acad. Sci USA. 1979, Feb; 76(2): 999-1003.
  13. ^ Pittendrigh, C.S., Daan, S. A Functional Analysis of Circadian Pacemakers in Nocturnal Rodents. J. Comp. Physiol. 1976;106:333-355.
  14. ^ a b c Ralph, M.R., Foster, R.G., Davis, F.C. Menaker, M. Transplanted Suprachiasmatic Nucleus Determines Circadian Period" Science 1990, Feb 23;247(4945):975-8.
  15. ^ a b Silver, Rae, et al. "A diffusible coupling signal from the transplanted suprachiasmatic nucleus controlling circadian locomotor rhythms." Nature 382.6594 (1996): 810-813.
  16. ^ Tosini, Gianluca, and Michael Menaker. "Circadian rhythms in cultured mammalian retina." Science 272.5260 (1996): 419-421.
  17. ^ Lowrey, Phillip L., et al. "Positional syntenic cloning and functional characterization of the mammalian circadian mutation tau." Science 288.5465 (2000): 483-491.
  18. ^ Honma, S., Yasuda, T., Yasui, A., van der Horst, G.T.J., Honma, K. Circadian Behavioral Rhythms in Cry1/Cry2 Double-Deficient Mice Induced by Methamphetamine. Biol Rhythms. 2008, Feb; 23(1): 91-94.
  19. ^ Ruis, J.F., Buys, J.P., Cambras, T., Rietveld W.J. Effects of t cycles of light/darkness and periodic forced activity on methamphetamine-induced rhythms in intact and SCN-lesioned rats: Explanation by an hourglass-clock model. Physiol Behav. 1990; 47:917-929
  20. ^ Tataroglu Ö., Davidson A.J., Benvenuto L.J., Menaker M. The Methamphetamine-Sensitive Circadian Oscillator (MASCO) in Mice. Bio Rhythms. 2006, Jun; 21(3): 185-194.
  21. ^ Mohawk J.A., Baer M.L., Menaker M. The methamphetamine-sensitive circadian oscillator does not employ canonical clock genes" Proc Natl Acad Sci USA 2009, Mar 3; 1006(9): 3519-2.
  22. ^ a b Menaker, Michael. Personal interview. 11 April 2013.

March 04, 2023
michael, menaker, 1934, february, 2021, american, chronobiology, researcher, commonwealth, professor, biology, university, virginia, research, focused, circadian, rhythmicity, vertebrates, including, contributing, understanding, light, input, pathways, extra, . Michael Menaker May 19 1934 February 14 2021 1 was an American chronobiology researcher and was Commonwealth Professor of Biology at University of Virginia His research focused on circadian rhythmicity of vertebrates including contributing to an understanding of light input pathways on extra retinal photoreceptors of non mammalian vertebrates discovering a mammalian mutation for circadian rhythmicity tau mutation in golden hamsters and locating a circadian oscillator in the pineal gland of bird He wrote almost 200 scientific publications 2 Michael MenakerBorn 1934 05 19 May 19 1934AustriaDiedFebruary 14 2021 2021 02 14 aged 86 Virginia U S Alma materSwarthmore College B A Princeton UniversityScientific careerFieldsBiologyDoctoral advisorColin Pittendrigh Contents 1 Early life and education 2 Academic career 3 Scientific work 3 1 Discovery of extra retinal photoreceptor s in the house sparrow 3 2 Pineal gland as a location for circadian oscillator in the house sparrow 3 3 Discovery of the tau mutation in golden hamsters 3 4 Molecular identification of the tau locus 3 5 Establishing methamphetamine sensitive circadian oscillator MASCO in mice 3 6 Molecular mechanism of MASCO 4 Later work 5 Awards and honors 7 6 See also 7 ReferencesEarly life and education EditMenaker grew up in New York City and attended Swarthmore College After graduating from Swarthmore College in 1955 with a B A in biology Menaker went on to Princeton University 3 In the lab of Colin Pittendrigh 4 5 the father of research on biological clocks Menaker studied the endogenous circadian rhythm of bats Myotis lucifugus 6 He graduated from Princeton University with a Ph D in 1960 and continued postdoctoral studies in Donald Griffin s lab 5 at Harvard University 3 As he continued to study bats his interest shifted from circadian rhythms to hibernation patterns 7 When Menaker joined faculty at University of Texas at Austin in 1962 4 he transitioned to studying circadian rhythms in the house sparrow Passer domesticus 8 and the golden hamster Mesocricetus auratus 9 Academic career EditMenaker has held academic positions at the University of Texas University of Oregon and more recently at University of Virginia where he has been the Commonwealth Professor of Biology since 1987 3 He served as Chairman of the Biology Department at Virginia from 1987 to 1993 3 He has mentored several experts in the field of chronobiology including Joseph Takahashi 10 Chair of the Neuroscience Department at University of Texas Southwestern Medical Center Heidi Hamm Chair of the Pharmacology Department at Vanderbilt University and Carl Johnson Professor of Biological Sciences at Vanderbilt University He has authored almost 200 papers and maintained grant funding to support his research for over 60 years 5 Scientific work EditDiscovery of extra retinal photoreceptor s in the house sparrow Edit In 1968 Menaker provided evidence for the existence of extra retinal photoreceptors that were sufficient for photoentrainment by measuring rhythmic locomotor behavior as the output signal of the house sparrows Passer domesticus circadian clock He demonstrated that photoentrainment could occur in the absence of optic neurons evidence for the presence of an extra retinal photoreceptor s coupled to the House Sparrow circadian clock 11 In this experiment bilaterally enucleated house sparrows were exposed to an artificial light dark cycle They were kept in constant darkness to determine their free running period and subsequently allowed to entrain to light cues Locomotor activity was recorded through observing perching behavior of the sparrows He tested three possible confounding variables for entrainment 1 temperature fluctuation 2 post enucleation retinal fragments remaining in the eye and 3 ectoparasites that might transfer light information through their movements in the birds skin To study the effects of temperature on circadian rhythms Menaker exposed the enucleated sparrows to an electroluminescent panel Menaker treated sparrows with Dry Die an anti parasitic agent to eliminate any possible effects of light transferring by ectoparasites Since the sparrows did not entrain during tests of temperature fluctuation and the sparrows remained entrained 10 months after enucleation a point at which any excess of the functional retina would have degraded Menaker ruled out these possible confounding variables 8 Menaker s lab concluded the sparrows were able to entrain to environmental light cues These results demonstrate that retinal light receptors are not necessary for photoentrainment indicating there is an extra retinal photoreceptor s contributing to circadian locomotor activity Menaker s findings in enucleated sparrows were consistent with Aschoff s Rule and he concluded that the retinae and the extra retinal receptor s both contribute to the photoentrainment process Pineal gland as a location for circadian oscillator in the house sparrow Edit In 1979 Menaker and Natille Headrick Zimmerman expanded on Menaker s previous work with house sparrows by exploring the influence of the pineal gland and hypothalamus on circadian rhythms They transplanted the pineal tissue of one sparrow into the anterior chamber of the eyes of an arrhythmic pinealectomized sparrow Prior to the transplantation procedure the donor birds were entrained to a 12 12 light dark photoperiod cycle This allowed them to compare the onset of activity measured by perching patterns of the donors before pineal transplantation and the recipients after transplantation Upon receiving pineal tissue transplantation previously arrhythmic sparrows experienced the reestablishment of rhythmicity In fact their reestablished circadian oscillations resembled the circadian oscillation pattern for locomotor activity of the donor sparrows The 20 of the sparrows who had successful transplantations showed temporary arrhythmicity in constant darkness for a period of 10 to 100 days which was not always evenly distributed in the 24 hour day the sparrows however eventually became rhythmic once again 12 Menaker concluded the pineal gland is a driving oscillator within a multi component system Discovery of the tau mutation in golden hamsters Edit In 1988 Martin Ralph and Menaker serendipitously came across a tau mutant male golden hamster in a shipment from their commercial supplier Charles River Laboratories that was observed to have a circadian period significantly shorter than what is characteristic of that breed These golden hamsters are recognized for their narrow range of periods with a typical mean of 24 hours 13 Thus rather than overlooking this abnormal male hamster Menaker conducted breeding experiments to produce homozygous tau mutants with a period of 20 hours and heterozygous tau mutants with a period of 22 hours The pattern of inheritance from this shortened tau indicated the genetic cause of this phenotype was isolated to a single allele providing a genetic approach to the determination of the biological mechanism 14 This accidental forward genetic screen yielded the first specimen that could be studied for genetic insight into mammalian circadian mechanisms The first major finding with this strain was that the oscillator had to be located in the suprachiasmatic nucleus SCN 14 To test this conclusion Menaker and colleagues conducted experiments whereby the SCN from a tau mutant hamster was transplanted through a neural graft to a wild type hamster with an ablated SCN After this procedure the formerly wild type hamster displayed a shortened period which resembled the tau mutant This result led to the conclusion that the SCN is sufficient and necessary for mammalian circadian rhythms 14 Further investigation of the SCN as a central structure of circadian rhythms by Silver et al found that the SCN can control circadian rhythmicity by a diffusive signal 15 They transplanted the SCN as previously done by Menaker but they encapsulated the graft thus preventing outgrowth by mutant SCN neurons Even with the SCN restrained in this way the wild type hamster displayed a shorter period consistent with the period of the SCN donated by the mutant tau hamster suggesting the SCN emits diffusable factors to control circadian rhythms 15 That same year Gianluca Tosini and Menaker also determined that hamster retinas cultured in vitro produced a consistent circadian rhythm as measured by melatonin levels 16 This suggests that there are multiple oscillators or multiple neurons that compose a single oscillator sufficient for circadian outputs Molecular identification of the tau locus Edit It was still uncertain as to exactly which genetic locus the tau mutation was found and which protein it affected In 2000 Menaker collaborated with other scientists in the field to use genetically directed representational difference analysis GDRDA a new technique in molecular genetics that allowed them to accomplish this goal 17 GDRDA works by first generating polymorphic genetic markers for a monogenic trait which the tau has already been proven to be that can be directly identified in the genome This is done by separating progeny from a cross based on the phenotype of interest and then creating amplicons of pooled DNA from each group With these groups of amplified DNA it can be determined which loci are enriched in the group exhibiting the phenotype of interest These enriched loci are the genetic markers for the trait of interest The genetic markers for the tau mutants mapped to chromosome 22 The region of conserved synteny was the gene casein kinase I epsilon CKIe This is consistent with CKIe s homology to the Drosophila circadian control gene doubletime dbt From this work it was also shown that CK1e could interact with the mammalian PERIOD protein in vitro and effect the expression of Per1 From this work the Takahashi lab successfully validated the tau mutant genetically by discovering the affected locus and subsequently established a model of circadian protein interaction by which the effects of the tau mutation could be explained Establishing methamphetamine sensitive circadian oscillator MASCO in mice Edit Although previous studies demonstrate that methamphetamine MAP has a significant effect on the circadian behavior of rats suggesting evidence of the SCN independent MAP sensitive circadian oscillator MASCO Menaker and colleagues chose to look at MASCO in mice 18 The work done by Menaker and colleagues looked at the effects of chronic MAP expression on two strains of intact and SCN lesioned mice in constant dark and constant light conditions MAP in the drinking water generated circadian locomotor rhythmicity in SCN lesioned mice When MAP was removed the free running locomotor rhythm persisted for as long as fourteen cycles This study also showed that small increases in MAP caused an increase in daily wheel running activity and the length of the circadian period for intact mice and SCN lesioned mice in constant dark and constant light conditions The observations of Menaker and colleagues indicate that MASCO a circadian oscillator functions separately from the master clock of the SCN and is sufficient for locomotor circadian rhythm control This study disproves the hourglass mechanism hypothesis for MASCO proposed by Ruis et al This hypothesis states that the spontaneous consumption of MAP in drinking water by rodents results in lengthened bouts of activity followed by sleep The cycle is reinforced when the animal awakes and drinks once more 19 Menaker and colleagues tested SCN lesioned arrhythmic mice in constant darkness and found that when the MAP was no longer consumed at rhythmic intervals constant rhythms in locomotor behavior were still found In another trial MAP was alternated every other day with water and locomotor rhythm persisted on days with just the water Both of these findings made clear that the hourglass hypothesis for the mechanism of MASCO was not valid 20 Molecular mechanism of MASCO Edit Menaker and colleagues investigated if MASCO affected the molecular feedback loop underlying the currently accepted model for circadian rhythmicity in mammals This investigation was done by treating arrhythmic mice lacking or with mutations to various genes in this feedback loop with MAP dosages These genes included mutations and deletions to Per1 Per2 Cry1 Cry2 Bmal1 Npas2 CLOCK and CK1e All of these mutants continued to respond and exhibit changes in free running rhythms in the presence of MAP despite mutational breaks in the feedback loop for circadian oscillation In these arrhythmic animals regardless of mutation or knockout of critical clock genes MAP restored rhythm of circadian properties This suggests that the molecular mechanism for MASCO is radically different from the known and accepted circadian oscillation model in mammals and the feedback loop is not necessary for the generation of circadian locomotor rhythmicity by MAP 21 Later work EditMenaker s lab group at University of Virginia was focused on the organization of circadian systems in vertebrates The lab is working with a transgenic rat model with Per1 gene linked to a luciferase reporter to track the circadian expression patterns of the Per1 gene in brain and peripheral tissues They anticipate this data to address if the clocks in all tissues remain in synchrony with a change in light cycle and the clock related signals from the brain to peripheral tissues 1 Menaker discovered another mutant hamster this time showing a free running period of 25 hours in conditions of constant darkness 22 Menaker s graduate student Ashli Moore was a teaching assistant in his colleague s animal behavior course when an undergraduate student insisted on trading in her hamster for one that had a period more closely resembling that of her classmates hamsters Menaker bred this mutant hamster with three different females to produce litters with Mendalian ratios of wild type and heterozygous mutants He subsequently bred homozygous mutants with a free running period of 28 hours Menaker s lab is currently in collaboration with Carla Green s molecular biology lab at University of Texas Southwestern Medical Center to study this mutant hamster line further 22 Awards and honors 7 EditWilliam Greig Lapham Fellow Princeton University 1957 1958 National Science Foundation Predoctoral Fellow Princeton University 1958 1959 NIH NSF Postdoctoral Fellowship Harvard University 1960 1962 Career Development Award National Institutes of Health 1970 1975 Guggenheim Fellowship University of Montpellier France 1971 1972 Fellow American Association for the Advancement of Science elected 1983 Benjamin Meaker Visiting Professor University of Bristol UK 1986 Commonwealth Professor of Biology University of Virginia 1987 Fellow Japan Society for the Promotion of Science 1992 Fellow American Academy of Arts amp Sciences elected 1999 Lifetime Achievement Award American Society of Photobiology 2002 Virginia s Outstanding Scientists and Industrialists Life Achievement in Science Award 2003 Peter C Farrell Prize in Sleep Medicine Harvard Medical School Division of Sleep Medicine 2007 University of Virginia Distinguished Scientist Award 2009 University of Groningen Honorary Doctorate 2009 Honma Life Science Foundation Sapporo Japan Aschoff Honma Prize 2009See also EditColin Pittendrigh Gene Block PER1 Circadian rhythmReferences Edit Passing of Michael Menaker SRBR Society for Research on Biological Rhythms Using PubMed National Center for Biotechnology Information U S National Library of Medicine n d Web 23 Apr 2013 a b c d Menaker Michael Department of Biology University of Virginia a b Refinetti Roberto Circadian Physiology Boca Raton CRC Taylor amp Francis Group 2006 Print a b c Michael Menaker EUCLOCK Information System Retrieved April 16 2013 MENAKER MICHAEL October 17 1959 Endogenous Rhythms of Body Temperature in Hibernating Bats Nature 184 4694 1251 1252 Bibcode 1959Natur 184 1251M doi 10 1038 1841251a0 S2CID 4152050 a b F1000Prime Michael Menaker Faculty of 1000 Ltd Retrieved April 24 2013 a b Menaker Michael Extraretinal Light Perception in Sparrow I Entrainment of the Biological Clock Proc Natl Acad Sci USA 1968 Feb 15 59 2 414 421 Ralph Martin Michael Menaker 1988 A mutation of the circadian system in golden hamsters Science 241 4870 1225 1227 Bibcode 1988Sci 241 1225R doi 10 1126 science 3413487 PMID 3413487 Chemical and Genetic Manipulation of Circadian Systems Contact Archived from the original on February 3 2014 Retrieved April 13 2013 Bellingham James and Russell G Foster Opsins and mammalian photoentrainment Cell and Tissue Research 309 1 2002 57 71 Zimmerman N H Menaker M The pineal gland A pacemaker within the circadian system of the house sparrow Proc Natl Acad Sci USA 1979 Feb 76 2 999 1003 Pittendrigh C S Daan S A Functional Analysis of Circadian Pacemakers in Nocturnal Rodents J Comp Physiol 1976 106 333 355 a b c Ralph M R Foster R G Davis F C Menaker M Transplanted Suprachiasmatic Nucleus Determines Circadian Period Science 1990 Feb 23 247 4945 975 8 a b Silver Rae et al A diffusible coupling signal from the transplanted suprachiasmatic nucleus controlling circadian locomotor rhythms Nature 382 6594 1996 810 813 Tosini Gianluca and Michael Menaker Circadian rhythms in cultured mammalian retina Science 272 5260 1996 419 421 Lowrey Phillip L et al Positional syntenic cloning and functional characterization of the mammalian circadian mutation tau Science 288 5465 2000 483 491 Honma S Yasuda T Yasui A van der Horst G T J Honma K Circadian Behavioral Rhythms in Cry1 Cry2 Double Deficient Mice Induced by Methamphetamine Biol Rhythms 2008 Feb 23 1 91 94 Ruis J F Buys J P Cambras T Rietveld W J Effects of t cycles of light darkness and periodic forced activity on methamphetamine induced rhythms in intact and SCN lesioned rats Explanation by an hourglass clock model Physiol Behav 1990 47 917 929 Tataroglu O Davidson A J Benvenuto L J Menaker M The Methamphetamine Sensitive Circadian Oscillator MASCO in Mice Bio Rhythms 2006 Jun 21 3 185 194 Mohawk J A Baer M L Menaker M The methamphetamine sensitive circadian oscillator does not employ canonical clock genes Proc Natl Acad Sci USA 2009 Mar 3 1006 9 3519 2 a b Menaker Michael Personal interview 11 April 2013 Retrieved from https en wikipedia org w index php title Michael Menaker amp oldid 1139778338, wikipedia, wiki, book, books, library,

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